KR20230000306U - Waste disposal unit - Google Patents

Abstract

The present invention relates to a food waste disposer. One aspect of the food waste disposer according to an embodiment of the present invention includes a casing defining an external appearance; a treatment tank located inside the casing and fermenting and decomposing the food waste stored therein by microorganisms; a blowing unit for flowing air to be sucked in and discharged into and out of the treatment tank; and a deodorizing unit including a first deodorizing unit supplying deodorizing components to air sucked into the treatment tank and at least one second deodorizing unit filtering malodorous components in the air discharged to the outside of the treatment tank; includes

Description

Food waste disposer {WASTE DISPOSAL UNIT}

The present invention relates to a food waste disposer.

Recently, as interest in the environment increases, food waste disposers for more environmentally friendly processing of food waste have been released. Among such food waste disposers, Prior Art Document 1 (Registration Patent Publication No. 10-0743544, name: deodorization system for eco-friendly food waste disposer) filed and registered by the applicant of the present invention includes food waste using microorganisms. Disclosed is a food waste disposer that decomposes in an environmentally friendly manner.

Referring to Prior Art Document 1, conventionally, food waste is fermented and decomposed by microorganisms inside the treatment tank 10 . In addition, odor generated in the process of fermenting and decomposing food waste inside the treatment tank 10 is removed while passing through the deodorization chamber 20 . More specifically, when air containing odor components is introduced into the deodorization chamber 20, oxygen in the air is synthesized into ozone by the ultraviolet lamp 2 located inside the deodorization chamber 20, Eliminates odorous components in In addition, odor components in the air delivered to the inside of the deodorization chamber 20 may be removed by a photocatalyst or non-photocatalyst coated on the surface of the breathable filler 26 located inside the deodorization chamber 20. Next, the air from which odor components are removed in the deodorization chamber 20 passes through the ozone decomposition chamber 30, and ozone in the air is removed. That is, when air containing ozone is introduced into the ozone decomposition chamber 30, the ozone remaining in the air is decomposed and removed by the ozone decomposition catalyst 40 located inside the ozone decomposition chamber 30. do. However, in the prior art, since the odor generated in the process of treating food waste is not sufficiently removed, the user still feels uncomfortable.

In order to solve this problem, prior art document 2 (Korean Patent Publication No. 10-2021-0037266 (name: food waste disposer) filed by the applicant of the present invention, by volatilizing deodorizing or aromatic liquid, food three Disclosed is a technique for removing odors generated in the process of processing the ghee.

Referring to Prior Art Document 2, conventionally, the deodorizing or aromatic liquid volatilized in the volatilization unit 600 is volatilized into the air sucked into the treatment tank 200 and into the air discharged to the outside of the treatment tank 200. do. However, in such a prior art, since the odor is simply removed by the volatilized deodorant or aromatic liquid, it is not possible to remove the odor more efficiently by various means, especially the air discharged to the outside of the treatment tank 200. As the excessive deodorizing or aromatic liquid is volatilized in the middle, rather, the disadvantage that the user feels uncomfortable occurs.

Republic of Korea Patent Registration No. 10-0743544 (Name: Eco-friendly food waste disposal system deodorization system) Republic of Korea Patent Publication No. 10-2021-0037266 (name: food waste disposer)

The present invention is to solve the problems caused by the prior art as described above, and an object of the present invention is to provide a food waste disposer configured to more efficiently remove odors generated in the process of treating food waste. .

One aspect of the food waste disposer according to an embodiment of the present invention for achieving the above object is a casing defining an appearance; a treatment tank located inside the casing and fermenting and decomposing the food waste stored therein by microorganisms; a blowing unit for flowing air to be sucked in and discharged into and out of the treatment tank; and a deodorizing unit including a first deodorizing unit supplying deodorizing components to air sucked into the treatment tank and at least one second deodorizing unit filtering malodorous components in the air discharged to the outside of the treatment tank; includes

In one aspect of an embodiment of the present invention, the deodorization unit further includes a deodorization tank detachably mounted on one side of the casing and detachably coupled to the first and second deodorization units.

