KR20210023639A - Organic Waste Treatment Apparatus - Google Patents

Abstract

The present invention relates to an apparatus for treating an organic waste. According to an embodiment of the present invention, the apparatus for treating the organic waste includes: a reaction tank including an air inlet and an air outlet to treat the organic waste by making a reaction with aerobic or hydrophilic microorganisms in the state that the organic waste is received in the reaction tank; a stirring blade installed inside the reaction tank; an air injection unit coupled to one surface of the reaction tank to inject air heated to a set temperature into the reaction tank; an air circulation unit connected to the air outlet, such that air discharged from the reaction tank is connected to the air injection unit to be supplied back to the reaction tank; a reaction tank heating unit formed on an outer surface of the reaction tank to maintain the reaction tank to have an appropriate temperature; a stirring blade driving unit connected to the stirring blade to apply hydraulic pressure to the stirring blade; and a controller.

Description

Organic Waste Treatment Apparatus}

The present invention relates to an organic waste treatment apparatus capable of fermenting and treating organic waste.

Organic waste (food waste, livestock manure, sewage sludge) is an inevitable waste, and its generation is on the rise in recent years with an increase in population and high-quality living. Methods for treating such organic waste include incineration, landfill, composting, feed conversion, and the like.

However, in the case of incineration among the above methods, there are enormous costs for treatment, secondary environmental pollution caused by incineration residues, and adverse effects when entering the human body.In the case of reclamation, the surrounding soil and The river is contaminated, and the methods of composting and feeding have a problem of consuming a lot of fuel in the heat-drying treatment.

In order to solve this problem, a device for biologically decomposing organic waste by aerobic microorganisms has been developed, but there is a problem that the air supply nozzle is frequently clogged in supplying heated air for removing moisture generated during decomposition of organic waste. In addition, when some of the plurality of nozzles are clogged, there is a problem in that air is supplied to the remaining nozzles, thereby reducing air supply efficiency.

The present invention is to provide an organic waste treatment apparatus capable of effectively treating organic waste.

In addition, the present invention is to provide an organic waste treatment apparatus capable of effectively supplying heated air.

In addition, the present invention is to provide an organic waste treatment apparatus capable of improving a nozzle clogging phenomenon in the supply of heated air.

In addition, the present invention is to provide an organic waste treatment apparatus capable of improving the supply of air to the remaining nozzles because some of the plurality of nozzles are blocked in the supply of heated air.

In addition, the present invention is to provide an organic waste treatment apparatus capable of effectively removing moisture and odors in air discharged from a reaction tank.

In addition, the present invention is to provide an organic waste treatment apparatus capable of reducing the fuel used to heat the reaction tank.

According to an aspect of the present invention, an air inlet portion and an air outlet portion are formed, and a reaction vessel that is a container that reacts and treats an aerobic or hydrophilic microorganism in a state where an organic waste is accommodated therein, a stirring blade installed inside the reaction vessel, the An air injection unit coupled to one side of the reaction tank to inject air heated to a set temperature into the reaction tank, and the air discharged from the reaction tank is connected to the air injection unit to be supplied back to the reaction tank. An organic waste treatment apparatus comprising an air circulation unit, a reaction tank heating unit formed on the outer surface of the reaction tank to maintain an appropriate temperature of the reaction tank, a stirring blade driving unit connected to the stirring blade to supply hydraulic pressure to the stirring blade, and a control unit Can be provided.

In addition, the air injection unit is an air chamber coupled to one surface adjacent to the stirring blade in the reaction tank, an air injection nozzle connected to the air chamber, a check valve installed on a flow path connecting the air chamber and the air injection nozzle, An organic waste treatment apparatus including an air chamber heater in which a heating wire is coupled to be exposed to an inner space of the air chamber, and an air chamber temperature sensor installed in the air chamber or the air chamber heater may be provided.

In addition, the air circulation unit has one end connected to the air discharge unit, the other end is located in the air discharge pipe connected to the air chamber, the air discharge pipe, the injection bubbling blower for sucking the internal air of the reaction tank, the air discharge pipe A condenser positioned between the air outlet and the outlet blower, or a condenser positioned on a downstream side of the outlet blower, a moisture separator positioned on the air outlet pipe, and a moisture separator positioned on the downstream side of the condenser, An organic waste treatment apparatus may be provided that is located and includes an injection blower installed on a downstream side connected to the air chamber, and a deodorization unit located on the air discharge pipe and located on an upstream side of the injection blower.

