KR100438885B1 - Refrigerator and deodorizing device - Google Patents

Abstract

In the deodorizing device, a strong deodorizing action is obtained, and a refrigerator which does not require special handling at the time of disposal is provided.

The space discharge mechanism 73, the photocatalyst module 74, and the ozone decomposition catalyst 75 are disposed in the blowing path 71 of the deodorizing device 11 arranged in the cold air passage of the refrigerator, so that the space discharge mechanism 73 The photocatalytic action of the photocatalyst module 74 is effected by the ultraviolet rays generated by the high pressure discharge, and the ozone generated by the high voltage discharge and the ozone decomposition action by the ozone decomposition catalyst 75 are included in the cold air in the furnace. Oxidatively decomposes any odor or harmful components.

Description

Refrigerators and Deodorizers {REFRIGERATOR AND DEODORIZING DEVICE}

The present invention relates to a refrigerator configured by arranging a deodorizing device for deodorizing inside a refrigerator in a circulation path of cold air, and a deodorizing device used for the refrigerator.

Conventionally, deodorization in a refrigerator has been carried out by arranging a platinum catalyst in the vicinity of a defrost heater to adsorb odorous substances contained in the air in the furnace, heating the heater during defrosting, and thermally decomposing odorous substances. However, in order to remove the bad smell in a refrigerator and to fully prevent the smell from spreading to other foods, it is desired to exhibit a more powerful deodorizing effect.

In recent years, refrigerators have been set to have higher humidity in the refrigerating chamber by using dedicated coolers in the refrigerating chamber and the freezing chamber, respectively, to improve the freshness maintaining effect of the food. In this way, when the humidity in the refrigerating chamber is increased, the smell is more easily felt, and the germs in the refrigerating chamber are also more easily propagated.

From these circumstances, a deodorizer using the oxidizing power of ozone is introduced into the refrigerator as a more powerful deodorizing method. However, even with the oxidizing power of ozone, the odor component could not be completely decomposed, and intermediate products were sometimes produced.

For example, there is a method of oxidatively decomposing odor components by using a photocatalytic action by irradiating ultraviolet light to a photocatalyst material such as titanium oxide. According to this method, a stronger oxidizing power than ozone can be obtained, but a fluorescent tube lamp is required to irradiate ultraviolet rays. Since the fluorescent tube lamp contains mercury, consideration should be given not to increase the environmental load at the time of disposal. Therefore, handling at the time of disposal becomes a problem.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object thereof is to provide a refrigerator and a deodorizing device for use in the refrigerator, which attain a strong deodorizing action in the deodorizing device and do not require special handling at the time of disposal. .

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a longitudinal side view showing the structure of a main portion of a deodorizing device according to a first embodiment of the present invention.

Figure 2 is a longitudinal side view of the refrigerator.

FIG. 3 is an enlarged view of the cold air passage portion of FIG. 2; FIG.

4 is a functional block diagram showing an electrical configuration.

5 is a configuration of a refrigeration cycle.

Fig. 6 is a diagram showing one example of experimental results performed by the inventors of the present invention.

Fig. 7 is a second embodiment of the present invention, showing an enlarged longitudinal sectional view of an R cold air generating chamber portion.

Fig. 8 is a third embodiment of the present invention, showing an enlarged end face of the vegetable compartment part.

Fig. 9 is a perspective view showing the detachable form of the deodorizing device after removing the lower case of the vegetable compartment, (a) shows the form before the deodorizing device is attached, and (b) shows the form after the deodorizing device is attached.

Fig. 10 is an equivalent view of Fig. 1 showing a fourth embodiment of the present invention.

Fig. 11 is a perspective view showing only the space discharge mechanism and the photocatalyst module.

Fig. 12 is an equivalent view of Fig. 1 showing a fifth embodiment of the present invention.

Fig. 13 is an equivalent view of Fig. 1 showing a sixth embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

11, 11A, 11B, 11C: Deodorizer

28 control device (control means, voltage change means)

33: R evaporator (heat exchanger)

38: cold air intake

43: R fan

70: high voltage application unit (voltage change means)

71: blowing path

73: space discharge mechanism (discharge means)

74: photocatalyst module

75: ozone decomposition catalyst (ozone decomposition means)

76: discharge electrode

77: dipole (electrode)

81: space discharge mechanism (discharge means)

83: Fan

84: deodorizer

85: blowing path

86a: Step-up Transformer

88: battery

101: cold air passage (circulation path)

The refrigerator of Claim 1 arrange | positions the deodorization apparatus for deodorizing in a refrigerator in the circulation path of cold air, Comprising:

The deodorizing device is characterized by comprising a discharging means for generating ozone and ultraviolet rays by a high voltage discharge and a photocatalyst module for decomposing odorous components and harmful substances contained in the air by a photocatalytic action.

If comprised in this way, when cold air circulates in a high temperature, an ultraviolet-ray will generate | occur | produce by the high voltage discharge in the discharge means of the deodorizing apparatus arrange | positioned in the circulation path. In the photocatalyst module, the photocatalytic reaction can be effected by receiving the ultraviolet rays, so that the odor component contained in the circulating cold air is oxidatively decomposed and removed. That is, since ultraviolet rays can be generated without using a fluorescent tube lamp, there is no need to consider special handling during disposal.

In addition, since ozone is generated simultaneously by the high voltage discharge, the oxidizing power of the ozone also acts and the odor component is oxidatively decomposed. In addition, by generating the ozone atmosphere by diffusing the generated ozone into the furnace by circulating cold air, it is possible to achieve an antibacterial effect on foods in the oven and the like, and is effective in maintaining the freshness of the food.

