KR20190063507A - Photo-catalyzer filter unit and Food sweepings annihilating apparatus using the same - Google Patents

Abstract

The present invention relates to a deodorizing container having a photocatalytic filter, comprising: a filter pipe which has both sides open; at least one photocatalytic filter which is mounted on the inside of the filter pipe, is a plate shape and has a plurality of gas permeation holes therein; and a lamp inserting hole which is formed in the photocatalytic filter. In particular, the present invention has a structure capable of being applied to a food waste disposing and processing device in an applicable field, and uses a deodorizing container having the photocatalytic filter to solve efficiently deodorization problems in a small-sized device used at home or in a store. According to the present invention, for a deodorizing system for deodorization, the present invention has a deodorizing container having a simple structure and a photocatalytic filter which maximizes a contacting area with harmful gases and has a very simple installation structure, thereby maximizing a deodorizing efficiency and providing convenience in installation and maintenance.

Description

{Photo-catalyzer filter unit and food sweepings annihilating apparatus using the same}

The present invention relates to a deodorizing container having a photocatalytic filter, and more particularly, to a deodorizing system for deodorizing a deodorizing container having a simple structure and maximizing a contact area with a noxious gas, The present invention relates to a deodorizing container which is provided with a photocatalytic filter to maximize deodorization efficiency and provide excellent convenience in installation and maintenance. Particularly, as a more specific application field, there is a food waste disposal apparatus capable of remarkably improving a deodorizing and purifying function by applying a deodorizing container as a structure for filtering the food decomposition noxious gas generated during the decomposition of food, The present invention relates to a deodorizing container applicable to a device.

Generally, the photocatalyst is optically excited by irradiation of light having an energy of a band gap or more, and generates electrons and holes. Part of the electrons and holes move to the surface of the photocatalyst and decompose and remove harmful substances in the air and water. The photocatalyst functions efficiently as the contact area with the substance to be decomposed is large and the energy of light irradiated within a predetermined range is large.

As a typical photocatalyst, titanium oxide can be mentioned. A light such as sunlight, a black light, a xenon lamp, a mercury lamp, a sodium lamp, an incandescent lamp, or a cold cathode discharge tube is irradiated to a photocatalyst such as titanium oxide, It is possible to perform filtering by adsorbing and decomposing harmful substances, purifying the water, purifying the air, and sterilizing or sterilizing the pollutants.

In addition, the photocatalyst is fixed to a base material for easy handling. As the substrate on which the photocatalyst is fixed, for example, paper, cloth, polymer resin, steel, glass fiber, or the like is used for air cleaning and deodorization. It is known that a substrate selected from the above is coated with a photocatalyst by forming a honeycomb shape, a solid wing shape, an exposure type optical fiber filter, or the like, as a filter of an air cleaner / deodorizer. In addition, as the base material, a sorbent material such as a ceramic calcining material, zeolite, activated carbon, silica gel or the like is used for water purification and sterilization. Such a substrate coated with a photocatalyst is known as a filter of a water quality purification apparatus and sterilizing purification apparatus.

 However, due to its chemical nature, photocatalyst decomposes not only harmful substances but also organic substances such as base materials, cloths, and polymer resins. In addition, paper, cloth, polymer resin and the like are deteriorated by ultraviolet rays and deteriorated. In a serious case, the photocatalytic film may be peeled off because the paper or cloth absorbs moisture.

Accordingly, the photocatalyst member made of paper, cloth, polymer resin, or the like has poor durability and short life span, so that the decomposition performance as a photocatalyst is deteriorated, resulting in an increase in manufacturing cost and a problem of lowering the production yield.

The conventional photocatalytic filter of FIG. 1 will be described by way of example.

The conventional photocatalytic filter basically comprises a filter tube 10 having a tubular shape and having a plurality of connection rings 20 formed at intervals of 90 degrees along an outer circumferential surface thereof, A plurality of purifying fins 11 arranged radially in the center direction and coated with a photocatalyst on the surface thereof, a connecting pin 30 inserted into the connecting ring 20, and a plurality of filter tubes 10 arranged to form heat And a fixing means 40 mounted at an end of the filter tube 10 and fixing an ultraviolet lamp penetrating the inner center of the filter tube 10. The fixing means 40 has a hexahedron shape coupled to both ends of the filter tube 10 And a through hole 41 penetrating through the center of the filter tube 10 is formed on one side of the filter tube 10. An insertion groove 42 recessed by a predetermined depth in the cross- (10) is inserted and fixed. In addition, a fixing portion 43 is formed at the center of the through-hole 41 so that the ultraviolet lamp is electrically connected to the external power source and fixed at the same time.

In the above structure, the gas is circulated into the filter tube, and the decomposition of the noxious gas is performed through the photocatalyst filter applied inside.