In addition, the reaction tank heating unit is an organic waste treatment apparatus including a water chamber installed on the outer bottom surface of the reaction tank, a water chamber heater installed on the bottom surface of the water chamber, and a water chamber temperature sensor installed in the water chamber or the water chamber heater. Can be provided.

In addition, the stirring blade driving unit is connected to the stirring blade, a hydraulic motor that provides a driving force to the stirring blade, one end is coupled to the hydraulic motor to supply hydraulic pressure to the hydraulic motor, and installed in the hydraulic supply pipe, An organic waste treatment apparatus including a hydraulic supply unit for supplying oil and a supply control valve installed in the hydraulic supply pipe to supply the supplied oil in a forward or reverse direction may be provided.

According to an embodiment of the present invention, an organic waste treatment apparatus capable of effectively treating organic waste may be provided.

In addition, according to an embodiment of the present invention, an organic waste treatment apparatus capable of effectively supplying heated air may be provided.

In addition, according to an embodiment of the present invention, an organic waste treatment apparatus capable of improving a nozzle clogging phenomenon in supplying heated air may be provided.

In addition, according to an embodiment of the present invention, an organic waste treatment apparatus capable of improving the supply of heated air due to the supply of air to the remaining nozzles due to clogging of some of the plurality of nozzles may be provided.

In addition, according to an embodiment of the present invention, an organic waste treatment apparatus capable of effectively removing moisture and odors in air discharged from the reaction tank may be provided.

In addition, according to an embodiment of the present invention, an organic waste treatment apparatus capable of reducing fuel used to heat a reaction tank may be provided.

1 is a view schematically showing an organic waste treatment apparatus according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating the reaction tank of FIG. 1.
3 is a side view of the air chamber of FIG. 2.
4 is a structure of the air injection nozzle of FIG. 3.
5 is a block diagram functionally showing a configuration related to operation control of an organic waste treatment apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the following embodiments. This embodiment is provided to more completely explain the present invention to those with average knowledge in the industry. Therefore, the shape of the element in the drawings is exaggerated to emphasize a more clear description.

1 is a view schematically showing an organic waste treatment apparatus according to an embodiment of the present invention, FIG. 2 is a view showing the reaction tank of FIG. 1, FIG. 3 is a side view of the air chamber of FIG. 2, and FIG. 4 is This is the structure of the air injection nozzle of FIG. 3.

1 to 4, the organic waste treatment apparatus 10 includes a reaction tank 110, a stirring blade 120, an air injection unit 130, an air circulation unit 140, a reaction tank heating unit 150, and agitation. It includes a wing drive unit 160 and a control unit 170.

The reaction tank 110 is a container for treating by reacting with aerobic or hydrophilic microorganisms while containing organic waste therein. An air inlet 110a is formed on one side of the reaction tank 110. The air inlet 110a allows external air to be introduced into the reaction tank 110. The air inlet 110a may introduce external air due to a negative pressure generated due to a difference in flow rate between the air discharged from the reaction tank 110 and the air injected and supplied. The air inlet 110a supplies new external air into the reaction tank 110. Accordingly, the organic waste accommodated in the reaction tank 110 can be treated by reacting with aerobic or hydrophilic microorganisms. An air outlet 110b is formed on one side of the reaction tank 110. For example, the air discharge part 110b may be formed on a surface facing the surface on which the air inlet 110a is formed based on the central region of the reaction tank 110. The air discharge unit 110b is connected to the air circulation unit 140. The air discharge unit 110b allows air discharged from the reaction tank 110 to be supplied to the air circulation unit 140. In addition, the air inlet 110a may be provided so that communication with the outside is closed and air inside the reaction tank 110 is introduced. At this time, the air inside the reaction tank 110 introduced into the air inlet 110a may be discharged to the air outlet 110b through a separately formed passage. A temperature sensor 111 and a moisture sensor 112 are installed on an inner surface of the reaction tank 110. The temperature sensor 111 senses the temperature in the reaction tank 110. In addition, the moisture sensor 112 detects the moisture content of the organic waste injected into the reaction tank 110. In this way, based on the temperature in the reaction tank 110 sensed by the temperature sensor 111 and the moisture sensor 112 and the moisture content data of the organic waste, the control unit 170 to be described later ensures that the temperature in the reaction tank 110 is properly maintained. .