In this case, as described in claim 2, it is preferable to arrange the ozone decomposition means for decomposing ozone generated in the discharge means at least downstream of the discharge means and the photocatalyst module. With this arrangement, since ozone generated by the high voltage discharge is decomposed by the ozone decomposing means, the ozone concentration in the high rises excessively, so that the user can not feel the smell of ozone when the door is opened. In addition, when ozone is decomposed, active oxygen is more likely to be generated, so that a stronger oxidizing power is obtained, and the deodorization efficiency is further improved.

In addition, as described in claim 3, the ozone decomposition means may be disposed at the cold air intake portion of the heat exchanger. In other words, when the ozone generated by the deodorizer is circulated in the furnace, if it is circulated to the cooler portion as it is, there is a possibility that it will adversely affect the cooler itself, piping and the like. Therefore, by disposing the ozone decomposing means at the cold air intake portion of the heat exchanger, it is surely prevented that the ozone decomposes at the stage before the circulating cold air is introduced into the heat exchanger, thereby adversely affecting the internal components.

In addition, as described in claim 4, the photocatalyst module may be disposed on both the upstream side and the downstream side of the discharge means, and if configured in this way, the utilization efficiency of the ultraviolet rays generated in the discharge means can be further improved.

Further, as described in claim 5, the photocatalyst module may be detachably attached to the deodorizing apparatus main body, and when configured in this way, the photocatalytic module is installed in a case where contaminants such as inorganic substances adhere to the surface of the photocatalyst module. The contaminant taken out from the main body can be removed.

As described in claim 6, the photocatalyst module may be configured such that the photocatalyst module can be attached to the main body by replacing the surface facing the discharge means and the surface located on the opposite side thereof. That is, on the surface facing the discharge means, the photocatalytic reaction becomes active and contaminants tend to adhere. Therefore, in the stage where adhesion of the contaminants has progressed to some extent, if the surface facing the discharge means and the surface located on the opposite side are replaced, the photocatalytic reaction can be satisfactorily progressed by using the surface on the opposite side where the contamination has little adherence. It becomes possible.

As described in claim 7, the photocatalyst module may be configured by fixing the photocatalyst material on the surface of the base made of a porous ceramic. In such a configuration, even if the photocatalyst module is disposed in the air blowing path, the circulation of cold air is not actively prevented. In addition, since the area for fixing the photocatalytic material to the base can be made larger, the photocatalytic reaction can be performed with high efficiency, and the hazardous substances can be decomposed and removed efficiently.

As described in claim 8, the control means for controlling the discharge means of the deodorizing device to discharge when the cold air circulation in the furnace is performed may be provided. That is, when cold air circulation is performed, deodorization can be performed efficiently because cold air containing an odor flows through the inside of a deodorizing apparatus, and deodorization is performed.

As described in claim 9, the deodorizing apparatus may be provided with a fan for blowing air to the discharge means and the photocatalyst module. If comprised in this way, regardless of whether a refrigerator circulates cold air, a deodorizer can blow and blow it to a discharge means and a photocatalyst module independently, and it can deodorize.

As described in claim 10, it is preferable to configure the discharging means so as to discharge directly between the two electrodes, and to be detachable to the deodorizing apparatus main body. With this configuration, it becomes possible to take more deodorization processing space than the creepage discharge system which discharges through the insulator. In addition, when the contaminant adheres to the electrode, the contaminant can be removed by removing the discharge means from the apparatus main body.

As described in claim 11, by applying a negative polarity high voltage between the electrodes of the discharge means, when the discharge is configured, the amount of ozone generated can be increased and the deodorization efficiency is improved.

As described in claim 12, a voltage change means for changing the discharge voltage of the discharge means may be provided, and if configured in this way, for example, by changing the voltage so as to increase the applied voltage as the fan rotation speed decreases and the airflow amount decreases, The fall of the deodorization efficiency according to the fall of airflow amount can be compensated.

As described in Claim 13, the control means which controls so that discharge by a discharge means may be stopped at the time of opening of a door may be provided. In such a configuration, it is possible to prevent high voltage discharge from being performed when the user opens the door.

As described in claim 14, the photocatalyst module may be disposed between the electrodes of the discharge means. If configured in this way, the ultraviolet light generated in the discharge means can be efficiently irradiated to the photocatalyst module, thereby increasing the photocatalytic reaction. have.

As described in Claim 15, what is necessary is just to comprise a deodorization apparatus detachably from a refrigerator main body. In this configuration, the deodorizing device can be easily removed from the refrigerator, and decomposed by the deodorizing action to remove substances attached to the respective parts.

As described in claim 16, the deodorizing device may be configured to enable operation by a battery. If comprised in this way, since a deodorization apparatus becomes a structure completely independent from a refrigerator, it can be arrange | positioned in arbitrary positions in a refrigerator.

According to the deodorization apparatus of Claim 17, deodorization can be performed by arrange | positioning inside the refrigerator which is not equipped with the deodorization function.

Hereinafter, a first embodiment of the present invention will be described with reference to Figs. In Fig. 2 showing a longitudinal side view of the refrigerator, the refrigerator main body 1 is formed in a rectangular box shape whose front is opened, and the inner housing 3 is disposed in the outer housing 2, and the outer housing 2 and It is formed by filling a heat insulating material 4 such as urethane foam between the inner housings 3. In addition, horizontal partition plates (refrigeration chamber bottom plates) 5 are fixed to the inner surface of the inner housing 3. The partition plate 5 forms a refrigerating chamber (storage chamber) 6 in the upper part of the refrigerator main body 1, and the R door 7 is rotatably attached to the front end of the refrigerating chamber 6.

A plurality of protrusions (not shown) are formed on the upper surface of the partition plate 5, and the freezing case 8 is mounted on the plurality of protrusions. The refrigeration case 8 has a container shape with an upper surface and a front surface open. A cold air passage 9 is formed between the lower surface of the refrigeration case 8 and the partition plate 5. In addition, the code | symbol 10 shows the cover which opens and closes the front surface of the refrigeration case 8. As shown in FIG.

