KR20030063871A - device for removing the odor in refrigerator - Google Patents

Abstract

PURPOSE: A deodorizing apparatus for a refrigerator is provided to resolve and remove all kinds of ill-smelling elements from cool air circulating through the refrigerator, using harmless plasmatic photo-catalytic reaction. CONSTITUTION: A deodorizing apparatus for a refrigerator includes a plasma reactor(110) composed of a discharge electrode(111) and a ground electrode(113) coated with oxidized titanium, and an auxiliary filter(120) disposed to the front or the rear of the plasma reactor, to adsorb and resolve residual ill-smelling ingredients. The plasma reactor is disposed to a cooling air duct(7) circulating through the refrigerator. The auxiliary filter is coated with oxidized titanium to cause photo-catalytic reaction, using energy generated while plasma is released from the discharge electrode to the ground electrode.

Description

Deodorizer for refrigerator {device for removing the odor in refrigerator}

The present invention relates to a refrigerator. More particularly, the present invention relates to a refrigerator deodorizer for decomposing and removing various odor components and microorganisms contained in cold air circulating in a refrigerator using a plasma photocatalytic reaction that is harmless to a human body.

In general, the refrigerator is used when the food is stored for a long time while preventing the corruption of the food, the temperature is usually controlled within the temperature range of 0 ~ 10 ℃. However, when the food is left in the refrigerator for a certain period of time, the food starts to rot, and odors are generated accordingly, causing severe discomfort to the user. In addition, when the smell of a particular food is infiltrated into other food, the smell of the food is lost, there is a problem that discards the food.

For this reason, most refrigerators are equipped with various kinds of deodorizers for the purpose of sterilizing various microorganisms while removing odors caused by food odors or food decay and preventing circulation of the odors.

Among these deodorizing devices, a deodorizing filter in which manganese oxide (MnO ₂ ), copper oxide (CuO), and an artificial enzyme catalyst is supported on a lattice-type activated carbon is widely used. The deodorizing filter absorbs and removes odor components by using activated carbon to which the hydrocarbon compounds can be easily bonded by utilizing the fact that various odor components present in the furnace are mainly hydrocarbon compounds composed of carbon and hydrogen. However, since the deodorizing filter has a limit on the capacity of activated carbon capable of adsorbing malodorous components, there is a problem in that it can no longer adsorb malodorous components if it is not replaced periodically. In addition, various organic compounds, hetero compounds, etc., saturated in the activated carbon, were again scattered into the air and had a negative effect of acting as a second source of odor.

In order to solve this problem, a deodorizing device using a strong oxidizing power of ozone (O ₃ ) has been proposed.

1 is a view schematically showing the configuration of a deodorizer for a refrigerator using a conventional ozone generator, the deodorizer is exposed to a cold air flow path, the ozone generating electrode 10 to generate ozone by receiving power, and sufficient concentration And a high voltage generating means (HVB) 20 for applying a high voltage to the ozone generating electrode to generate ozone, and an ozone decomposition catalyst filter 30 disposed behind the ozone generating electrode to decompose residual ozone.

In general, ozone (O ₃ ), as shown in Equation [1], generates generator oxygen (O) by being naturally decomposed in air, and since the generator oxygen has a strong oxidizing power, it has excellent contact reactivity with odor components or microorganisms. As a result, deodorization of odorous components and sterilization of microorganisms are possible.

..................................[One]

However, since ozone takes a long time to decompose naturally in the air, the odor component or microorganism must be exposed to ozone for a long time for deodorization or sterilization. In particular, in low temperature conditions such as a refrigerator, it is more difficult to naturally decompose ozone, and therefore, artificial conditions for activating decomposition using heat, high frequency, or ultraviolet light should be made.

For example, the high voltage generating means 20 activates decomposition of ozone by applying a high frequency voltage having a magnitude of 5 to 6 kVpp and a frequency of 20 to 40 kHz to the ozone generating electrode 10.

However, the deodorizer using the ozone generator as described above also had the following problems.

