KR100515114B1 - Deodorizing Device for Food Garbage Disposal - Google Patents

Abstract

The present invention relates to a deodorizing apparatus of a food waste disposal apparatus, the body 10 having a fermentation tank 11 for storing and fermenting food waste inside the body and a stirrer 12;

It is installed in communication with the inside and outside the body of the main body 10 comprises a deodorizing means 20 for removing water vapor and odor gas generated during operation of the stirrer 12;

The deodorizing means 20 has a first chamber 30 which is installed to one side of the fermentation tank 11 and in communication with the inside of the fermentation tank 11;

A filter 31 installed inward from one side of the first chamber 30;

A photocatalyst 40 communicating with the first chamber 30 and installed above the filter 31;

A second chamber 50 interconnected by a duct 51 to a side portion of the photocatalyst 40;

A gas connection pipe 60 for moving the gas primarily processed by the fan 61 configured as an upper part of the body of the second chamber 50;

A housing 70 in which the gas connection pipe 60 is located at a bottom surface and communicates with each other, and a space portion 140 is formed in the body and is spaced up and down;

The heater rod 81 is formed inside the body so as to be in contact with the gas passing through the photocatalyst 40 and the photocatalyst 40 and the gas connecting tube 60 inside the housing 70. An oxidation reaction unit 80 having a heater case 82 therein;

A thermal catalyst unit 90 installed in communication with the upper portion of the oxidation reaction unit 80 and deodorizing while being in contact with the gas through the oxidation reaction unit 80;

It is partitioned and installed in the upper portion of the thermal catalyst unit 90, the central portion is provided with the exhaust port 110 in communication with the thermal catalyst unit 90, preheating the space portion 140 is formed on one side of the exhaust port 110 An air chamber 100;

An air suction port 120 installed at one side of the preheating air chamber 100 to introduce external air into the inner space 140;

Formed to the other side of the body of the preheated air chamber 100 and formed in communication with the fermentation tank 11 to return the heat exchanged gas in the preheating air chamber 100 to the fermentation tank 11 through the air inlet 120 Since it consists of a heated air discharge pipe 130, while the deodorizing device of the present invention food waste disposal process by performing the configuration of the photocatalyst and the deodorizing device using a high temperature oxidation method in order to perform the deodorizing operation complex, while passing through the photocatalyst The generated ozone and undeodorized gas can be deodorized and extinguished at high temperature through the thermal catalyst, thereby improving the deodorizing efficiency.

Therefore, it is a very useful invention that can improve the reliability and commerciality of the product.

Description

Deodorizing Device for Food Garbage Disposal

The present invention relates to a deodorizing device of a food waste treatment device, and more particularly, to a combination of a photocatalyst and a high temperature oxidation type deodorizing device, invented to improve the deodorizing performance and maximize energy efficiency.

In general, a certain amount of food waste is discharged every day from each home or restaurant, and the residue is used as a livestock feed, or is only discarded after filtering the mixed water through a simple strainer.

The general food waste treatment apparatus has a predetermined width and size, and has a main body having an accommodating portion therein, a fermentation tank installed in the accommodating portion of the main body for storing and fermenting food waste, and installed inside the fermentation tank. It is largely composed of a stirrer for mixing food waste by the motor drive, and a deodorizing means is installed inside and outside the body of the main body to remove steam and odor gas generated during operation of the stirrer.

On the other hand, the deodorizing means of the food waste treatment apparatus is a situation in which the activated carbon filter, ozone, a high temperature oxidation method using a thermal catalyst, a photocatalytic oxidation method and the like are used.

As described above, the deodorization means of the conventional food waste disposal apparatus has to raise the active temperature of the catalyst in order to improve the deodorization performance, which causes a lot of energy costs.

After a certain time, the deodorization performance due to sulfur poisoning of the catalyst is sharply lowered.

In addition, the energy maintenance cost can be saved when using the photocatalyst deodorizer, but excessive ozone was generated, and the odor purification rate was less than expected.

SUMMARY OF THE INVENTION An object of the present invention is to provide a deodorizing apparatus for a food waste disposal system, which is configured by combining a photocatalyst and a high temperature oxidation deodorizing apparatus, thereby improving deodorizing performance and maximizing energy efficiency.

It is another object of the present invention to provide a deodorizing apparatus of a food waste processor that maximizes the deodorizing effect by allowing the ozone and the undeodorized gas generated while passing through the photocatalyst to pass through the high temperature portion of the thermal catalyst.