In addition, the support plate 100 is fixed below the partition plate 5 at predetermined intervals. The front end side of the partition plate 5 is open, and cold air is guided from the refrigerating chamber 6 side to the cold air passage (circulation path) 101 formed between the partition plate 5 and the support plate 100. . And the deodorizing apparatus 11 is arrange | positioned in the cold air | air path 101. As shown in FIG. 3 is an enlarged view of this portion. In addition, the detailed structure of the deodorizing apparatus 11 is mentioned later.

The rear end side of the support plate 100 is opened to the vegetable chamber 13, and the circulating cold air introduced into the cold air passage 101 from the refrigerating chamber 6 side passes through the deodorizing device 11, and then into the vegetable chamber 13. It is to come early.

In the inner housing 3, it is located below the partition plate 5, and the heat insulation partition plate 12 is fixed. The heat insulating partition plate 12 is formed by storing foamed styrol in a case made of synthetic resin, and a vegetable compartment (storage chamber) 13 is formed between the heat insulating partition plate 12 and the partition plate 5. The vegetable chamber 13 passes through the deodorizing device 11 disposed in the cold air passage 101 to the inside of the refrigerating chamber 6 (functioning as part of the refrigerating chamber 6), and at the front end of the vegetable chamber 13 The V door 14 is slidably mounted in the front-rear direction.

The lower case 15 is accommodated in the vegetable chamber 13. The lower case 15 has a container shape with an upper surface opening, and the upper case 16 is mounted on the lower case 15. The upper case 16 closes a portion except the front end of the upper surface of the lower case 15, and forms a container shape in which the upper surface is opened. The lid 17 is attached to the upper surface of the upper case 16 so that it can be opened and closed.

The freezer compartment 19 is formed below the heat insulation partition plate 12. The freezing compartment 19 is thermally isolated from the upper vegetable compartment 13 and the refrigerating compartment 6, and the upper door 20 and the lower door 21 can slide in the front-rear direction at the front end of the freezing compartment 19. In the freezer compartment 19, the freezing cases 22 and 23 are stored in two stages.

The machine room 24 is formed in the lower end part of the refrigerator main body 1, and the compressor 25 of a refrigeration cycle is arrange | positioned in the machine room 24. As shown in FIG. This compressor 25 is a reciprocating type which uses the compression motor 26 as a drive power supply, and the compression motor 26 is a control apparatus (control means, voltage change) through the drive circuit 27 as shown in FIG. Means (28) electrically. The control apparatus 28 mainly consists of a microcomputer, and is arrange | positioned in the refrigerator main body 1. As shown in FIG.

The discharge port of the compressor 25 is connected to the input port of the flow path valve 30 via the condenser 29 of a refrigeration cycle, as shown in FIG. The flow path valve 30 is configured to selectively open the RF output port and the F output port based on the forward and reverse of the valve motor 31 (see FIG. 4), and the valve motor 31 includes the drive circuit 27. It is electrically connected to the control apparatus 28 via the via.

As illustrated in FIG. 5, the RF output port of the flow path valve 30 is connected to the inlet of the R evaporator 33 via the RF capillary tube 32, and the R evaporator (heat exchanger) 33. The inlet of the F evaporator 34 is connected to the outlet of. The outlet of this F evaporator 34 is connected to the inlet of the compressor 25, and when the RF output port is opened, the refrigerant discharged from the compressor 25 passes to both the R evaporator 33 and the F evaporator 34. Supplied.

The inlet of the F capillary tube 35 is connected to the F output port of the flow path valve 30. The outlet of this F capillary tube 35 is connected between the outlet of the R evaporator 33 and the inlet of the F evaporator 34. When the F output port is opened, the refrigerant discharged from the compressor 25 is F Only the evaporator 34 is supplied.

Referring again to FIG. 2, an R cold air generating chamber 36 is formed in the rear portion of the vegetable chamber 13, and the R evaporator 33 is housed in the R cold air generating chamber 36. The R cold air generating chamber 36 has a cylindrical cold air discharge port 37 and a cold air intake port 38, and the cold air discharge port 37 is inserted into the upper case 16.

An approximately L-shaped duct cover 39 is fixed in the refrigerator compartment 6. The duct cover 39 is formed of a synthetic resin material, and a plurality of cold air discharge holes 40 opening in the refrigerating chamber 6 are formed in the duct cover 39. The duct cover 39 cooperates with the rear plate of the inner housing 3 to form an L-shaped passage-type cold air duct 41. The upper end of the cold air duct 41 is opened in the refrigerating chamber 6, and the cold air is The lower end part of the duct 41 passes through the R cold air generating chamber 36.

The R fan motor 42 is accommodated in the R cold air generating chamber 36, and the R fan motor 42 is electrically connected to the control device 28 via the drive circuit 27. An R fan (blowing fan) 43 is connected to the rotation shaft of the R fan motor 42, and cold air circulates in the following path during the rotation of the R fan 43. Reference numeral 44 denotes an R fan apparatus constituted by the R fan motor 42 and the R fan 43. This R fan apparatus 44 comprises the R cooling apparatus 45 simultaneously with the R evaporator 33.

<About the circulation path of cold air in the refrigerator compartment 6 and the vegetable compartment 13>

A part of the air is discharged into the upper case 16 from the inside of the R cold air generating chamber 36 through the cold air outlet 37, and through the cold air outlet hole 46 formed in the front end of the lid 17, the upper case 16. ) Is released to the front. And it flows downward along the front surface of the lower case 15, and flows back along the lower surface of the lower case 15, and is returned to the R cold air production | generation chamber 36 through the cold air suction port 38. As shown in FIG. At this time, the R evaporator 33 is cold-aired based on cooling air, and the inside of the vegetable chamber 13 is cooled.