In general, ozone is a harmful substance to the human body, and when the ozone is exposed to food or directly to the user, it causes much harm to the human body. However, as described above, the ozone generating means generates excessive ozone above a concentration required for sterilization or sterilization due to the applied high frequency voltage. In this case, the ozone remaining without decomposing during the reaction becomes considerable, and eventually, they have to be removed artificially. To this end, an ozone decomposition catalyst filter 30 is essentially added to the rear of the ozone generating electrode 10 to decompose and remove residual ozone, or a control method for artificially blocking the output of the high voltage generating means 20. Was used.

However, since the activated carbon is added to the ozone decomposition catalyst filter 30, there is a problem in that ozone harmful to the human body is exposed to the user or food as it is when the activated carbon is saturated. In addition, there was a problem that the function of removing the odor component or performing sterilization when the output of the high voltage generating means 20 is cut off cannot be achieved.

The present invention has been made to solve the above problems, an object of the present invention is for a refrigerator that can decompose and remove various odor components or microorganisms contained in the cold air circulating in the interior using a plasma photocatalytic reaction harmless to the human body It is to provide a deodorizing device.

1 is a view schematically showing the configuration of a deodorizer for a refrigerator using a conventional ozone generator

2 is a cross-sectional view schematically showing the structure of a refrigerator according to the present invention.

3 is a view schematically showing the configuration of a deodorizer for a refrigerator according to the present invention

4 is a view schematically showing the operation of the deodorizer for a refrigerator according to the present invention

Explanation of symbols on the main parts of the drawings

7: suction cold air duct 110: plasma reactor

111: discharge electrode 113: ground electrode

115: titanium oxide coating film 120: auxiliary filter

130: high voltage generating means

In order to achieve the above object, the present invention is provided on a cold air flow path circulating in the interior of the plasma reactor (plasma reactor) consisting of a discharge electrode and a titanium oxide coated ground electrode, and in front or rear of the plasma reactor It is provided with a deodorizing device for a refrigerator including an auxiliary filter for adsorbing and decomposing residual odor components by coating titanium oxide on the surface to cause a photocatalytic reaction using energy generated by the discharge of plasma from the discharge electrode to the ground electrode To provide.

Accordingly, the present invention provides an advantage of stably maintaining a high internal environment comfortably and hygienically by separating and removing various malodorous constituents or microorganisms generated from foods in the oven by plasma photocatalytic reaction which is harmless to the human body.

Hereinafter, with reference to the accompanying drawings, a deodorizer for a refrigerator according to a preferred embodiment of the present invention will be described in detail as follows.

First, Figure 2 is a cross-sectional view schematically showing the structure of a refrigerator according to the present invention, Figure 3 is a view schematically showing the configuration of a deodorizer for a refrigerator according to the present invention.

As shown in FIG. 2, the refrigerator according to the present invention includes a freezer compartment 2 in which cold air heat exchanged by the evaporator 4 is directly introduced to maintain an internal temperature of about −18 ° C., and cold or evaporator of the freezer compartment. The cold air heat-exchanged from the direct flow into the refrigerating chamber (3) which maintains the internal temperature of about 0 ~ 7 ℃, largely divided into, the machine room (not shown) is provided under the back of the freezing chamber.

The upper portion of the evaporator 4 is provided with a cold air circulation fan 5 for forcibly circulating the cold air cooled through the evaporator to the freezing chamber 2 and a motor for driving the cold air circulation fan.

The freezing compartment (2) and the refrigerating compartment (3) is divided up and down by a barrier, the suction cold air duct (7) is provided in the inside of the barrier, the hot air is sucked back to the evaporator 4 side while circulating the refrigerating compartment. In addition, a discharge cold air duct 6 in which cold air heat-exchanged through the evaporator 4 is directly discharged to the refrigerating compartment is provided on the rear surface of the refrigerating compartment 3.