In one aspect of the embodiment of the present invention, the deodorization tank is formed in a polyhedral shape with an open upper surface, and an exhaust hole is formed on the bottom surface of the tank body; and a tank cover coupled to an upper surface of the tank body to define a flow path together with the tank body and having the intake hole formed therein. The air discharged to the outside of the treatment tank is sucked into the flow path through the intake hole, flows through the flow path, and then is discharged to the outside of the flow path through the exhaust hole.

In one aspect of the embodiments of the present invention, the first desorbing part is seated on a seating opening formed in the tank cover so that a part thereof is exposed on the flow path, and the second deodorizing part is configured to allow air to flow through the flow path. It is disposed inside the flow path so as to be located upstream of the first deodorizing part in the direction, and a part of the air sucked into the flow path through the intake hole passes through the second deodorizing part while filtering the odor. The rest of the air discharged to the outside of the flow path through the exhaust hole and sucked into the flow path through the intake hole passes through the second deodorizing unit while passing through the first deodorizing unit in a state in which the odor is filtered, and the deodorizing component is discharged to the outside of the passage through the exhaust hole in a supplied state.

In one aspect of the embodiment of the present invention, the tank body is provided with a recessed portion formed by sinking a portion of the bottom surface of the tank body where the exhaust hole is disposed into the interior of the flow path, and through the exhaust hole by the recessed portion. A mixing space is defined in which air passing through only the second deodorizing portion that is discharged and air that has passed through the first and second deodorizing portions that are discharged through the exhaust hole are mixed.

In one aspect of the embodiments of the present invention, the first deodorizing unit includes a deodorizing container having a storage space defined therein, a supply opening communicating with the intake port and first and second communication openings communicating with the flow path; and a deodorizing member that is stored in the storage space and includes a deodorizing component that is volatilized into the air. wherein the deodorizing component of the deodorizing member is volatilized through the supply opening and supplied to the air sucked into the treatment tank, or is passed through the second deodorizing part while flowing in the passage, and then the first and second deodorizing components are supplied. Air is supplied into the air passing through the storage space through the communication opening.

In one aspect of the embodiments of the present invention, the deodorizing container includes a container body formed in a cylindrical shape with an open upper surface and having the first and second communication openings formed therein; a container cover coupled to an upper surface of the container body to define the storage space together with the container body and having the supply opening formed therein; and a partition plate partitioning the storage space into a first storage space communicating with the supply opening and a second storage space communicating with the first and second communication openings. includes

In one aspect of the embodiment of the present invention, a pair of guide ribs for guiding the air passing through the second desorption part to the first communication opening are provided on the bottom surface of the tank body.

In one aspect of the embodiment of the present invention, the guide rib is arranged so that the distance between the other end adjacent to the first communication opening is relatively reduced compared to the distance between one end adjacent to the second take-off portion.

In one aspect of an embodiment of the present invention, the second deodorizing unit may include: a deodorizing frame defining an appearance of the second deodorizing unit; and an activated carbon member fixed inside the deodorizing frame and filtering malodorous components in the air. includes

In one aspect of the embodiment of the present invention, a fixing boss formed by sinking a portion of the bottom surface of the tank body into the passage is provided, and the deodorizing frame and the activated carbon member are provided with a fixing hole into which the fixing boss is inserted. .

In the food waste disposer according to an embodiment of the present invention, a liquid such as a fragrance or a deodorant is volatilized into the air sucked into the casing or into the air discharged to the outside of the casing by the deodorizing unit. In particular, in this embodiment, the temperature of the liquid stored in the deodorizing unit is controlled to adjust the amount of the volatilized liquid, or the deodorizing liquid is volatilized in the air sucked into the casing, and the directionality in the air discharged to the outside of the casing is adjusted. It can volatilize liquids. Therefore, according to an embodiment of the present invention, it is possible to more efficiently remove odors generated in the process of treating food waste.

1 is a perspective view showing a food waste disposer according to an embodiment of the present invention;
Figure 2 is a rear view showing an embodiment of the present invention.
Figure 3 is a bottom perspective view showing a state in which the deodorizing unit is separated in an embodiment of the present invention.
Figure 4 is a longitudinal cross-sectional view showing a first desorption portion constituting an embodiment of the present invention.