The remainder of the air is discharged into the refrigerating chamber 6 from the inside of the R cold air generating chamber 36 through the plurality of cold air discharge holes 40 and the upper end of the cold air duct 41, and the cold air passage below the refrigeration case 8 ( 9) flows in. Then, it flows into the vegetable chamber 13 through the deodorizing device 11 and the cold air passage 101, and flows forward of the upper case 16 through the cold air outlet hole 46. Thereafter, it flows downward along the front surface of the lower case 15, flows backward along the lower surface of the lower case 15, and returns to the R cold air generating chamber 36 through the cold air intake port 38. At this time, the R evaporator 33 cools and cools the air to cool the inside of the refrigerating chamber 6 and the vegetable chamber 13. That is, the deodorizing device 11 is arranged on the return circulation path side of the circulation cold air.

The F cold air generating chamber 47 is formed in the rear part of the freezing chamber 19, and the cold air discharge port 48 and the cold air intake port 49 are provided in the upper end part and the lower end part of the F cold air generating chamber 47. The F evaporator 34 and the F fan motor 50 are accommodated in the F cold air generating chamber 47, and the F fan motor 50 is electrically connected to the control device 28 via the drive circuit 27. Connected.

The F fan 51 is connected to the rotating shaft of the F fan motor 50, and cold air circulates in the following path during the rotation of the F fan 51. Reference numeral 52 denotes an F fan apparatus composed of the F fan motor 50 and the F fan 51. This F fan apparatus 52 comprises the F cooling apparatus 53 simultaneously with the F evaporator 34.

<About the circulation path of cold air in the refrigerator compartment 19>

Air is discharged from the F cold air generating chamber 47 into the freezing chamber 19 through the cold air discharge port 48 and returned to the F cold air generating chamber 47 through the cold air inlet 49. At this time, the F evaporator 34 cools the air and cools it, thereby cooling the inside of the refrigerating chamber 19.

As shown in Fig. 4, the R temperature sensor 54 and the F temperature sensor 55 are arranged in the refrigerating chamber 6 and the freezing chamber 19. As shown in Figs. These R temperature sensors 54 and F temperature sensors 55 output the temperature signal Vr of the voltage level according to the temperature in the refrigerator compartment 6 and the temperature signal Vf of the voltage level according to the temperature in the freezer compartment 19. It consists of thermistors, and is electrically connected to the control apparatus 28. As shown in FIG.

The R evaporator temperature sensor 56 and the F evaporator temperature sensor 57 are electrically connected to the control apparatus 28. These R evaporator temperature sensors 56 and F evaporator temperature sensors 57 consist of thermistors attached to the R evaporator 33 and the F evaporator 34 via attachment holes (not shown), and the R evaporator 33 The temperature signal Vre of the voltage level according to the surface temperature of and the temperature signal Vfe of the voltage level according to the surface temperature of the F evaporator 34 are output.

The R door switch 102 and the V door switch 103 are switches for detecting the opening and closing of the R door 7 and the V door 14, respectively, and the opening and closing detection signal is also output to the control device 28. It is supposed to be.

An operation control program is recorded in the inside of the control device 28 (ROM), and the control device 28 has a temperature signal from the R temperature sensor 54 (Vr to F) and a temperature signal from the evaporator temperature sensor 57. Drive control of the compression motor 26, the valve motor 31, the R fan motor 42, and the F fan motor 50 based on (Vfe) performs cooling operation, etc. In addition, the control device 28 controls the high voltage applying unit (voltage change means) 70 to apply a pulsed high voltage of about several kV to the electrode of the deodorizing device 11.

1 is a longitudinal side view illustrating the configuration of the main portion of the deodorizing device 11. The preliminary filter 72, the space discharge mechanism (discharge means) 73, the photocatalyst module 74, and the ozone decomposition catalyst (ozone decomposition means) 75 are arrange | positioned inside the rectangular box-shaped ventilation path 71, have. As the R fan 43 in the R cold air generating chamber 36 rotates, cold air in the high-flow flows in from the inlet port 71a, which is the left end side in FIG. After making a deodorization effect by making it pass, the cold air after deodorization flows out into the cold air passage 101 from the outlet port 71b of the right end side in FIG.

The preliminary filter 72 is arrange | positioned in the uppermost oil | gas side in the ventilation path 71, and is to filter the dust contained in cold air.

The space discharge mechanism 73 disposed at the rear end of the preliminary filter 72 includes, for example, a plurality of discharge electrodes 76 formed in a wire shape of tungsten or the like, and two bipolar electrodes (electrodes formed in a flat shape). (77). The plurality of discharge electrodes 76 are arranged in parallel with each other in a row in the vertical direction in FIG. 1 so as to cross the flow direction of the cold air. The two bipolar 77 is arrange | positioned so that these discharge electrodes 76 may be interrupted from front and back in the flow direction of cold air. In addition, the dipole 77 is provided with a slit 77a for circulating cold air. Then, a high voltage of negative polarity is applied between the discharge electrode 76 and the dipole 77 to discharge, thereby generating ultraviolet rays (wavelength 380 nm or less) or ozone.

In addition, a photocatalyst module 74 is disposed between these discharge electrodes 76 and the dipoles 77. The photocatalyst module 74 is fixed to the base surface by applying a photocatalyst material such as titanium oxide to the surface of a base made of porous ceramic (for example, alumina, silica, etc.) and drying or sintering the photocatalyst material. Consists of.