At this time, the deodorization apparatus 100 is provided on the suction cold air duct 7 through which the freezing chamber side cold air flows into the evaporator 4. In general, the refrigerating chamber (3) has a high internal environment in which odor components and microorganisms of food are more active than the freezing chamber (2). Therefore, most of the odor component generated in the refrigerator is generated in the food in the refrigerator compartment, the odor component is introduced into the evaporator (4) through the suction cold air duct (7) and then back to the freezer compartment (2) or the refrigerating compartment (3). Discharged. Therefore, it is preferable that the odor component or microorganism of the refrigerating compartment is separated and removed before the refrigerating compartment side cold air flows into the evaporator. In this respect, the present invention provides that the deodorizing apparatus 100 is provided on the suction cold air duct 7. present.

As shown in FIG. 3, the deodorizer is provided on the suction cold air duct 7 in which cold air of the refrigerating chamber flows back to the evaporator side, and the discharge electrode 111 and the ground electrode coated with titanium oxide (TiO ₂ ) ( A plasma reactor 110 including a plasma reactor 110 and an auxiliary filter 120 provided at the front or rear of the plasma reactor to generate a photocatalytic reaction using energy generated by plasma discharge from the discharge electrode to the ground electrode. It is composed of

In general, when ultraviolet rays having a wavelength band of a certain band are irradiated onto a surface of an object coated with titanium oxide, a heat source is generated as if heated to 36,000 ° C. This reaction is called a photocatalytic reaction. At this time, not only the various organic substances and bacteria are incinerated but also various odor components are removed by the generated heat source.

At this time, in order to activate the photocatalyst, energy for exciting the photocatalyst, that is, energy above the band gap is required. For example, when titanium oxide is used as the photocatalyst, light energy (3.2 eV) having a wavelength of approximately 350 to 400 nm band is required to excite the titanium oxide.

The present invention presents a plasma reactor 110 as an energy source for exciting titanium oxide.

The plasma reactor 110 includes a discharge electrode 111 and a ground electrode 113 serving as a discharge corresponding electrode, and a titanium oxide coating film 115 is provided on a surface opposite to the discharge electrode of the ground electrode. In this case, titanium oxide coated on the ground electrode is excited by energy (approximately 3 to 4 eV) generated when plasma is discharged from the discharge electrode 111 to the ground electrode 113. To this end, the discharge electrode 111 is connected to the output line (L ₁ ) of the high voltage generating means 130, the ground electrode 113 is connected to the ground line (L ₂ ) of the high voltage generating means.

At this time, the plasma reactor 110 is provided on the intake cold air duct (7), it should take a structure that can activate the photocatalytic reaction without disturbing the flow of cold air. To this end, the plasma reactor 110 is a tungsten wire type discharge electrode 111 provided in the transverse direction with respect to the flow direction of cold air to minimize the flow resistance, and the net provided around the discharge electrode It is composed of a mesh type ground electrode 113. In this case, the ground electrode 113 is formed in a mesh shape because the plasma emitted from the discharge electrode 111 passes the ground electrode to excite the titanium oxide of the auxiliary filter 120 without blocking the flow of cold air. To make it possible.

The ground electrode 113 having the above-described function may be configured in a cylindrical or semi-cylindrical shape provided in the transverse direction with respect to the flow direction of the cold air, for example, a cylindrical ground electrode. At this time, although not shown, when the ground electrode 113 is a semi-cylindrical, the ground electrode should be provided on the auxiliary filter side to be in contact with or adjacent to the auxiliary filter 120.

The auxiliary filter 120 may be provided at the front and rear of the plasma reactor 110 or at least one side thereof, for example, to be provided at the rear of the plasma reactor. At this time, since the auxiliary filter 120 also decomposes and removes odor components and microorganisms by photocatalytic reaction like the ground electrode 113, a titanium oxide coating film 125 should be formed on the surface thereof. At this time, the auxiliary filter 120 is configured by stacking a plurality of corrugated plate (121) so that the contact area with the cold enough, the titanium oxide coating film 125 is formed on the surface of the corrugated plate do.

Meanwhile, the auxiliary filter 120 and the ground electrode 113 may be connected to each other.

Hereinafter, the operation of the deodorizer for a refrigerator according to the present invention in detail.