Still another object of the present invention is to provide a deodorization apparatus for a food waste disposal system capable of improving reliability and quality stabilization of a product.

An object of the present invention, the main body 10 having a fermentation tank 11 and a stirrer 12 for storing and fermenting food waste inside the body;

It is installed in communication with the inside and outside the body of the main body 10 comprises a deodorizing means 20 for removing water vapor and odor gas generated during operation of the stirrer 12;

The deodorizing means 20 has a first chamber 30 which is installed to one side of the fermentation tank 11 and in communication with the inside of the fermentation tank 11;

A filter 31 installed inward from one side of the first chamber 30;

A photocatalyst 40 communicating with the first chamber 30 and installed above the filter 31;

A second chamber 50 interconnected by a duct 51 to a side portion of the photocatalyst 40;

A gas connection pipe 60 for moving the gas primarily processed by the fan 61 configured as an upper part of the body of the second chamber 50;

A housing 70 in which the gas connection pipe 60 is located at a bottom surface and communicates with each other, and a space portion 140 is formed in the body and is spaced up and down;

The heater rod 81 is formed inside the body so as to be in contact with the gas passing through the photocatalyst 40 and the photocatalyst 40 and the gas connecting tube 60 inside the housing 70. An oxidation reaction unit 80 having a heater case 82 therein;

A thermal catalyst unit 90 installed in communication with the upper portion of the oxidation reaction unit 80 and deodorizing while being in contact with the gas through the oxidation reaction unit 80;

It is partitioned and installed in the upper portion of the thermal catalyst unit 90, the central portion is provided with the exhaust port 110 in communication with the thermal catalyst unit 90, preheating the space portion 140 is formed on one side of the exhaust port 110 An air chamber 100;

An air suction port 120 installed at one side of the preheating air chamber 100 to introduce external air into the inner space 140;

Formed to the other side of the body of the preheated air chamber 100 and formed in communication with the fermentation tank 11 to return the heat exchanged gas in the preheating air chamber 100 to the fermentation tank 11 through the air inlet 120 It is achieved by consisting of a heated air discharge pipe (130).

Therefore, the deodorizing device of the food waste processor of the present invention allows the deodorizing operation to be performed in combination while sequentially proceeding with the configuration of the photocatalyst and the high temperature oxidation method, so that ozone and undeodorized gas generated while passing through the photocatalyst are Deodorization and extinction at high temperatures through the thermal catalyst can improve the deodorization efficiency.

Therefore, the reliability and the merchandise of the product can be improved.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing the configuration of a food waste processor deodorizing apparatus to which the present invention is applied.

Figure 2 is a cross-sectional view showing the configuration of the thermal catalyst deodorizer in the deodorizing apparatus to which the present invention is applied.

Figure 3 is an enlarged perspective view of the main portion showing the configuration of the air control damper is installed on the body of the heating air supply pipe.

4 is a cross-sectional view illustrating a configuration of an air control damper formed in a heating air supply pipe.

That is, the deodorizing apparatus of the present food waste treatment apparatus as shown in Figure 1 to Figure 4 relates to a hybrid deodorizing apparatus mixed with a photocatalyst and a high temperature oxidation method.

The first chamber 30 in communication with the inside of the fermentation tank 11 is provided at the upper side of the fermentation tank 11 in the present invention deodorizing means.

The first chamber 30 is formed in the upper portion of the inlet 13 formed in the body of the fermentation tank 11, and serves to capture the odor gas generated during the stirring process in the fermentation tank (11).

In addition, a filter 31 is installed at the inner side of the body of the first chamber 30 to serve to catch foreign substances and dust in the process of transferring the malodorous gas through the first chamber 30.

On the other hand, the upper portion of the body of the first chamber 30 is provided with a photocatalyst 40 is configured to communicate with the first chamber (30).

The photocatalyst 40 serves to substantially purify the malodorous gas introduced through the first chamber 30 in the fermentation tank 11 and constitutes a plasma type photocatalyst applied to a food waste treatment apparatus. It is to be used by applying, and it is found that this configuration is the same as the conventional general photocatalyst configuration.

In addition, a second chamber 50 which is interconnected through the duct 51 is formed as a side portion of the photocatalyst 40.