However, in the conventional photocatalytic filter as described above, it is necessary to design the base material in a complex shape in order to increase the contact area with the material to be degraded in a steel-based photocatalytic material, There arises a problem that the manufacturing cost rises. In addition, when such a filter structure is installed in a small equipment such as a home or business, and is required to be repaired during use, in reality, even if the inside of the photocatalytic filter is defective and its degree is very small, There is a problem that maintenance and repair are significantly increased in cost and cost. In particular, since the cleaning pin, which is a part to be filtered, has a rectangular plate member in a radial shape, the contact area between the circulating gas and the photocatalytic filter is very narrow and the gas passes through the filter tube in a short time, .

Further, the above-mentioned photocatalytic filter is produced in a complicated shape, so that light is not uniformly irradiated to each photocatalyst particle. In addition, in the photocatalytic filter made of an exposure type optical fiber filter including the above-mentioned photocatalytic filter, in order to widen the contact area, the density increases and the light transmittance decreases. On the other hand, in order to improve the light transmittance, A sufficient contact area can not be ensured due to the problem of laminar entanglement, and therefore there is a limit to the efficient decomposition of the substance to be decomposed by the photocatalyst.

In particular, in the case of a purifying filter for use in a purification system for decomposing harmful gas generated during decomposition of a food, for example, a food waste disposal device for home or business that has become a household appliance indispensable to the recent generation, However, the purification system applied to a factory or a large-sized appliance is relatively reduced, and the function of the filter is remarkably deteriorated. Further, it takes a lot of time and money to maintain the filter. , And when a small-size purification system used for home or business use is required, it shows a lot of cost and efficiency problems.

The object of the present invention is to provide a deodorizing container capable of simplifying a deodorizing structure for decomposing and purifying noxious gases and simplifying maintenance repair and maintenance and improving the versatility of its application .

More specifically, it is an object of the present invention to provide a deodorization system for deodorization, in which a deodorizing tube having a simple structure is provided with a photocatalytic filter having a very simple installation structure while maximizing a contact area with harmful gas, And to provide excellent convenience for maintenance.

In order to realize the above-described object, the present invention provides a filter tube having both side openings; A plate-shaped photocatalytic filter mounted in the filter tube at least at one or more times and having a plurality of gas-permeable holes; A lamp insertion hole formed in the photocatalytic filter; The present invention provides a deodorizing container having a photocatalytic filter. Furthermore, the structure for disposing the photocatalytic filter and the auxiliary supporting filter are provided, so that the convenience of installation and maintenance can be remarkably improved.

Particularly, in a field of its application, a deodorizing container having the above-described photocatalytic filter can be applied to a food garbage disposing device or a drying device for treating food and drying, and the deodorization problem in small household appliances or small appliances So that it can be solved efficiently.

According to the present invention, in a deodorization system for deodorization, a deodorizing tube having a simple structure is provided with a photocatalytic filter having a very simple installation structure while maximizing the contact area with harmful gas, thereby maximizing deodorization efficiency and improving installation and maintenance Thereby providing an excellent convenience.

It is an object of the present invention to provide an apparatus for disposing a food garbage with a deodorizing container or a device for drying a food waste to provide an economical food garbage disposal device capable of achieving convenience of maintenance and maximization of deodorization efficiency in a deodorization system in a small household appliance There is also an effect.

1 is a view showing the structure of a conventional photocatalytic filter.
2 is a view showing a structure of a photocatalytic filter according to the present invention.
FIGS. 3A to 3C are diagrams illustrating the arrangement of a photocatalytic filter according to the present invention.
FIGS. 4A to 4E and FIGS. 5 to 6 illustrate application examples of the photocatalytic filter according to the present invention to a food waste treatment apparatus.
FIG. 7 is a view showing another application example of a food processing apparatus to which the photocatalytic filter according to the present invention is applied.

The present invention relates to a filter tube having both side openings; A plate-shaped photocatalytic filter mounted in the filter tube at least at one or more times and having a plurality of gas-permeable holes; A lamp insertion hole formed in the photocatalytic filter; A deodorizing system having a simple and simple structure can be realized by maximizing the contact area between the noxious gas and the filter to improve the deodorization efficiency and to improve convenience in maintenance Let the song be increased.

Further, the present invention is characterized in that the photocatalytic filter further comprises an auxiliary supporting filter which is spaced apart from other filters adjacent to each other, wherein the contact area between the noxious gas and the filter is Widening,

It is possible to maximize the deodorization efficiency by forming a photocatalyst material in the auxiliary supporting filter itself. In addition, the auxiliary support filter can be formed in various shapes, and the photocatalytic filter can be supported to maintain a constant gap, so that the distribution of the noxious gas can be smoothly performed.

In the present invention, the auxiliary support filter is formed on at least one or more outer peripheral side surfaces of the photocatalytic filter. The deodorizing container is provided with a photocatalytic filter, So that appropriate intervals can be maintained. As a result, the contact area between the noxious gas and the filter is widened, and the staying time of the gas within the secured separation interval is secured, thereby maximizing the deodorization efficiency.