4 is a view schematically showing the operation of the deodorizer for a refrigerator according to the present invention, wherein the cold air, which has been heated while circulating in the refrigerating chamber, is introduced into the suction cold air duct 7 by the suction force of the cold air circulation fan. At this time, the cold air contains a large amount of microorganisms including various malodorous components (P ₁ ).

Thereafter, the cold air flows into the plasma reactor 110. At this time, the odor component in the cold air collides with the plasma emitted from the discharge electrode 111 of the plasma reactor to the ground electrode 113, that is, electrons of 3 to 4 eV because the binding energy is approximately 3 eV or less. It is destroyed, and an electrochemical reaction occurs in which radical (OH ⁻ ) ions generated by air colliding with electrons oxidize malodorous components. In particular, radical ions change the odor component into carbon dioxide and water, so that the odor component becomes an odorless component (P ₂ ).

In addition, the odor component in the cold air is attached to the titanium oxide coating film 115 of the ground electrode 113 is adsorbed to the inner surface of the titanium oxide. At this time, the titanium oxide receives the electron energy of 3 ~ 4eV generated from the discharge electrode 111 to form the above-mentioned radical ions, and also serves to destroy the ring of odor component with strong oxidizing power to deodorize function Will be further promoted. At the same time, most of the microorganisms in the cold air are incinerated by the high heat generated during the photocatalytic reaction.

Thereafter, the cold air passing through the plasma reactor 110 flows into the auxiliary filter 120. At this time, in the titanium oxide coating film 125 of the auxiliary filter, as described above, the same reaction as the reaction occurring at the ground electrode 113 proceeds. That is, the titanium oxide coating film 125 of the auxiliary filter 120 is excited by electrons passing through the mesh-shaped ground electrode to generate a large amount of radical ions, and the radical ions oxidize residual odorous components to form an odorless component. To change In addition, due to the high heat generated in the titanium oxide coating film 125, most of the remaining microorganisms are also incinerated and removed.

Therefore, no odor or microorganisms are present in the cold air which has passed through the plasma reactor 110 and the auxiliary filter 120 in turn, and fresher and more comfortable cold air is heat-exchanged through the evaporator to recycle the inside of the container.

So far, the present invention has been described with reference to preferred embodiments thereof, and one of ordinary skill in the art to which the present invention pertains may implement the modified embodiment within the essential technical scope of the present invention. Here, the essential technical scope of the present invention is shown in the claims, and the modified forms within the equivalent range will be construed as being included in the present invention.

Deodorizer for a refrigerator according to the present invention provides the following effects.

First, according to the present invention, by separating and removing various malodorous components or microorganisms generated from food in the oven using a plasma photocatalytic reaction that is harmless to the human body, the environment within the high stability can be maintained more stably and comfortably and hygienically.

Second, according to the present invention further comprises a separate auxiliary filter coated with titanium oxide in front or (and) the rear of the plasma reactor, it is possible to further improve the deodorizing function and sterilization function.

Claims (5)

A plasma reactor provided on a cold air passage circulating in the furnace, the plasma reactor including a discharge electrode and a ground electrode coated with titanium oxide; Titanium oxide is coated on the surface of the plasma reactor so as to cause a photocatalytic reaction using energy generated as plasma is discharged from the discharge electrode to the ground electrode. Refrigerator deodorizer including an auxiliary filter to. The method of claim 1, The plasma reactor includes a wire type discharge electrode provided in a horizontal direction with respect to the flow direction of cold air to minimize flow resistance, and a mesh type ground electrode provided around the discharge electrode. Deodorizer for refrigerators. The method of claim 2, The ground electrode is a deodorizing device for a refrigerator, characterized in that the cylindrical or semi-cylindrical provided in the transverse direction with respect to the flow direction of the cold air. The method of claim 1, The auxiliary filter is a deodorizing device for a refrigerator, characterized in that a plurality of corrugated plates are stacked to ensure a sufficient contact area with cold air. The method of claim 1, The plasma reactor is a deodorizer for a refrigerator, characterized in that the cold air circulated in the refrigerating compartment is provided on the cold air flow path to the evaporator side.