The space discharge mechanism 73 is configured to be detachable in the direction of the arrow in FIG. 1 with respect to the blowing path 71 at the same time as the photocatalyst module 74. That is, although not specifically shown, the door wall which can be opened and closed corresponding to the site | part in which the space discharge mechanism 73 is located is attached to the pipe wall of the ventilation path 71, and the ventilation path 71 is opened by opening the door. The space discharge mechanism 73 and the photocatalyst module 74 disposed therein can be taken out in the direction of the arrow.

Next, the operation of this embodiment will be described with reference to FIG. 6 as well. When the controller 28 determines that the cooling operation is to be performed based on the temperature setting information related to the refrigerating chamber 6, the temperature information of the R temperature sensor 54, or the like, the control device 28 switches the RF output port of the flow path valve 30 to the same. It opens, supplies the refrigerant | coolant discharged from the compressor 25 to the R evaporator 33, and drives the R fan apparatus 45 to circulate cold air in the refrigerating chamber 6 and the vegetable chamber 13. And the control apparatus 28 starts the operation | movement of the deodorizing apparatus 11. As shown in FIG. Then, a high voltage discharge is performed between the discharge electrode 76 and the dipole 77, and ultraviolet-ray or ozone is generated.

At this time, the cold air in the furnace containing the odor component flows in from the inlet port 1a side by the rotation of the R fan 43 and is filtered by the preliminary filter 2, and then the slit 77a of the bipolar 77. It leads to the space discharge mechanism 73 via. In the space discharge mechanism 73, ultraviolet rays generated by high voltage discharge are irradiated to the photocatalyst module 74, and titanium oxide receives photo energy of the ultraviolet rays, activates the photocatalytic effect, and forms ammonia contained in the circulating cold air. Oxidative decomposition of such odor components.

In addition, the circulating cold air is mixed with ozone generated by the high voltage discharge when passing through the space discharge mechanism 73 to reach the ozone decomposition catalyst 75 at the next stage. In the ozone decomposition catalyst 75, when ozone in a state mixed with odor components in cold air is decomposed, active oxygen is generated, and odor components and the like are oxidatively decomposed by the oxidizing power of the active oxygen.

The cold air deodorized as mentioned above flows out into the inside of the air outlet from the outlet 71b of the ventilation path 71.

6 shows an example of experimental results performed by the inventors of the present invention. When the ammonia in the refrigerator was decomposed and removed using various types of deodorizers, the ammonia remaining ratio (%) in the refrigerator over time was measured. The symbol "Δ" denotes a case of a conventional deodorization apparatus configured by using a thermal decomposition catalyst, and the symbol "◇" and "○" denotes a case of the deodorizer 11 of the present embodiment. Corresponds to the case where discharge is performed (ON) or not (OFF) in the space discharge mechanism 3, respectively.

As is apparent from FIG. 6, the deodorizing device 11 of the present embodiment has a significantly lower residual rate of ammonia than the conventional deodorizing device even when the space discharge mechanism 3 is OFF. When 3) is turned ON, good characteristics are also shown.

As described above, according to the present embodiment, the space discharge mechanism 73, the photocatalyst module 74, and the ozone decomposition catalyst 75 are provided in the blowing path 71 of the deodorizer 11 disposed in the cold air passage 101 of the refrigerator. ) And the photocatalytic action of the photocatalyst module 74 by the ultraviolet rays generated by the high voltage discharge of the space discharge mechanism 73, and the ozone by the ozone decomposition catalyst 75 generated by the high voltage discharge. By the decomposition action, odor components and harmful components contained in cold air in the oven were oxidatively decomposed.

That is, since ozone and ultraviolet rays generated by high-voltage discharge can be used to decompose and remove odor components and the like, there is no need to replace an adsorbent for deodorization or to supplement chemical components. In addition, by combining the photocatalytic action and the ozone decomposing action, it is possible to decompose a wider range of odor components and the like. And since ultraviolet rays can be generated without using a fluorescent tube lamp, there is no need to consider special handling during disposal.

Moreover, by decomposing ozone by the ozone decomposition catalyst 75, the ozone concentration in the atmosphere in the refrigerating chamber 6 or the vegetable chamber 13 rises excessively, and the user opens the R door 7 or the V door 14. Ozone odor can be felt at one time (for example, in the case of concentrations of 0.02 to 0.03 ppm), or corrosion of each member in the furnace can be prevented.

In addition, since the space discharge mechanism 73 is detachably configured with respect to the blowing path 71, the space discharge is performed when the contaminant adheres to the discharge electrode 76, the bipolar 77, or the photocatalyst module 74. The mechanism 73 can be taken out from the deodorizer main body, and contaminants adhering to them can be removed, for example, by washing with water.

In addition, since the space discharge mechanism 73 is constituted by the wire-shaped discharge electrode 76 and the external flat plate-shaped bipolar 77, the deodorizing processing space is increased in comparison with the creepage discharge system which discharges through an insulator. Can be taken. Since the negative high voltage is applied between the electrodes 76 and 77, the amount of ozone generated can be increased and the deodorization efficiency is improved.

In addition, according to the present embodiment, the control device 28 synchronizes the application of the voltage to the space discharge mechanism 73 with the operation of the R fan 43, and further applies the voltage applied to the space discharge mechanism 73, The air flow of the R fan 43 was changed. Therefore, deodorization can be performed efficiently by operating the deodorization apparatus 11 in addition to the case where the cold internal air flows in the ventilation path 71. In addition, by lowering the rotation speed of the R fan 43 and increasing the applied voltage as the flow rate of the cold air decreases, the decrease in the deodorization efficiency due to the decrease in the flow rate can be compensated.