Further, the present invention provides a deodorizing bar having a photocatalytic filter, wherein the auxiliary supporting filter is a plate-shaped one having an opening inside and a surface of an auxiliary supporting filter formed in a mesh shape, A decomposable photocatalyst material is formed so that a deodorizing effect can be realized.

Further, the present invention provides a deodorizing bar equipped with a photocatalytic filter, wherein the cross-sectional surface of the auxiliary support filter has the same or different shape as the cross-sectional shape of the photocatalytic filter, Shape.

The auxiliary support filter is integrally formed on the lower surface of the photocatalytic filter. The auxiliary support filter can be manufactured as a separate type by providing a deodorizing container having a photocatalytic filter. In addition, So that the installation efficiency can be improved.

Further, in the present invention, a second auxiliary supporting filter is further formed inside the opening of the auxiliary supporting filter, thereby maximizing the contact area between the noxious gas and the photocatalytic filter. .

Further, in the present invention, the second auxiliary support filter is provided with at least one or more thin plate-like mesh filter members arranged in a direction perpendicular to the transverse section of the auxiliary support filter, And the photocatalytic filter can be maximized.

In addition, the present invention is characterized in that the second auxiliary supporting filter is arranged such that at least one or more thin mesh filter elements are arranged at an acute angle with the transverse section of the auxiliary supporting filter, and the second auxiliary supporting filters forming the respective acute angles are horizontal The deodorizing tank is provided with a photocatalytic filter. The deodorization efficiency of the photocatalytic filter is increased by increasing the contact area between the photocatalytic filter and the noxious gas.

In addition, the present invention provides a deodorization barrel having a photocatalytic filter, wherein the filter tube is coated with a reflective material for reflecting light on the inner surface, thereby enhancing optical efficiency provided by the photocatalyst material.

Further, in the present invention, the filter tube is provided with a latching jaw for fixing the photocatalytic filter, so that the photocatalytic filter can be fixed with a more stable structure.

In addition, the present invention provides a deodorizing bar equipped with a photocatalytic filter, wherein the catching jaw is formed with a concave groove at a central portion of a catching jaw of the filter tube, so that the photocatalytic filter can be fixed with a more stable structure .

Further, the present invention provides a deodorizing bar having a photocatalytic filter, wherein the photocatalytic filters formed in the filter tube are arranged at uniform or non-uniform intervals, The efficiency of the gas circulation structure and the improvement of the deodorizing function are matched with each other so that high efficiency can be exhibited.

In addition, the present invention provides a deodorizing container having a photocatalytic filter, wherein the photocatalyst is TiO2.

The present invention also provides a food garbage disposal apparatus including a food waste accommodating portion inside a storage portion and a purifier for purifying decomposed gas generated in the storage portion,

The photocatalyst filter according to claim 1, wherein the purifier comprises: a filter tube having both side openings; a plate-shaped photocatalytic filter mounted on at least one of the filter tubes and having a plurality of gas-permeable holes; And a deodorizing container having a deodorizing container provided with a deodorizing container. The deodorizing device can be improved in efficiency of a deodorizing system in a device for destroying a food used for a home or business.

In addition, the photocatalytic filter used in the food disappearance apparatus of the present invention can utilize the structure of the photocatalytic filter, which is an embodiment of the present invention described above. And an auxiliary supporting filter for separating the other filters from the neighboring filters. The present invention further provides an apparatus for treating food waste, which maximizes a contact area between a noxious gas and a photocatalytic filter.

Further, the auxiliary support filter used in the food disappearance processor of the present invention is provided with at least one or more at least one outer peripheral side surface of the photocatalytic filter.

Further, it is possible to provide a device for annihilating a food waste, characterized in that the auxiliary support filter used in the food disappearance processor of the present invention is a plate-shaped one whose interior is opened and the surface of the auxiliary support filter is mesh-shaped.

In addition, the cross-sectional surface of the auxiliary support filter used in the food disappearance apparatus of the present invention has the same or different shape as the cross-sectional shape of the photocatalytic filter.

Further, the auxiliary support filter used in the food disappearance processor of the present invention is integrally formed on the lower surface of the photocatalytic filter, thereby providing a device for destroying the food. In addition, the auxiliary supporting filter used in the food disappearance processor of the present invention may further include a second auxiliary supporting filter in the opened interior thereof.

The apparatus for destroying food waste according to the present invention may further comprise an ozone treatment unit for sterilizing the gas flowing in the accommodation unit. The structure and function of the present invention will be described in detail.

The structure of the photocatalytic filter according to the present invention will be described with reference to FIGS. 2A to 2H. 2A to 2H schematically show the shapes of the photocatalytic filters 110a and 110b and the auxiliary supporting filters 140a to 140c mounted inside the filter tube 100 shown in FIG.