As shown in the drawing, the second chamber 50 is installed to collect ozone and undeodorized gas in the state where the primary deodorization operation is completed through the photocatalyst 40.

In addition, a gas connecting pipe 60 is formed at the upper portion of the body side of the second chamber 50 to move the gas moved through the fan 61 to the next secondary deodorizer.

The gas connection pipe 60 is configured to re-deodorize the odor gas first processed through the high temperature oxidation method in the housing 70 to be described later again by the high temperature oxidation method.

Therefore, the fan 61 which moves the malodorous gas processed primarily through the gas connection pipe 60 initially transmits the malodorous gas generated in the fermentation tank 11 to the initial photocatalyst 40. Since the role of flowing into the photocatalyst 40 through the configuration has a configuration in communication with each other, it is possible.

On the other hand, the gas connection pipe 60 may be located to the bottom of the housing 70 may supply the first malodorous gas to the interior of the housing 70.

In addition, the housing 70 is formed in each of the space portion 140 partitioned up and down inside the body.

As shown in the drawing, the housing 70 includes a plurality of spaces 140 partitioned into the body, and the spaces 140 partitioned by the partition plates 71 are spaced by the respective partition plates 71. ) Can be configured independently.

That is, the odor gas, which is primarily deodorized through the photocatalyst 40, is introduced into the bottom entrance hole 72 of the housing 70 through the fan 61 provided in the gas connection pipe 60. While rising in a straight direction, it is exhausted after passing through the oxidation reaction unit 80 and the thermal catalyst unit 90 to be described later.

Therefore, the housing 70 is a partition plate 71 is formed so that the oxidation reaction unit 80 and the thermal catalyst unit 90 can be independently communicated with each other, and will be described later on the thermal catalyst unit 90. The preheated air chamber 100 and the thermal catalyst unit 90 are separated by the partition plate 71.

In addition, it is preferable to insert and install the heat insulating material 150 on the outer surface of the housing 70 for temperature maintenance and the like.

On the other hand, the bottom portion of the housing 70 is formed in communication with each other through the photocatalyst 40 and the gas connection pipe 60, the odor gas and ozone gas that is primarily processed while passing through the photocatalyst 40 The heater rod 81 is formed inside the body and the oxidation reaction unit 80 provided with the heater case 82 is formed inside the body so as to be contacted while being lifted upward.

That is, the odor gas deodorized first and the ozone gas generated at this time are introduced into the heater case 82 of the oxidation reaction unit 80 while being in contact with the high temperature heater rod 81 through the photocatalyst unit 40. Some oxidation occurs.

The temperature sensor 160 is installed at one side of the oxidation reaction unit 80 so as to set a proper temperature by sensing a set temperature of the heater rod 81.

In addition, the gas in which the oxidation reaction is performed while contacting the heater rod 81 of the oxidation reaction unit 80 is installed in communication with the upper portion of the oxidation reaction unit 80 is in contact with the gas through the oxidation reaction unit 80 While moving to the thermal catalyst unit 90 to deodorize.

In addition, it is preferable to install a heat insulating material 140 on the outer side of the thermal catalyst part 90 to maintain heat.

Therefore, in the configuration of the present invention, the food waste processor deodorizing means using the photocatalyst and the thermal catalyst in combination is the odor gas introduced from the fermentation tank 11 is introduced through the first chamber 30, the foreign matter is filter 31 It is caught by, and then deodorizing operation can be performed while sequentially contacting the photocatalyst portion 40, the oxidation reaction portion 80 and the thermal catalyst portion 90.

 As a result, unlike the conventional deodorizing means, the deodorizing operation is sequentially performed through the thermal catalyst unit 90 of the ozone gas and the undeodorized gas which are first processed and remain while passing through the photocatalyst unit 40 in the housing 70. Because it can be, to maximize the deodorization efficiency.

On the other hand, the upper portion of the thermal catalyst portion 90 is partitioned in the housing 70, the central portion is provided with an exhaust port 110 in communication with the thermal catalyst portion 90, one side of the exhaust port 110 The preheated air chamber 100 is formed with a space 140 is formed.

In addition, an air inlet 120 for introducing external air into the inner space 140 is installed at one side of the body of the preheating air chamber 100.

This is, after all, the gas which is finally deodorized through the thermal catalyst 90 is discharged through the air inlet 120 in the process of being discharged through the exhaust port 110 provided inside the preheating air chamber 100. As the heat exchange with the air is made, the final exhaust is made.