Moreover, since the photocatalyst module 74 is arrange | positioned between the electrodes 76 and 77 of the space discharge mechanism 73, the non-directional ultraviolet-ray generate | occur | produced in the space discharge mechanism 73 is efficient with respect to the photocatalyst module 74. Can be irradiated and the photocatalytic reaction can be further enhanced. And since the photocatalyst module 74 was arrange | positioned in the blowing path 71 both upstream and downstream of the space discharge mechanism 73, the utilization efficiency of the ultraviolet-ray generate | occur | produced in the space discharge mechanism 73 is further improved. It can increase.

In addition, since the photocatalyst module 74 was formed by fixing titanium oxide on the surface of the base made of a porous ceramic, even if the photocatalyst module 74 is disposed in the air passage 71, the circulation of cold air is actively prevented. There is nothing to do. In addition, since the area for fixing titanium oxide to the base can be made larger, the photocatalytic reaction can be performed with high efficiency even in a state where the amount of titanium oxide, which is an expensive material, is actively reduced, so that decomposition and removal of harmful substances can be efficiently performed. I can do it.

Fig. 7 shows a second embodiment of the present invention. The same parts as those in the first embodiment will be denoted by the same reference numerals, and description thereof will be omitted. Only the other parts will be described below. 7 is a diagram corresponding to FIG. 3. In the second embodiment, the deodorizing device 11 is an inlet 71a above the R fan 43 in the R cold air generating chamber 36 instead of the cold air passage 101 of the first embodiment. Is located at the R fan 43 side. Moreover, the ozone decomposition catalyst 78 is arrange | positioned in the cold air intake port 38 part of the R cold air production | generation chamber 36. As shown in FIG. The rest of the configuration is the same as in the first embodiment.

According to the second embodiment configured as described above, the ozone decomposition inlet 38 is disposed in the R cold air generating chamber 36 by decomposing ozone also in the cold air intake port 38 by the ozone decomposition catalyst 775. It is possible to reliably prevent the external pipes and the like from corroding by the oxidizing power of ozone. In this case, in order to prevent corrosion, the ozone concentration may be 0.05 ppm or less.

8 and 9 show a third embodiment of the present invention. In the third embodiment, the deodorizing device 11A is configured independently of the refrigerator main body 1 and can be attached to and detached from the main body 1. And as shown in FIG. 8, 11 A of deodorizing apparatuses are arrange | positioned in the cold air path 79 formed between the lower case 15 and the heat insulation partition plate 12 in the vegetable chamber 13, The inlet 71b of the deodorizing device 11A communicates with the cold air suction port 38 of the R cold air generating chamber 36.

9 is a perspective view showing the detachable state of the deodorizing device 11A with the lower case 15 removed. That is, as shown in Fig. 9A, the power plug 80 for supplying alternating current 100V extends from the rear end side of the right side of the deodorizing device 11A, and is shown in Fig. 9B. As described above, in the case of attaching the deodorizing device 11A, the power plug 80 is inserted into the socket 81 arranged next to the cold air intake port 38 so as to be electrically connected.

According to the third embodiment configured as described above, since the deodorizing device 11A is configured to be detachably attached to the refrigerator main body 1, the discharge electrode 76, the bipolar 77, or the photocatalyst similarly to the first embodiment are provided. The space discharge mechanism 73 can be taken out from the deodorizing apparatus main body, for example, when a contaminant adheres to the module 74, and these attached contaminants can be removed by, for example, water washing. In addition, such as a refrigerator for work or a vehicle, it is suitable for the case where frequent maintenance is required because the volume is relatively large and many odorous substances are contained in the atmosphere.

10 and 11 show a fourth embodiment of the present invention. The same parts as those in the first embodiment will be denoted by the same reference numerals, and descriptions thereof will be omitted. Only the other parts will be described below. In the deodorizing device 11B of the fourth embodiment, the space discharge mechanism (discharge means) 81 is disposed in place of the space discharge mechanism 73. The dipoles (electrodes) 82 of the plurality of sheets (number of discharge electrodes 76 + 1) constituting the space discharge mechanism 81 are formed in a single shape, and in the same arrangement as the discharge electrodes 76, the discharge electrodes Alternately with 76, the planes are arranged so as to be parallel to the flow direction of the cold air. The photocatalyst module 74 is disposed on both the upstream side and the downstream side of the space discharge mechanism 81.

In addition, the space discharge mechanism 81 is configured to be detachably attached to the blowing path 71 similarly to the space discharge mechanism 73 of the first embodiment, and is disposed independently of the space discharge mechanism 73. The photocatalyst module 74 is also detachably attached.

The operation relating to the deodorization of the fourth embodiment configured as described above is basically the same as that of the first embodiment, but since the plane of the bipolar 82 is arranged so as to be parallel to the flow direction of the cold air, the blowing path 71 It has a structure which does not actively prevent the circulation of cold air in the inside.

11 is a perspective view showing only the space discharge mechanism 81 and a portion of the photocatalyst module 74 at the rear end thereof. In the fourth embodiment, when detaching the photocatalyst module 74 with respect to the blowing path 71, the surface (A surface) facing the photocatalytic module 74 toward the space discharge mechanism 81 side and the B surface which abuts thereafter are replaced. It is possible.

In other words, on the A surface facing the space discharge mechanism 81, contaminants tend to adhere due to the active photocatalytic reaction. Therefore, in the stage where adhesion of the contaminant has progressed to some extent, if surface A and the surface B are replaced before removing the photocatalytic module 74 and performing cleaning or the like, it is possible to temporarily use the surface B with little adherence of the contaminant. As a result, the photocatalytic reaction can be satisfactorily performed.

As described above, according to the fourth embodiment, the photocatalyst module 74 can be mounted to the main body of the deodorizing device 11B by replacing the A surface facing the space discharge mechanism 81 and the B surface positioned on the opposite side thereof. In this case, even when adhesion of the contaminants proceeds to some extent and the photocatalytic reaction decreases, the photocatalytic reaction can be temporarily activated by replacing the A and B surfaces. Therefore, the photocatalyst module 74 can be utilized more effectively.