As shown in FIG. 2A, the photocatalytic filter proposed in the present invention can be basically formed into a mesh structure in which a circular gas through hole 120 is formed, or a plate-like structure in which a gas through hole is formed in a circular plate. Of course, the shape of such a photocatalytic filter can be variously manufactured including a circular shape. In order to illustrate a shape that can be matched with the shape of the cross section of the filter tube 100, a disc shape is presented in this embodiment have. Of course, various compounds can be used as the photocatalyst material to be applied to the photocatalytic filter, but more preferably, a material containing a titanium compound can be coated. The photocatalytic filter may be formed of a metal material or other synthetic material. Preferably, the photocatalytic filter is made of Al, and the photocatalyst can be coated by a method of oxidizing and coating titanium on the aluminum. In this case, the photocatalyst material may be formed of TiO2.

A lamp inserting hole 130 is formed in the center of the photocatalytic filter 110a so that the lamp can be inserted therein. The lamp inserting hole is formed in the center of the lamp inserting hole. However, in order to maximize the light efficiency, Two or more of them may be formed. A light source for providing a light source to the photocatalyst is inserted into the lamp insertion hole. Various light sources such as a fluorescent lamp, a black light, a xenon lamp, a mercury lamp, a sodium lamp, and an incandescent lamp are applicable. In order to improve the light efficiency, it is preferable that a reflection material is coated on the inside of the filter tube when the lamps emit light, so that light emitted from the light source is reflected to improve the light efficiency.

As shown in FIG. 2B, the present invention shows an example of the auxiliary supporting filter 140a. In the present invention, the auxiliary supporting filter is formed by forming the photocatalytic filters formed at the lower end of the above-mentioned photocatalytic filter, . In this case, the auxiliary support filter has a cylindrical structure hollowed out so that the inside, the top and bottom of the filter pass through it, but this is an example, and the auxiliary filter may have various structures such as a regular tetrahedron, a cube, and an octahedron. Further, it is possible to form a simple planar support portion not a polyhedral structure. Particularly, in this embodiment, the outer surface of the auxiliary supporting filter is formed into a mesh shape, and a photocatalyst material is coated on the outer surface of the auxiliary supporting filter so that the contact area between the harmful gas and the photocatalyst material can be further increased.

As shown in FIG. 2C, the auxiliary support filter may be integrally formed with the photocatalytic filter, or may be formed as a separate type.

As shown in FIG. 2d, the auxiliary support filter may include a separate second auxiliary support filter 140b therein. That is, the second auxiliary support filter 140b can be used as an auxiliary support filter itself, and can be modified and used in combination with the inside of the auxiliary support filter described above.

2E shows a structure in which the auxiliary supporting filter 140a and the second auxiliary supporting filter 140b are combined to couple the second auxiliary supporting filter into the auxiliary supporting filter.

The second auxiliary support filter 140b may have various structures. For example, it may be formed in the same shape as the auxiliary supporting filter but in a smaller diameter and spaced apart from the auxiliary supporting filter, or may be formed of a thin flake mesh member such as the second auxiliary supporting filter And can be formed by applying a photocatalyst material to the mesh-like member itself.

In the illustrated structure, the thin laminas have a structure in which the thin laminas cross each other at right angles. However, the laminar structure may be formed by changing the thin laminas so as to form an acute angle instead of a vertical intersection and obliquely intersecting each other. That is, when the thin plate-shaped mesh filter element takes into account the cross-sectional surface of the auxiliary support filter, the skew is formed at an acute angle with the cross-section, in which case the respective mesh filter elements are preferably spaced horizontally.

As shown in FIGS. 2F and 2G, the auxiliary support member 140c may be formed in the photocatalytic filter 110b so as to have at least one or more outer peripheral surfaces. Of course, this case can be applied to a photocatalytic filter formed as a mesh type, and it can be manufactured by applying a photocatalytic filter to a plate-like member as shown, and forming a gas-permeable hole on the plate surface. Of course, the position of the auxiliary support member 140c may be changed to the lower side of the photocatalytic filter rather than the outer surface.

2h illustrates the structure of a photocatalytic filter according to another embodiment of the present invention. As shown in the figure, the photocatalytic filter 110 is provided with a lamp insertion hole 130 at the center thereof, and is formed into a shape having a plurality of rotation blades 150 radially outwardly with the lamp insertion hole as a central axis. It is possible. Preferably, the rotary vane is formed in a vane shape so as to be rotatable when air flows in and out. The rotating blade 150 may be formed of a rotating blade 160 or a rotating blade 150. The rotating blade and the rotating surface of the photocatalytic filter may be coated with a photocatalyst material.

The structure of the photocatalytic filter having the rotating blades and the rotating surface enables the air and the side noxious gas to have the maximum residence time and the transfer distance at a short distance, thereby maximizing the reaction time with the photocatalyst and increasing the deodorizing effect . In addition, it is possible to increase the contact area of the coated area by allowing the flow of air to be rotated by a vane-like structure.

In this case, a gas-permeable hole may be formed on the side surface of the rotary vane so that the flow of the gas can be smoothly continued. Of course, the photocatalytic filter having such a structure may include the above-described auxiliary support filter. In this case, it is preferable that at least one auxiliary support filter 140 is provided on the outer circumferential surface of the photocatalytic filter.