The stirring blade 120 is installed inside the reaction tank 110. The stirring blade 120 stirs organic waste with aerobic or hydrophilic microorganisms. The rotating shaft of the stirring blade 120 may be provided in a direction parallel to the ground. Stirring blades 120 may be provided in a pair. A pair of stirring blades 120 may be provided to be positioned in a direction in which the rotation axis crosses with respect to the vertical direction, respectively. In this case, a trajectory in which each of the stirring blades 120 is rotated may be provided such that regions facing each other are adjacent or intersected.

The air injection unit 130 is coupled to one surface of the reaction tank 110. The air injection unit 130 is coupled to one surface of the reaction tank 110 to inject air heated to a set temperature into the reaction tank 110. The air injection unit 130 includes an air chamber 131, an air injection nozzle 132, a check valve 133, an air chamber heater 134, and an air chamber temperature sensor 135.

The air chamber 131 is coupled to one surface adjacent to the stirring blade 120 in the reaction tank 110. For example, the air chamber 131 may be provided to be coupled to the bottom surface of the reaction tank 110. The air chamber 131 may be provided in a columnar shape such as a cylinder. The air chamber 131 may be provided in a form in which at least a part of the outer surface is exposed to the inside of the reaction tank 110 or may be provided in a form fixed to the outer surface of the air chamber 131. The air chamber 131 may be located below a region in which the pair of stirring blades 120 face each other. The air chamber 131 has a set length in the direction of the rotation axis of the pair of stirring blades 120. One side of the air chamber 131 is connected to the air circulation unit 140. Air that has passed through the air circulation unit 140 is supplied to the air chamber 131.

The air injection nozzle 132 is provided to be connected to the air chamber 131. The air injection nozzle 132 is formed on the outer surface of the air chamber 131 exposed to the inside of the reaction tank 110, or the air chamber 131 is located on the inner surface of the reaction tank 110 and fixed to the outer surface of the reaction tank 110 It can be provided to be connected with. The air injection nozzle 132 is formed so that the trajectory of the stirring blade 120 faces the upper portion of the reaction tank 110 under the area where the trajectories of the stirring blade 120 face each other. Accordingly, air supplied to the air chamber 131 through the air injection nozzle 132 is injected into the reaction tank 110. A plurality of air injection nozzles 132 may be formed along the longitudinal direction in the axial direction of the stirring blade 120. By allowing the air injected into the reaction tank 110 to be supplied between the pair of stirring blades 120, activation of aerobic or hydrophilic microorganisms is further improved, thereby improving the treatment efficiency of organic waste.

The check valve 133 is installed on a flow path connecting the air chamber 131 and the air injection nozzle 132. The check valve 133 is provided to be opened from the air chamber 131 to the air injection nozzle 132 when a set pressure is applied in the air chamber 131 direction, so that the air in the air chamber 131 is transferred to the air injection nozzle 132 ) To flow only in the direction of injection into the reaction tank 110. When the direction in which air is injected from the air chamber 131 into the reaction tank 110 is referred to as a forward direction and the opposite direction is referred to as a reverse direction, the check valve 133 is opened only when the air flows in the forward direction. When the air flows in the forward direction, the check valve 133 is opened by the pressure of the air. Accordingly, air may be injected through the air injection nozzle 132. The check valve 133 is closed when air flows in the reverse direction. Accordingly, it is possible to prevent air from flowing backward through the air injection nozzle 132. Accordingly, it is possible to prevent the material inside the reaction tank 110 from being introduced into the air injection nozzle 132 and clogging the air injection nozzle 132. By solving the nozzle clogging phenomenon in this way, air can be supplied more effectively by solving the phenomenon in which air is supplied unevenly due to clogging of some nozzles.

The air chamber heater 134 is coupled to the air chamber 131 so that the heating wire is exposed to the inner space of the air chamber 131. The air chamber heater 134 may be coupled to the inner surface or both ends of the air chamber 131. The air chamber heater 134 heats the air contained in the air chamber 131. The heated air is directly injected into the reaction tank 110. Since the heated air is directly injected into the reaction tank 110, heat dissipation to the outside of the air chamber 131 can be reduced. Accordingly, thermal efficiency increases.

The air chamber temperature sensor 135 is installed in the air chamber 131 or the internal configuration of the air chamber 131. The air chamber temperature sensor 135 may be installed on the inner surface of the air chamber or may be installed on the air chamber heater 134. The air chamber temperature sensor 135 detects the temperature in the air chamber 131 or the heating temperature of the air chamber heater 134. In this way, based on the temperature data sensed by the air chamber temperature sensor 135, the control unit 170, which will be described later, maintains an appropriate temperature in the air chamber 131 or prevents the air chamber heater 134 from overheating.