Hereinafter, the configuration of the food waste disposer according to an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a perspective view showing a food waste disposer according to an embodiment of the present invention, FIG. 2 is a rear view showing an embodiment of the present invention, and FIG. 3 is a bottom view showing a state in which a deodorizing unit is separated in an embodiment of the present invention. It is a perspective view, and FIG. 4 is a longitudinal cross-sectional view showing a first desorption part constituting an embodiment of the present invention.

First, referring to FIGS. 1 to 3 , the casing 100 defines the appearance of the food waste disposer according to the present embodiment. Substantially, the top, bottom, front, rear and side surfaces of the casing 100 are respectively upper plate 110, bottom plate 120, front plate 130, rear plate 140 and a pair of side plates ( 150) defines it. The front plate 130, the rear plate 140, and the side plate 150 may be formed separately and fixed to each other, or may be formed by bending one member.

An inlet 111 is formed in the upper plate 110 . The inlet 111 is a place where food waste to be treated is put. Substantially, the inlet 111 is defined by cutting a portion of the upper plate 110 and communicates with the upper surface of the treatment tank 200 to be described later.

In addition, an intake port 121A and an exhaust port 121B are formed in the bottom plate 120 . The intake port 121A is a place where air is sucked into the casing 100 , and the exhaust port 121B is a place where air is discharged to the outside of the casing 100 . The intake port 121A and the exhaust port 121B are spaced apart from each other on the bottom plate 120 . In this embodiment, the inlet port 121A is positioned adjacent to the front plate 130 and the exhaust port 121B is positioned adjacent to the rear plate 140 .

In addition, an intake groove 122A and an exhaust groove 122B are formed in the bottom plate 120 . The intake groove 122A and the exhaust groove 122B are defined by recessing portions thereof including the intake port 121A and the exhaust port 121B, respectively. The intake groove 122A and the exhaust groove 122B, as will be described later, in a state where the deodorization unit 1000, substantially, the storage tank 610 is installed below the bottom plate 120, the storage tank ( 610) to allow air to flow in and out of the casing 100 through the intake port 121A and the exhaust port 121B. To this end, in a state where the storage tank 610 is installed below the bottom plate 120, the orthogonal projection of the intake groove 122A and the exhaust groove 122B on the upper surface of the storage tank 610, At least a part of the shadow extends to the outside of the storage tank 610 .

A door 160 is installed in the casing 100 . The door 160 serves to selectively open and close the inlet 111 . For example, the door 160 may be rotatably installed in the casing 100 about an axis in a horizontal direction.

A treatment tank 200 is provided inside the casing 100 . The treatment tank 200 is a place where food waste is substantially treated, that is, food waste is fermented and decomposed by microorganisms. For example, the upper surface of the treatment tank 200 may communicate with the outside through the inlet 111 . Although not shown, an agitator is provided inside the treatment tank 200 . The stirrer serves to mix food waste and microorganisms inside the treatment tank 200 .

In this embodiment, a suction opening 210 is formed on one side of the treatment tank 200 . The intake opening 210 is a place where the air sucked into the casing 100 through the intake port 121A is sucked into the treatment tank 200 .

In addition, the treatment tank 200 is provided with a guide duct 220 . Both ends of the guide duct 220 communicate with the intake port 121A and the intake opening 210 . Accordingly, air sucked into the casing 100 by the guide duct 220 may be guided into the treatment tank 200 .

In addition, an ozone generating unit 300 is installed inside the casing 100 . The ozone generating unit 300 is used to remove odors in the air discharged from the treatment tank 200, that is, odors generated during fermentation and decomposition of food waste in the treatment tank 200. generate ozone.

In addition, an ozone decomposition unit 400 is installed inside the casing 100. The ozone decomposition unit 400 serves to decompose and remove the ozone generated in the ozone generating unit 300 and remaining in the air into oxygen. Substantially, air from which ozone has been removed by the ozone decomposition unit 400 is discharged to the outside of the casing 100 .

In this embodiment, the blowing unit 500 is provided inside the casing 100 . The blowing unit 500 causes the air sucked into the casing 100 to pass through the treatment tank 200 and then flow to be discharged to the outside of the casing 100 . The blowing unit 500 may be disposed between the ozone decomposition unit 400 and the exhaust port 121B, for example. In practice, the suction port of the blowing unit 500 communicates with the ozone decomposition unit 400, and the outlet port of the blowing unit 500 communicates with the exhaust port 121B. Therefore, the air sucked into the casing 100 through the intake port 121A sequentially passes through the treatment tank 200, the ozone generating unit 300, the ozone decomposition unit 400, and the blowing unit 500. After passing through, it is discharged to the outside of the casing 100 through the exhaust port 121B.