12 shows a fifth embodiment of the present invention, in which the same parts as those in the first embodiment are denoted by the same reference numerals, and explanations thereof will be omitted. Only the other parts will be described below. The deodorizing device 11C of the fifth embodiment is configured by incorporating a blower fan 83 in the main body of the deodorizing device 11C. The rest of the configuration is the same as in the first embodiment.

According to the fifth embodiment configured as described above, the fan 83 of the deodorizing device 11C can be operated independently of the R fan 43 of the refrigerator main body 1. Therefore, even if the refrigerator stops the R fan 43 during the energy saving operation or the defrosting operation, for example, when the fan 83 of the deodorizing device 11C is operated, the deodorizing device 11C deodorizes. Can work. In addition, it is applicable also to the direct cooling type refrigerator which does not circulate cold air.

Fig. 13 shows a sixth embodiment of the present invention. The same parts as those in the first or fifth embodiment are denoted by the same reference numerals, and explanations thereof will be omitted. Only the other parts will be described below. The deodorizing device 84 of the sixth embodiment is configured to be capable of battery driving, and can operate completely independently of the refrigerator main body 1.

That is, as shown in FIG. 13, the machine room 86 is formed in the lower side of the ventilation path 85, The high voltage application part 87 and the battery which contain the boost transformer 87a inside the machine room 86 are shown. A motor (DC motor) 91 for rotationally driving the 88 and the blowing fan 83 is incorporated. Moreover, the outlet port 85b of the blowing path 85 is formed so that it may face upward in FIG. 13, and the blowing path 85 is substantially L-shaped.

The high voltage applying unit 87 converts the DC power supplied from the battery 88 into an alternating current by an AC converting unit (not shown), and is boosted by the boosting transformer 87a to be disposed on the secondary side of the boosting transformer 87a. It converts to direct current again by the direct current converter which is not shown in figure, and finally, like the 1st Example, it is made to apply a negative pulse type high voltage between the discharge electrode 76 and the dipole 77. FIG.

According to the sixth embodiment configured as described above, since the deodorizing device 84 can operate by the battery 88 by using the boost transformer 87a, the deodorizing device 84 is configured to be completely independent of the refrigerator. The deodorizing action can be efficiently performed by placing a relatively strong food, for example, in the vicinity of s storing food having a strong smell. Moreover, even in the refrigerator which does not have a deodorizing function, the deodorizing function can be performed by arrange | positioning the deodorizing apparatus 84 inside it.

This invention is not limited only to the Example mentioned above and described in drawing, The following deformation | transformation or expansion is possible.

Also in the first embodiment, similarly to the fourth embodiment, it is possible to use the A side and the B side of the photocatalyst module 74 interchangeably.

The photocatalyst module 74 may be disposed only on either the upstream side or the downstream side of the space discharge mechanisms 73, 81.

The polarity of the voltage applied to the photocatalyst module 76 may be positive polarity. In addition, the applied voltage is not limited to a pulsed voltage, and may be a legitimate alternating voltage or a direct current voltage.

In addition, the applied voltage may be set constant regardless of the amount of air flow in the blowing path 71.

In addition, the control device 28 may stop the operation of the deodorizing device 11 when the R door 7 or the V door 14 is opened. With the above configuration, the high voltage discharge can be stopped when the user wants to open the door 7 or 14 to take out foodstuffs in the high place.

The discharge mechanism may have a surface discharge type electrode configuration by setting the deodorizing capability.

The bipolar 77 may be formed in a mesh shape.

The voltage applied to the space discharge mechanism 73 may not only be changed depending on the blowing amount, but also simply changed according to the strength and weakness of the deodorizing ability.

Since this invention is as having demonstrated above, the following effects are exhibited.

According to the refrigerator according to claim 1, when cold air circulates in the high temperature, ultraviolet rays are generated by the high voltage discharge in the discharge means of the deodorizing device disposed in the circulation path, so that the photocatalytic module receives the ultraviolet rays to activate the photocatalytic reaction. The odor component contained in the circulation cold air is oxidatively decomposed. That is, since ultraviolet rays can be generated without using a fluorescent tube lamp, there is no need to consider special handling during disposal.

In addition, since ozone is generated at the same time due to the high voltage, the oxidizing power of the ozone also acts, so that the deodorizing component is oxidatively decomposed, and in addition to the decomposition by the photocatalyst module, more kinds of odorous substances can be decomposed and removed. In addition, since the generated ozone is diffused into the oven by circulating cold air to form an ozone atmosphere, the antibacterial action can be achieved for food products in the oven, and therefore, it is also effective in maintaining freshness of the food.

According to the refrigerator according to claim 2, since the ozone decomposing means for decomposing ozone generated in the discharging means is disposed at least downstream of the discharging means and the photocatalyst module, the ozone generated by the high voltage is decomposed, and the ozone concentration in the high It rises excessively and can prevent a user from feeling ozone smell when opening a door. In addition, since ozone is decomposed, active oxygen is more likely to be generated, so that stronger oxidizing power is obtained, and deodorization efficiency is further improved.

According to the refrigerator according to claim 3, since the ozone decomposing means is disposed at the cold air intake portion of the heat exchanger, it is possible to prevent the adverse effects on the internal components by decomposing ozone at the stage before the circulation cold air enters the heat exchanger. .

According to the refrigerator of Claim 4, since the photocatalyst module is arrange | positioned at both the upstream and downstream of a discharge means, the utilization efficiency of the ultraviolet-ray generate | occur | produced in the discharge means can be improved further.

According to the refrigerator according to claim 5, the photocatalyst module is detachable from the main body of the deodorizing device. Therefore, when the contaminants such as inorganic substances adhere to the surface of the photocatalyst module, the photocatalyst module is taken out from the main body of the device, and the attached pollution is removed. It is possible to remove the substance.