3A to 3D, a structure for mounting the photocatalytic filter of the present invention to a filter tube will be described.

3A, the photocatalytic filter 110a according to the present invention is formed in a laminated structure inside the filter tube 110, and an auxiliary supporting member 140b is formed between the respective photocatalytic filters, Can be formed. The photocatalytic filter and the auxiliary supporting filter applied in this case can be applied to various structures shown in Fig. Basically, it is possible to form a stable arrangement by the laminated structure of the photocatalytic filter and the auxiliary supporting member. However, it is possible to form the catching jaws 101 on the inner surface of the filter tube, and furthermore, So that the photocatalytic filter can be fixed. Even if the filter tube is vertically erected, it is possible to eliminate the possibility that the laminated structure is compressed downward due to an external force such as gravity vertically due to the action of the auxiliary support filter and the latching jaw, Structure can be provided.

Particularly, in the arrangement of the photocatalytic filter, it is possible to use the auxiliary supporting filter uniformly to uniformly apply the spacing distance, but it is also possible to unequally adjust the spacing distance by varying the height of the auxiliary supporting filter in each part Do. In other words, the portion (X) where the noxious gas is first introduced has an auxiliary supporting filter of a lower height to increase the arrangement density of the photocatalytic filter to increase the filtering effect, and to arrange the intermediate portion (Y) It is possible to realize a more efficient purifying effect through the arrangement of the structure for lowering the density.

FIG. 3B is a cross-sectional view of a photocatalytic filter according to an embodiment of the present invention. Referring to FIG. 3B, a lamp insertion hole 130 and a gas permeable hole around the lamp insertion hole 130 are formed in an outer peripheral surface of a photocatalytic filter, Fig. The illustrated lamp is inserted into the lamp insertion hole 130.

FIG. 3C shows a structure in which the photocatalytic filter 110c and the auxiliary support filter 140d are separated from each other by another embodiment of the present invention. Needless to say, such a structure can be diversified by utilizing the filter structure and the auxiliary support filter structure of the various structures described above, and conversions of the same or equivalent category in the present invention are included in the gist of the present invention.

FIG. 3D illustrates a laminated structure of a photocatalytic filter 110d having a structure having a rotary vane as shown in FIG. 2H among the photocatalytic filters of the present invention. When the laminated structure is mounted inside the filter tube, the area of the photocatalyst material coated on the surface of the rotary vane 150 is maximized, and the residence time of the noxious gas in the filter tube due to the rotation of the rotary vane and the contact area So that the contact area between the photocatalyst and the noxious gas can be maximized. Of course, in this case, as described above, the rotational surface 160 having an oblique inclination at the upper surface of the rotary vane is formed and the photocatalyst material is coated to maximize the contact area and residence time of the harmful gas and the photocatalyst have.

1. Application to deodorization system in general food processing system

4, an application example of the deodorizing container including the photocatalytic filter according to the present invention to a device for disposing of food waste will be described.

Generally, the food waste-related processor 200, which accommodates food, which is dried or agitated to be consumed therein, has a basic structure of food storage portion S, and the noxious gas generated in the storage portion is supplied to the outside of the storage portion And is formed into a structure for attracting and deodorizing. In the general structure of the food garbage disposer, which is an application example of the present invention, the gas introduced from the receiving portion passes through the gas inlet pipe 210 leading to the outside, and is introduced into the purifier 230 as the deodorization system. And a motor M for introducing the noxious gas to the outside. And a deodorizing unit 220 for sterilization and deodorization may be installed thereon. And an ozone processing unit 240 for decomposing the generated ozone.

Referring to FIG. 4B, an embodiment in which the detailed configuration of the food waste-related processor 200 can be applied will be described.

FIG. 4B shows a gas inlet pipe 210 through which the harmful gas and odor are introduced into the food garbage receiving part S, and the noxious gas introduced from the gas inlet pipe first flows into the deodorizing unit 220. An ultraviolet wavelength lamp (UVC lamp) 222 is provided inside the deodorization processing unit 220, and a deodorizing effect can be formed due to the strong ultraviolet light generated therein. In particular, a sponge, a glass wool, a fabric, or the like may be used as the air-permeable filler 221 in order to increase the deodorization time by slowing the flow of the harmful gas around the ultraviolet wavelength lamp 222. More preferably, a plurality of fibers are preferably formed.

The noxious gas that has been deodorized in the deodorization processing unit 220 is transferred to the purifying unit 230 according to the present invention. The deodorization process in the deodorization processing unit is performed by decomposing and removing odorous components by ozone synthesized by synthesizing oxygen in the air flowing into the deodorization processing unit 220 from the ultraviolet wavelength lamp into ozone.