Meanwhile, although not shown, a suction opening may be formed in at least one of the ozone generation unit 300 and the ozone decomposition unit 400, similarly to the treatment tank 200. In this way, when the intake opening is formed in at least one of the ozone generating unit 300 and the ozone decomposition unit 400, the intake opening is also inside the ozone generating unit 300 and the ozone decomposition unit 400. The air sucked through (121A) can be sucked in.

A deodorizing unit 1000 is installed in the casing 100 . The deodorizing unit 1000 removes odors in the air discharged to the outside of the treatment tank 200 by the blowing unit 500, that is, in the process of fermenting and decomposing food waste in the treatment tank 200. Eliminate odors that arise. To this end, in this embodiment, the deodorizing unit 1000 includes a deodorizing tank 1100 and first and second deodorizing units 1200 and 1300 .

Referring to FIG. 4 , the deodorization tank 1100 is detachably mounted below the casing 100, and air discharged to the outside of the treatment tank 200 is inside the deodorization tank 1100. A flow path 1100P through which is flowed is defined. The first and second deodorizing units 1200 and 1300 are detachably coupled to the deodorizing tank 1100 . The first deodorizing unit 1200 supplies a deodorizing component into the air sucked into the treatment tank 200, and the second deodorizing unit 1300 supplies a deodorizing component to the outside of the treatment tank 200. Filters odor components in the air. In addition, in the present embodiment, the first deodorizing unit 1200 discharges the air discharged to the outside of the treatment tank 200, substantially into the air filtered by the second deodorizing unit 1300. Also supplies deodorizing ingredients.

More specifically, the deodorization tank 1100 includes a tank body 1110 and a tank cover 1120 coupled to each other to define the flow path 1100P therein. The tank cover 1120 may be formed in a polyhedral shape with an open upper surface, for example, a hexahedron shape. The tank cover 1120 is formed in, for example, a rectangular plate shape and coupled to the upper surface of the tank body 1110 . And, when the tank cover 1120 is coupled to the tank body 1110, the flow path 1100P is defined by both.

An exhaust hole 1111 is formed on the bottom surface of the tank cover 1120 , and an intake hole 1121 is formed in the tank cover 1120 . The intake hole 1121 is a place where the air discharged to the outside of the treatment tank 200 is sucked into the flow path 1100P, and the exhaust hole 1111 flows through the flow path 1100P. This is where air is discharged to the outside of the flow path 1100P. Therefore, the air discharged to the outside of the treatment tank 200 is sucked into the flow path 1100P through the intake hole 1121, flows through the flow path 1100P, and passes through the exhaust hole 1111. through which it is discharged to the outside of the flow path 1100P.

Particularly, in the present embodiment, part of the air sucked into the flow path 1100P through the air intake hole 1121 passes through the second deodorizing unit 1300 while filtering out odorous components, and the exhaust air It is discharged to the outside of the flow path 1100P through the hole 1111. In addition, the rest of the air sucked into the flow path 1100P through the air intake hole 1121 passes through the second deodorizing part 1300, and after the odor components are filtered, the first deodorizing part 1200 It is discharged to the outside of the flow path 1100P through the exhaust hole 1111 while passing through the deodorizing component.

Hereinafter, for convenience of explanation, the air discharged to the outside of the flow path 1100P through the exhaust hole 1111 in a state in which odor components are filtered while passing through the second deodorizing unit 1300 is referred to as first air, After the odor component is filtered while passing through the second deodorizing portion 1300, the outside of the flow path 1100P passes through the exhaust hole 1111 while passing through the first deodorizing portion 1200 and containing the deodorizing component. The air discharged is called secondary air.

Meanwhile, the tank body 1110 includes a depression 1113. The recessed portion 1113 is formed by recessing a portion of the bottom surface of the tank body 1110 where the exhaust hole 1111 is disposed into the flow path 1100P. And, the mixing space 1113S is defined by the depression 1113 . The mixing space 1113S is a place where the first and second air discharged through the exhaust hole 1111 are mixed.