According to the refrigerator according to claim 6, the photocatalyst module can be mounted to the main body by replacing the surface facing the discharge means and the surface located on the opposite side, so that the surface facing the discharge means is at a stage where adhesion of contaminants has progressed to a certain degree. By replacing the surfaces located on the opposite side and the opposite side, the photocatalytic reaction can be satisfactorily performed by using the surface on the opposite side where the contaminants are hardly attached.

According to the refrigerator according to claim 7, the photocatalyst module is fixed to the surface of the base made of porous ceramic, so that the photocatalyst module is not actively prevented from distributing cold air even when the photocatalyst module is disposed in the air blowing path. In addition, since the area for fixing the photocatalytic material to the base can be made larger, the photocatalytic reaction can be performed with high efficiency, and the hazardous substances can be decomposed and removed efficiently.

According to the refrigerator of Claim 8, since a control means makes discharge to discharge means in addition to the case where cold air circulation in a refrigerator is performed, deodorization effect | action can be performed efficiently.

According to the refrigerator of Claim 9, since a deodorizing apparatus is equipped with the fan for blowing to a discharge means and a photocatalyst module, a deodorizing apparatus is independent of a discharge means and a photocatalyst module irrespective of whether a refrigerator circulates cold air. Blowing can be performed.

According to the refrigerator according to claim 10, since the discharge means can be directly discharged between the two electrodes and detachably attached to the refrigerator main body, it is possible to take more deodorizing processing space as compared with the creepage discharge method which discharges through an insulator. Become. In addition, when the contaminant adheres to the electrode, the contaminant taken out by the discharge means from the apparatus main body can be removed.

According to the refrigerator of Claim 11, since discharge is performed by applying a negative high voltage between the electrodes of a discharge means, the amount of ozone generation can be made larger and deodorization efficiency improves.

According to the refrigerator according to claim 12, since the voltage changing means changes the discharge voltage of the discharge means, for example, by increasing the applied voltage as the number of revolutions of the fan is low and the amount of blowing is small, the deodorization efficiency according to the decrease in the blowing amount is increased. The degradation can be compensated for.

According to the refrigerator of Claim 13, since a control means stops the discharge by the discharge means at the time of opening and closing of a door, it can prevent it from performing high voltage discharge, when a user opens a door.

According to the refrigerator according to claim 14, the photocatalyst module may be disposed between the electrodes of the discharge means. If configured in this way, the ultraviolet light generated by the discharge means can be irradiated to the photocatalyst module, thereby further enhancing the photocatalytic reaction. .

According to the refrigerator of claim 15, since the deodorizer is detachable from the refrigerator main body, maintenance such as removing the deodorizer from the refrigerator, decomposing by the deodorizing action and removing substances attached to each part can be easily performed. . Therefore, it is suitable for high capacity refrigerators, such as for business use and vehicle mounting.

According to the refrigerator of claim 16, the deodorizing device can be operated by a battery, whereby the deodorizing device can be disposed where the user desires to efficiently perform the deodorizing action.

According to the deodorization apparatus of Claim 17, deodorization can be performed by arrange | positioning the deodorization apparatus in the inside of the refrigerator which does not have a deodorization function.

Claims (17)

In the refrigerator comprised in the circulation path of cold air, the deodorizing apparatus for deodorizing in a refrigerator is comprised, The deodorizing apparatus comprises a discharge means for generating ozone and ultraviolet rays by high voltage discharge, and a photocatalyst module for decomposing odor components and harmful substances contained in the air by the photocatalytic action. . The refrigerator according to claim 1, wherein ozone decomposing means for decomposing ozone generated in the discharging means is disposed at least downstream of the discharging means and the photocatalyst module. The refrigerator according to claim 2, wherein the ozone decomposing means is disposed at a cold air intake portion of the heat exchanger. The refrigerator according to any one of claims 1 to 3, wherein the photocatalyst module is disposed on both the upstream side and the downstream side of the discharge means. The refrigerator according to any one of claims 1 to 3, wherein the photocatalyst module is configured to be detachable from the main body of the deodorizer. The refrigerator according to claim 5, wherein the photocatalyst module is configured to be mounted to the main body by replacing a surface facing the discharge means and a surface located on the opposite side thereof. The refrigerator according to any one of claims 1 to 3, wherein the photocatalyst module is configured by fixing a photocatalyst material on the surface of a base made of a porous ceramic. The refrigerator according to any one of claims 1 to 3, further comprising a control means for controlling the discharge means to discharge when the cold air circulation in the furnace is performed. The refrigerator according to any one of claims 1 to 3, wherein the deodorizer includes a fan for blowing air to the discharge means and the photocatalyst module. The refrigerator according to any one of claims 1 to 3, wherein the discharge means is configured to discharge directly between the two electrodes and is detachably attached to the deodorizing device main body. The refrigerator according to any one of claims 1 to 3, wherein a discharge is performed by applying a negative high voltage between the electrodes of the discharge means. The refrigerator according to any one of claims 1 to 3, comprising voltage changing means for changing a discharge voltage of the discharge means. The refrigerator according to any one of claims 1 to 3, comprising control means for controlling to stop the discharge by the discharge means when the door is opened. The refrigerator according to any one of claims 1 to 3, wherein the photocatalyst module is disposed between the electrodes of the discharge means. The refrigerator according to any one of claims 1 to 3, wherein the deodorizing device is configured to be detachable from the refrigerator main body. The refrigerator according to claim 15, wherein the deodorizing device is configured such that at least the operation of the discharge means is possible by supplying power from the battery. It is used for the refrigerator in any one of Claims 1-3, The deodorizing apparatus characterized by the above-mentioned.