The purifier 230 may include a photocatalytic filter 231, which is one of the technical features of the present invention, and may constitute a deodorization system having the structure described in FIGS. 2A to 3D. Of course, the photocatalytic filter 231 is separated from the auxiliary supporting filter 232, and is again deodorized by a photocatalytic reaction using a UVA lamp passing through the center portion, thereby achieving more complete deodorization.

In this case, an ozone processing unit 240 may be further disposed between the deodorization processing unit 220 and the purifying unit 230 to decompose ozone generated in the deodorization processing unit. That is, the ozone used for deodorization is decomposed again so as not to flow out to the outside, so that it can be reduced to oxygen in the air.

The ozone treatment unit 240 further includes an ozone decomposition catalyst 241 for promoting the decomposition of ozone and includes a heating unit 250 for supplying a heat source to prevent moisture from being condensed in the ozone decomposition catalyst, It is possible to maximize the decomposition efficiency. The ozone decomposition catalyst and the heating unit may include a blocking cover (C).

The ozone treatment unit 240 includes an ozone detection sensor for detecting the amount of ozone in the air exhausted to the outside from the outflow portion 242. The ozone detection sensor 240 receives data of the ozone detection sensor The controller 270 may further include a controller 270 for controlling the operation of the heating unit 250. The ozone decomposition catalyst 241 may be coated with a ball core material and the outlet 242 formed in the ozone treatment unit 240 may include an odor detection sensor 280 connected to the control unit 270 May be provided. Further, a fan 290 for discharging purified air may be further provided.

4C shows another embodiment of the breathable filler 221 formed inside the deodorization processing unit 220 of FIG. 4B.

That is, as shown in the drawing, a layer of air-permeable filler 221, such as a metal fiber, having a certain thickness is disposed between the upper and lower portions of the deodorizing processing unit, and a mesh type or porous photocatalytic filter 231 ) May be formed into a cylindrical shape to surround the ultraviolet lamp (UVC), and the metal fiber layer may be formed so as to support the upper metal fiber layer. In this case, odor is removed by ozone due to ultraviolet light, and at the same time, odor can be removed through a photocatalytic filter.

FIG. 4D illustrates a deodorization system having a structure in which two deodorization units are formed by replacing the deodorization unit 220 of FIG. 4B with the deodorization unit of FIG. 4B. Identification codes in the other drawings are the same as those in Fig. 4B. Such a structure is advantageous in that a strong deodorizing effect can be realized by providing a double deodorizing bucket equipped with a photocatalytic filter according to the present invention.

Also, as shown in FIG. 4 (e), when two purifiers are used, the purifying efficiency is remarkably improved to such an extent that the amount of generated ozone is relatively small. In this case, the ozone treatment unit is removed, It is possible.

The deodorizing tube according to the present invention can be applied to a purifying unit applied to a deodorization system in a food waste-related processing system having such a structure.

2. Application to Deodorization System to Food Destruction Processor with Middle Door Another specific application according to the present invention will be described with reference to FIG. 5, a device for disposing food waste (hereinafter referred to as 'the present apparatus') includes a main body 310 having an outer cover C, an intermediate door (not shown) formed inside the main body, 320 and an agitating part stirring the agitating shaft 330 by a motor 340 inside the main body.

The middle door 320 includes a door lever 321 connected to one side of the main body through elastic members 322 so that the middle door 320 can be opened and closed by elasticity. And is connected to an axis 323 fixed to one end.

The motor for rotating the stirring shaft may be installed inside or outside the container. The stirring shaft may be rotated through a driving belt, for example, a drive transmission medium, and the stirring shaft may be provided with a stirring blade to stir the internal material The basic structure is provided. The trunk portion of the main body is formed by collecting food waste, and the food garbage bag is disassembled therein, and the portion where the food garbage is received serves as a disassembling tank.

In the food waste disposal apparatus having such a structure, the deodorizing structure having the structure of FIG. 4 described above can be formed inside. In this case, a deodorizing system according to the present invention can be applied to form a deodorizing system.

3. Application to a food waste disposal apparatus having a structure for opening and closing an intermediate door by cam drive The deodorization system formed by the deodorization cylinder of the present invention is a deodorization system in which the food garbage disposal apparatus of the above- It is also applicable to the extinction device.

Referring to FIG. 6, an embodiment of the present invention shown in FIG. 2 basically includes the main body 10, the intermediate door 20, the stirring shaft 30, and the motor 40, It is formed in a structure that can be automatically opened and closed in a manual opening / closing structure. A unit having a structure capable of automatically opening and closing the middle door is called an intermediate door assembly 400 and includes a driving cam 450 connected to the stirring shaft 30 and a rotary motion of the driving cam And an operation plate 430 as a follower for performing the upward movement.

That is, the intermediate door 20, which is opened down through the driving cam 450 using the rotational force of the stirring shaft 30, is automatically lifted and closed, so that the rotational force in the equipment is used as it is. And it is possible to construct an opening / closing system which is very cheap in facilities cost, but is easy to use. That is, the present invention utilizes the rotational force for rotating the stirring shaft as a power source for the opening / closing operation of the middle door, and basically uses the driving cam to change the rotational motion into linear motion It is a structure that pushes the middle door and closes.