In addition, a guide rib 1115 is provided on the bottom surface of the tank body 1110 . The guide ribs 1115 guide the second air to the first communication opening 1211A to be described later so that the second air is sucked into the first desorption part 1200, and is composed of a pair. In particular, the guide rib 1115 is arranged so that the distance between the other end adjacent to the first communication opening 1211A is relatively reduced compared to the distance between one end adjacent to the second breakaway portion 1300. Therefore, the flow rate of the second air guided from the second deodorizing part 1300 to the first deodorizing part 1200 by the guide rib 1115 is gradually increased, so that the second air more quickly 2 It can be sucked into the deodorizing unit 1300.

In addition, a plurality of fixing bosses 1117 are provided on the tank body 1110 . The fixing boss 1117 is formed by recessing a part of the bottom surface of the tank body 1110 into the flow path 1100P, and is for fixing the second extraction part 1300 .

Meanwhile, a seating opening 1123 is formed in the tank cover 1120 . The seat opening 1123 is formed by cutting a portion of the tank cover 1120 corresponding to the space between the intake hole 1121 and the exhaust hole 1111, more specifically, between the guide ribs 1115. . The first desorption part 1200 is seated in the seating opening 1123 .

In a state where the first decoupling part 1200 is seated in the seating opening 1123, at least a part of it is exposed on the flow path 1100P, and the second desorption part 1300 is positioned on the flow path 1100P. is disposed inside the flow path 1100P so as to be located upstream of the first deodorizing part 1200 in the direction in which the air flows. Substantially, the first air passes through only the second deodorizing portion 1300, and the second air passes through not only the second deodorizing portion 1300 but also the first deodorizing portion 1200 exposed on the flow path 1100P. Some of the also pass through.

More specifically, the first deodorizing unit 1200 includes a deodorizing container 1210 and a deodorizing member 1220 . A storage space 1210S is defined inside the deodorizing container 1210, and a supply opening 1213A and first and second communication openings 1211A and 1211B are formed in the deodorizing container 1210. The deodorizing member 1220 includes a deodorizing component stored in the storage space 1210S and volatilized into the air. As the deodorizing member 1220, a well-known deodorizing component formed in various shapes such as a ball shape may be used.

In this embodiment, the deodorizing component of the deodorizing member 1220 may be volatilized through the supply opening 1213A and supplied to the air sucked into the treatment tank 200 . In addition, the deodorizing component volatilized from the deodorizing member 1220 passes through the second deodorizing part 1300 while flowing through the flow path 1100P, and then passes through the first and second communication openings 1211A and 1211B. Through this, the air passing through the storage space 1210S, that is, is supplied into the second air.

In addition, the deodorizing container 1210 includes a container body 1211 , a container cover 1213 and a partition plate 1215 . The container body 1211 is formed in a cylindrical shape with an open upper surface, and the first and second communication openings 1211A and 1211B are formed in the container body 1211 . The first and second communication openings 1211A and 1211B may be formed by cutting a lower portion of a rim surface of the container body 1211 that faces the guide rib 1115 , respectively. The container cover 1213 is formed in a disk shape of the container body 1211 and has the supply opening 1213A. The supply opening 1213A may be formed by cutting a portion of the container cover 1213 facing the intake port 121A. When the container cover 1213 is coupled to the upper surface of the container body 1211, the storage space 1210S is defined between them. The partition plate 1215 partitions the storage space 1210S into first and second storage spaces 1210S1 and 1210S2. The first storage space 1210S1 communicates with the supply opening 1213A, and the second storage space 1210S2 communicates with the first and second communication openings 1211A and 1211B. For example, the partition plate 1215 is formed in a disk shape to partition the storage space 1210S in a horizontal direction, and the upper portion of the storage space 1210S corresponding to the upper part of the partition plate 1215 A portion is defined as the first storage space 1210S1, and the remainder of the storage space 1210S corresponding to the lower portion of the partition plate 1215 is defined as the second storage space 1210S2.