In addition, the other side of the body of the preheating air chamber 100 to communicate with the fermentation tank 11 to return the heat exchanged gas in the preheating air chamber 100 to the fermentation tank 11 through the air inlet 120. The formed heated air discharge pipe 130 is formed.

The heated air discharge pipe 130 is configured to introduce fresh and warm air necessary for aerobic microorganisms into the fermentation tank 11, and finally, deodorization is finished through the thermal catalyst unit 90 as shown in the drawing. In the process of exhausting the extracted gas to a high temperature through the exhaust port 110 configured in the preheating air chamber 100, the exhausted gas is contacted with the external air introduced through the air intake port 120, and then exhausted after heat exchange. Air can also be converted to warm air as it is heat exchanged.

On the other hand, one side of the lower body of the heating air discharge pipe 130 is provided with an air control damper 131 to adjust the appropriate temperature by introducing external air in the process of supplying preheated air into the fermentation tank.

As shown in FIGS. 3 and 4, the air control damper part 131 includes an air inlet hole 132 formed at one side of a lower body of the heated air discharge pipe 130, and an inner surface of the air inlet hole 132. One side of the body is fixed by the fixing means 133, the guide plate 135 is provided with an inclined surface 134 protruding toward the center portion and the heating air discharge pipe 130 to the other side of the guide plate 135 The upper part of the body is provided with a plurality of fixing holes 136 to selectively open and close the air inlet hole 132 formed in the body of the intermittent to the heating air discharge pipe 130 by the fixing means 133, The lower part of the body is composed of a control plate 138 having a guide portion 137 bent inwardly.

Therefore, the air control damper part 131 configured as the lower part of the body of the heated air discharge pipe 130 is a fermentation tank 11 according to the temperature of the fermentation tank 11 and the amount of food introduced into the warm air supplied to the fermentation tank 11. The temperature of the warm air supplied to the can be adjusted through the air control damper unit 131.

In the end, in order to inflow and close the outside air through the external air inlet hole 132, by using the fixing holes 136 formed by releasing the fixing means 133 to control the control plate 138 is provided a plurality of By lowering and raising the control plate 138, the external air inlet hole 132 may be blocked or opened.

That is, as the height of the adjustment plate 138 is set differently by such a configuration, the guide part 137 configured as the lower portion of the adjustment plate 138 is bent inclined in a predetermined direction to the inside, and thus the guide plate 135 configured as the other side. It is possible to open or close the air passage of the inclined surface 134 and optionally.

As a result, when viewed in the above configuration, when blocking the air inlet hole 132, the inclined surface 134 and the guide portion 137 of the control plate 138 and the guide plate 135 to open the inner air passage 170 is mutually When the air inlet hole 132 is opened, the outside air is introduced into the air passage 170 through the rear side of the guide part 137, and at this time, the guide part 137 and the guide plate ( Through the moving hole 180 having a relatively small tolerance of the inclined surface 134 of 135, the heated air is lowered and mixed to adjust the appropriate temperature.

Therefore, the most important feature in the configuration of the present invention, unlike the conventional deodorizing means through the photocatalyst portion 40 and the thermal catalyst portion 90 through the composite configuration sequentially deodorization is made, the air intake in the process of exhaust The hot gas exhausted by the external air introduced through the 120 is heat-exchanged and then exhausted and at the same time the external air heat-exchanged in this process is returned back into the fermentation tank 11 through the heating air discharge pipe 130 and the fermentation tank ( 11) The aerobic microorganisms are heat-exchanged and supplied with warm air, which is easily activated.

Therefore, the configuration of the present invention is the odor gas introduced through the first chamber 30 in the fermenter 11 after filtering through the filter 31 to the gas connecting pipe 60 in the second chamber 50. Oxidation reaction part through the fan 61 provided ?? The deodorizing operation is finally performed while the thermal catalyst is sequentially processed on a vertical line. In the final exhaust process, the gas exhausted by the external air introduced through the air inlet 120 is exchanged and discharged, and at the same time, the heated air discharge pipe 130 is opened. The external air heat exchanged through is returned to the fermentation tank 11 again.

According to the configuration of the present invention as described above, since the deodorization operation is carried out by sequentially configuring the photocatalyst portion and the thermal catalyst portion as compared to the deodorizing means of the conventional food waste treatment apparatus, it is possible to maximize the deodorization efficiency.