In the case where food waste is opened by opening the outer cover, the stirring shaft 30 is stopped and the middle door 20 is kept closed. do. Further, when the food is put into the upper portion of the middle door and the outer cover is closed, the end portion of the outer cover presses the open switch. When the outer cover is closed, the middle door is opened by pressing the open switch. The shaft is rotated, and the driving cams are simultaneously operated to close the intermediate doors sequentially. In other words, as the driving cam 450 rotates, the distal end portion 440 of the middle door assembly makes a contact movement along the side surface of the driving cam, so that the entire middle door assembly rises and the middle door connected thereto is closed.

In the food waste disposal apparatus having such a structure, harmful gas generated from the inside can be formed and removed from the deodorization system having the structure shown in FIG. 4, and furthermore, the deodorization system according to the present invention can be efficiently and conveniently installed And to perform maintenance.

4. Use in food decomposition or drying device

The deodorizer having the photocatalytic filter according to the present invention can be applied to various devices to which a deodorization system is applied, and can be applied to a device for drying food. A deodorization system for deodorization is inevitably required in an apparatus for drying food in addition to the above-described food disappearance apparatus. In this case, the present invention can be applied to exhibit an efficient deodorizing effect. It goes without saying that the present invention is also applicable to the case where the drying function is incorporated into the above-described food waste disposal apparatus.

The apparatus for disposing food waste according to the present invention may be applied to a food processing apparatus having a deodorization system having a similar structure.

An embodiment in which the ozone system is bonded in the above-described food processing apparatus capable of drying or decomposing food will be described in detail.

Referring to FIG. 7, the apparatus shown in FIG. 7 basically includes a receptacle 510 for receiving food waste to be disassembled or dried, and a control unit 500 connected to the receptacle for removing toxic gases and odors generated in the receptacle A deodorizing tank 520 and an ozone treatment unit 530 connected to one end of the deodorizing barrel so as to introduce air treated in the deodorizing tank. A stirrer (511) for stirring the food may be provided in the accommodating portion.

The above is similar to the above-mentioned general food processing apparatus in that it comprises a receiving portion, a receiving portion for decomposing or drying the food, and a deodorizing container. Furthermore, the deodorizing container, which is a gist of the present invention, is constituted by the laminated structure of the photocatalytic filter constituted by the various embodiments described above.

This shares the technical features of the present invention in that a deodorizing tube formed of the various embodiments described in Figs. 2A to 3D is formed. 7, the deodorizing tube is formed in a structure in which the photocatalytic filter 520a is laminated. Each photocatalytic filter is separated by an auxiliary supporting filter 521. As described above, it is a matter of course that the laminated structure of such a photocatalytic filter can be arranged in the arrangement of the photocatalytic filter as an embodiment of various structures in the present invention. An air outlet 512 may be provided at a portion where the receiving portion and the deodorizing barrel are connected to each other and an air outlet 513 may be provided at a portion connecting the deodorizing barrel 520 and the ozone processor, Further, a fan for blowing air may be further provided for smooth gas movement.

The ozone treatment unit 530 further includes an ozone decomposition catalyst 540 for promoting the decomposition of ozone and includes a heating unit 550 for supplying a heat source to prevent moisture from being condensed in the ozone decomposition catalyst So that the efficiency of sterilization and deodorization due to ozone treatment can be maximized.

The ozone treatment unit 530 includes an ozone detection sensor for detecting an amount of ozone in the air exhausted to the outside from the outflow portion 531. The ozone detection sensor receives data of the ozone detection sensor And a control unit 570 for controlling the operation of the heater. The ozone decomposition catalyst 540 may be coated with a ball core material and the outlet 531 formed in the ozone treatment unit 530 may be connected to the odor detection sensor 580 connected to the control unit 570 And an ozone generator 590 connected to the control unit 570 is connected to the deodorization tank 520. The ozone generator 590 is controlled by the control unit such that the reference value It can be set to be operated only when the odor is detected.

A series of devices related to the deodorization of the above food treatment apparatuses all share the technical feature of maximizing the efficiency of deodorization by adding a deodorizing tube stacked inside with a unique structure of the photocatalytic filter which is a matter of the present invention. It is possible to realize an efficient and economical deodorizing effect.

In the foregoing detailed description of the present invention, specific examples have been described. However, various modifications are possible within the scope of the present invention. The technical idea of the present invention should not be limited to the embodiments of the present invention but should be determined by the equivalents of the claims and the claims.