Meanwhile, the second deodorizing unit 1300 includes a deodorizing frame 1310 and an activated carbon member 1320. The deodorizing frame 1310 defines the appearance of the second deodorizing part 1300, and the two surfaces facing the direction in which air flows inside the flow path 1100P allow air to flow in and out. Some or all of them may be open. The activated carbon member 1320 is fixed inside the deodorizing frame 1310 and serves to substantially filter odor components in the air. In addition, a fixing hole (not shown) into which the fixing boss 1117 is inserted is formed in the deodorizing member 1220 and the activated carbon member 1320 .

Hereinafter, the operation of the food waste disposer according to an embodiment of the present invention will be described in detail.

First, food waste introduced into the treatment tank 200 is fermented and decomposed by microorganisms inside the treatment tank 200 . When the blowing unit 500 operates, the air sucked into the casing 100 through the intake port 121A is supplied to the inside of the treatment tank 200 through the intake opening 210 .

Next, the air supplied to the inside of the treatment tank 200 passes through the ozone generation unit 300 together with the odor generated in the process of treating food waste, and the odor is removed by ozone. In addition, the air from which the odor is removed in the ozone generating unit 300 passes through the ozone decomposition unit 400, and the ozone remaining therein is removed, and the air is discharged from the casing 100 through the exhaust port 121B. discharged to the outside

In the present embodiment, the deodorizing unit 1000, substantially the first deodorizing unit 1200, supplies deodorizing ingredients into the air sucked into the treatment tank 200 by the blowing unit 500. More specifically, the deodorizing component of the deodorizing member 1220 stored in the first storage space 1210S1 is volatilized through the supply opening 1213A and supplied into the air supplied to the inside of the treatment tank 200.

Meanwhile, in the present embodiment, the air discharged to the outside of the treatment tank 200 is sucked into the flow path 1100P through the intake hole 1121 and flows through the flow path 1100P while the second deodorizing unit ( 1300) or the first and second deodorizing parts 1200 and 1300, and then discharged to the outside of the flow path 1100P through the exhaust hole 1111. In other words, a portion of the air sucked into the flow path 1100P through the intake hole 1121, that is, the first air, passes through the second deodorizing unit 1300 to filter out odor components in the air. Then, it is discharged to the outside of the flow path 1100P through the exhaust hole 1111. The rest of the air sucked into the flow path 1100P through the intake hole 1121, that is, the second air, while passing through the second deodorizing part 1300, in a state in which odor components are removed, the first air While passing through the deodorizing unit 1200, the deodorizing component is discharged to the outside of the flow path 1100P through the exhaust hole 1111 in a state of containing the deodorizing component. In this way, the first and second air discharged through the exhaust hole 1111 are mixed while flowing in the mixing space 1113S.

As described above, in this embodiment, only a part of the air that has passed through the second deodorizing unit 1300 is mixed with the air that has passed only through the second deodorizing unit 1300 after passing through the first deodorizing unit 1200, A phenomenon in which the air finally discharged to the outside of the flow path 1100P is excessively affected by the deodorizing component generated in the first deodorizing unit 1200 can be prevented. In particular, when the deodorizing member 1220 includes a directional component, all of the air that has passed through the second deodorizing part 1300 passes through the first deodorizing part 1200 through the exhaust hole 1111. Exhausted air may be excessively scented, which may have the adverse effect of giving a user discomfort. However, in the case of the present embodiment, only a portion of the air flowing through the flow path 1100P includes a deodorizing component, so that proper adjustment is possible.

Within the scope of the basic technical idea of the present invention, other modifications are possible for those skilled in the art, and the scope of rights of the present invention should be interpreted based on the attached utility model registration claims. will be.

100: casing 200: treatment tank
300: ozone generating unit 400: ozone decomposition unit
500: blower unit 1000: deodorization unit
1100: deodorization tank 1200: first deodorization unit
1300: second desorption unit

Claims (11)