In addition, since the heat energy that goes out to the waste heat in the relatively small space can be recovered as much as possible, the heat energy consumption rate can be reduced and the flow path through the fan can be shortened, thereby improving the performance of the deodorizing means.

Therefore, it is a very useful invention that can improve the reliability and convenience of work.

1 is a perspective view showing the configuration of a food waste processor deodorizing apparatus to which the present invention is applied.

Figure 2 is a cross-sectional view showing the configuration of the thermal catalyst deodorizer in the deodorizing apparatus to which the present invention is applied.

Figure 3 is an enlarged perspective view of the main portion showing the configuration of the air control damper is installed on the body of the heating air supply pipe.

Figure 4 is a cross-sectional view showing the use condition of the air control damper formed in the heating air supply pipe.

      * Description of the symbols for the main parts of the drawings *

10-main body 11-fermenter

12-Agitator 13-Inlet

20-deodorizing means 30-first chamber

31-Filter 40-Photocatalyst

50-second chamber 51-duct

60-gas connector 61-fan

70-housing 71-partition plate

72-access hole 80-oxidation part

81-Heater Rod 82-Heater Case

90-Thermal catalyst section 100-Preheating air chamber

110-exhaust 120-air intake

130-Heated air discharge pipe 131-Air control damper part

132-Air inlet hole 133-Fixing means

134-Slope 135-Guides

136-fixing hole 137-guide part

138-Throttle 140-Space

150-Insulation 160-Temperature Sensor

170-Airway 180-Moving Hole

Claims (3)

A body 10 having a fermentation tank 11 for storing and fermenting food waste and a stirrer 12 inside the body; It is installed in communication with the inside and outside the body of the main body 10 comprises a deodorizing means 20 for removing water vapor and odor gas generated during operation of the stirrer 12; The deodorizing means 20 has a first chamber 30 which is installed to one side of the fermentation tank 11 and in communication with the fermentation tank 11; A filter 31 installed inward from one side of the first chamber 30; A photocatalyst 40 communicating with the first chamber 30 and installed above the filter 31; A second chamber 50 interconnected by a duct 51 to a side portion of the photocatalyst 40; A gas connection pipe 60 for moving the gas primarily processed by the fan 61 configured as an upper part of the body of the second chamber 50; A housing 70 in which the gas connection pipe 60 is located at a bottom surface and communicates with each other, and a space portion 140 is formed in the body and is spaced up and down; The heater rod 81 is formed inside the body so as to be in contact with the gas passing through the photocatalyst 40 and the photocatalyst 40 and the gas connecting tube 60 inside the housing 70. An oxidation reaction unit 80 having a heater case 82 therein; A thermal catalyst unit 90 installed in communication with the upper portion of the oxidation reaction unit 80 and deodorizing while being in contact with the gas through the oxidation reaction unit 80; It is partitioned and installed in the upper portion of the thermal catalyst unit 90, the central portion is provided with the exhaust port 110 in communication with the thermal catalyst unit 90, preheating the space portion 140 is formed on one side of the exhaust port 110 An air chamber 100; An air suction port 120 installed at one side of the preheating air chamber 100 to introduce external air into the inner space 140; It is formed to communicate with the fermentation tank 11 so as to return to the fermentation tank 11, the heat exchanged gas in the preheating air chamber 100 through the air suction port 120 while being formed to the other side of the body of the preheating air chamber 100. Deodorizer of the food waste treatment apparatus, characterized in that consisting of a heated air discharge pipe (130). The apparatus of claim 1, wherein an air control damper part is formed at an inner side of the body of the heated air discharge pipe 130. The method of claim 2, wherein the air control damper unit 131 is an air inlet hole 132 formed to one side of the lower body of the heating air discharge pipe 130; A guide plate 135 having an inclined surface 134 protruding toward a central portion of the inner surface of the air inlet hole 132, the other side of which is fixed by a fixing means 133; The fixing means 133 is provided with a plurality of fixing holes 136 at the upper portion of the body to selectively open and close the air inlet hole 132 formed in the body of the heating air discharge pipe 130 to the other side of the guide plate 135. The deodorizer of the food waste disposer characterized in that it is intermittent to the heated air discharge pipe 130 by a control plate 138 having a guide portion 137 bent inclined inward to the lower body.