Claims (33)

A filter tube having both side openings;
A plate-shaped photocatalytic filter mounted in the filter tube at least at one or more times and having a plurality of gas-permeable holes;
A lamp insertion hole formed in the photocatalytic filter;
And a photocatalyst filter disposed in the deodorizing container. The method according to claim 1,
Wherein the photocatalytic filter further comprises an auxiliary support filter spaced apart from another filter adjacent to the photocatalytic filter. The method according to claim 1,
Wherein the auxiliary support filter is formed on at least one outer peripheral side surface of the photocatalytic filter. The method of claim 2,
Wherein the auxiliary support filter is a plate-like shape having an opening inside and a surface of the auxiliary support filter formed in a mesh shape. The method of claim 2,
Wherein the cross-sectional surface of the auxiliary support filter has the same or different shape as the cross-sectional shape of the photocatalytic filter. The auxiliary support filter according to claim 4 or 5,
Wherein the photocatalytic filter is integrally formed on a lower surface of the photocatalytic filter. The method according to claim 3 or 4,
And a second auxiliary supporting filter is further formed inside the opening of the auxiliary supporting filter. The method of claim 7,
Wherein the second auxiliary supporting filter is disposed in a direction in which at least one or more thin plate-shaped members are perpendicular to the transverse section of the auxiliary supporting filter. The method of claim 8,
Wherein the second auxiliary support filter is arranged such that at least one or more thin plate-shaped members form an acute angle with the transverse section of the auxiliary support filter, and each second auxiliary support filter is formed in a horizontal structure. Deodorizing barrel. The method according to claim 1,
Wherein the filter tube is coated with a reflective material for reflecting light on the inner surface thereof. The method according to claim 1 or 10,
Wherein the filter tube is formed with a stopper for fixing the photocatalytic filter. The method of claim 11,
Wherein a recessed groove is formed in a central portion of the latching jaw of the filter tube.
One deodorizing barrel. The method according to claim 2 or 3,
Wherein the photocatalytic filters formed in the filter tube are arranged at uniform or non-uniform intervals. The method according to any one of claims 1, 10 and 13,
Wherein the photocatalyst is TiO 2. The photocatalytic filter according to any one of claims 1 to 3,
And a plurality of rotating blades radially formed in the lamp insertion hole in the outer circumferential direction of the photocatalytic filter,
Wherein the photocatalytic filter is a deodorizing container having a photocatalytic filter. 16. The apparatus of claim 15,
Further comprising a rotating surface having an inclination angle in a direction of a lower surface of a rotating blade adjacent to the upper surface of the rotating blade. And a purifier for purifying the decomposed gas generated in the containing portion
In the food garbage disposal apparatus,
A filter tube having both side openings,
And a deodorizing tube having at least one or more gas permeable holes in the filter tube and a photocatalytic filter including a plate-like photocatalytic filter having a plurality of gas permeable holes and a lamp insertion hole formed in the photocatalytic filter. Wherein the food processing apparatus comprises: 18. The method of claim 17,
Wherein the photocatalytic filter further comprises an auxiliary support filter which is spaced apart from other filters adjacent to each other. 19. The method of claim 18,
Wherein at least one auxiliary supporting filter is formed on an outer peripheral side surface of the photocatalytic filter. 19. The method of claim 18,
Wherein the auxiliary support filter is a plate-shaped member having an opening inside and a surface of the auxiliary support filter formed in a mesh shape. The method of claim 20,
Wherein the cross-sectional surface of the auxiliary support filter has the same or different shape as the cross-sectional shape of the photocatalytic filter. The auxiliary support filter according to claim 19 or 20,
Wherein the filter is integrally formed on the lower surface of the photocatalytic filter. 23. The method of claim 22,
Wherein the auxiliary support filter is further formed with a second auxiliary support filter inside. The method according to claim 18 or 19,
Wherein the apparatus for destroying food waste further comprises an ozone treatment section for sterilizing the gas flowing in the containing section. 27. The method of claim 24,
Wherein the ozone treatment section further comprises an ozone decomposition catalyst for promoting the decomposition of ozone and a heating section for heating the ozone decomposition catalyst to prevent moisture condensation of the ozone decomposition catalyst. [19] The food waste treatment apparatus according to claim 17, 27. The method of claim 26,
Wherein the deodorization processing unit is provided with an ultraviolet lamp (UVC) inside and the air-permeable member is filled around the ultraviolet lamp (UVC). 28. The method of claim 27,
Wherein the air permeable member is a metal fiber. 28. The method of claim 27,
The air-
A metal fiber layer is formed on an upper portion and a lower portion of the deodorization processing portion,
Further comprising a support member having a hollow structure for supporting the spaced-apart metal fiber layer. 29. The method of claim 29,
The support member has a mesh-like structure on a cylindrical shape 32. The method of claim 30,
Wherein the apparatus for destroying food waste further comprises an ozone treatment section for sterilizing the gas flowing in the containing section. 32. The method of claim 31,
Wherein the ozone treatment section further comprises an ozone decomposition catalyst for promoting the decomposition of ozone and a heating section for heating the ozone decomposition catalyst to prevent moisture condensation of the ozone decomposition catalyst. 27. The method of claim 26,
Wherein at least one of the purifying units is formed.

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