Casing 100 defining the appearance;
a treatment tank 200 located inside the casing 100 and fermenting and decomposing the food waste stored therein by microorganisms;
a blowing unit 500 for flowing air to be sucked in and discharged into and out of the treatment tank 200; and
A first deodorizing unit 1200 for supplying deodorizing components to the air sucked into the treatment tank 200 and at least one second deodorizing filter for filtering odor components in the air discharged to the outside of the treatment tank 200 a deodorizing unit 1000 comprising a portion 1300; Food waste disposer comprising a.
According to claim 1,
The deodorizing unit 1000 further includes a deodorizing tank 1100 detachably mounted on one side of the casing 100 and to which the first and second deodorizing parts 1200 and 1300 are detachably coupled. food waste disposer.
According to claim 2,
The deodorization tank 1100,
a tank body 1110 formed in a polyhedral shape with an open top surface and an exhaust hole 1111 formed on a bottom surface of the tank body 1110; and
a tank cover 1120 coupled to an upper surface of the tank body 1110 to define a flow path 1100P together with the tank body 1110 and having the intake hole 1121 formed therein; including,
The air discharged to the outside of the treatment tank 200 is sucked into the flow path 1100P through the intake hole 1121, flows through the flow path 1100P, and passes through the exhaust hole 1111. Food waste disposal machine discharged to the outside of the flow path (1100P).
According to claim 3,
The first desorption portion 1200 is seated on a seating opening 1123 formed in the tank cover 1120 so that a portion thereof is exposed on the flow path 1100P,
The second deodorizing part 1300 is disposed inside the flow path 1100P so as to be located upstream of the first deodorizing part 1200 in a direction in which air flows through the flow path 1100P,
A part of the air sucked into the flow path 1100P through the intake hole 1121 passes through the second deodorizing part 1300, and the odor is filtered through the exhaust hole 1111 through the flow path ( 1100P) and the remainder of the air sucked into the flow path 1100P through the air intake hole 1121 passes through the second deodorizing part 1300, while the odor is filtered out of the first air passage 1100P. The food waste disposer is discharged to the outside of the flow path 1100P through the exhaust hole 1111 in a state in which the deodorizing ingredient is supplied while passing through the deodorizing unit 1200.
According to claim 4,
The tank body 1110 is provided with a recessed portion 1113 formed by recessing a portion of the bottom surface of the tank body 1110 where the exhaust hole 1111 is disposed into the flow path 1100P,
The air passing through only the second deodorizing portion 1300 discharged through the exhaust hole 1111 by the depression 1113 and the first and second deodorizing portions discharged through the exhaust hole 1111 ( 1200) A food waste disposer in which a mixing space 1113S in which air passing through 1300 is mixed is defined.
According to claim 3,
The first deodorizing part 1200,
A storage space 1210S is defined therein, and a supply opening 1213A communicating with the intake port 121A and first and second communication openings 1211A and 1211B communicating with the flow path 1100P are formed. odor container 1210; and
a deodorizing member 1220 stored in the storage space 1210S and including a deodorizing component volatilized into the air; including,
The deodorizing component of the deodorizing member 1220 is volatilized through the supply opening 1213A and supplied to the air sucked into the treatment tank 200, or flows through the flow path 1100P to the second deodorizing unit. After passing through 1300, the air passing through the storage space 1210S is supplied through the first and second communication openings 1211A and 1211B.
According to claim 6,
The deodorization container 1210,
a container body 1211 formed in a cylindrical shape with an open upper surface and having the first and second communication openings 1211A and 1211B formed therein;
A container cover 1213 coupled to an upper surface of the container body 1211 to define the storage space 1210S together with the container body 1211 and having the supply opening 1213A formed therein; and
The storage space 1210S is divided into a first storage space 1210S1 communicating with the supply opening 1213A and a second storage space 1210S2 communicating with the first and second communication openings 1211A and 1211B. a partition plate 1215 to do; Food waste disposer comprising a.
According to claim 6,
A pair of guide ribs 1115 are provided on the bottom surface of the tank body 1110 to guide the air passing through the second deodorization part 1300 to the first communication opening 1211A.
According to claim 8,
The guide rib 1115 is arranged so that the distance between the other end adjacent to the first communication opening 1211A is relatively reduced compared to the distance between one end adjacent to the second decoupling part 1300. .
According to claim 3,
The second deodorizing part 1300,
a deodorizing frame 1310 defining the appearance of the second deodorizing part 1300; and
an activated carbon member 1320 fixed inside the deodorizing frame 1310 and filtering malodorous components in the air; Food waste disposer comprising a.
According to claim 10,
A fixing boss 1117 formed by recessing a part of the bottom surface of the tank body 1110 into the flow path 1100P is provided,
A food waste disposer in which a fixing hole into which the fixing boss 1117 is inserted is formed in the deodorization frame 1310 and the activated carbon member 1320.

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