The air circulation unit 140 allows the air discharged from the reaction tank 110 to be supplied back to the reaction tank 110. As the air discharged from the reaction tank 110 passes through the air circulation unit 140, moisture is removed. The air circulation unit 140 includes an air discharge pipe 141, a discharge blower 142, a condenser 143, a water separator 144, an injection blower 145, and a deodorization unit 146.

The air discharge pipe 141 has one end connected to the air discharge part 110b. In addition, the other end of the air discharge pipe 141 is connected to the air chamber 131. Hereinafter, a direction in which the air discharge pipe 141 is connected to the air discharge unit 110b is referred to as an upstream side, and a direction connected to the air chamber 131 is referred to as a downstream side.

The discharge bubbling blower 142 is located in the air discharge pipe 141 to allow the internal air of the reaction tank 110 to be sucked into the air discharge pipe 141. The discharge blower 142 is located adjacent to the air discharge part 110b. The flow rate of the discharge blower 142 may be set higher than the flow rate of the injection blower 145. Accordingly, outside air may be introduced into the air discharge pipe 141 together with the suction of the internal air of the reaction tank 110. In addition, a vent flow path for discharging air to the outside may be branched at one point of the air discharge pipe 141. A second discharge part blower 142a may be additionally installed in the vent passage. The second discharge bubbling blower 142a may discharge some of the air sucked through the air discharge pipe 141 to the outside of the air discharge pipe 141.

The condenser 143 is located in the air discharge pipe 141 to cool the air sucked into the air discharge unit 110b so that moisture contained in the air is condensed. The condenser 143 may be located between the air discharge unit 110b and the discharge blower 142, or may be located on the downstream side of the discharge blower 142. Also, the condenser 143 may be omitted.

The moisture separator 144 is located in the air discharge pipe 141 so that residual moisture contained in the air passing through the condenser 143 is separated from the air. The water separator 144 is located on the downstream side of the condenser 143. In addition, when the condenser 143 is not installed in the air discharge pipe 141, only the moisture separator 144 may be installed. In this case, the water separator 144 is located on the upstream side of the air discharge pipe 141, and the discharge blower 142 may be connected to the water separator 144 as a separate pipe. A separate supply control valve may be installed in a separate pipe to which the discharge blower 142 and the water separator 144 are connected.

The injection blower 145 supplies air from which moisture has been removed to the air chamber 131. The injection blower 145 is installed at a downstream end connected to the air chamber 131. The flow rate of the injection blower 145 may be set lower than the flow rate of the discharge blower 142. Accordingly, the amount of air supplied to the air injection unit 130 through the injection blower 145 may be provided smaller than the amount of air discharged from the reaction tank 110 to the air circulation unit 140. A negative pressure is generated inside the reaction tank 110 due to such a difference in flow rate. External air may be introduced through the air inlet 110a by the negative pressure generated in this way.

The deodorizing unit 146 is located in the air discharge pipe 110b, so that odor molecules in the air circulating through the air circulation unit 140 can be effectively adsorbed or divided into fine molecules to remove odors. The deodorization part 146 is located in the vent flow path branched from the air discharge pipe 141 and is located adjacent to the second discharge blower 142a. In addition, when the second discharge blower 142a is not installed, the deodorization unit is located adjacent to the discharge blower 142.

The reaction tank heating unit 150 is formed on the outer surface of the reaction tank 110. The reaction tank heating unit 150 heats the reaction tank 110 so that the internal temperature of the reaction tank 110 is maintained at an appropriate temperature. The appropriate temperature is about 40 ~ 60 ℃ for fermentation treatment of organic waste inside the reaction tank (110). The reaction tank heating unit 150 includes a water chamber 151, a water chamber heater 152, and a water chamber temperature sensor 153.

The water chamber 151 is installed on the outer surface of the reaction tank 110. The water chamber 151 may be installed on a lower bottom surface of a portion where the pair of stirring blades 120 are located. In addition, the water chamber 151 may be installed on both sides of the air chamber 131. The water chamber 151 is filled with water.

The water chamber heater 152 is installed to allow heat exchange with the water chamber 151. The water chamber heater 152 heats the water filled in the water chamber 151. The inside of the reaction tank 110 is maintained at an appropriate temperature by the heated water chamber 151.

The water chamber temperature sensor 153 is installed in the water chamber 151 or the internal structure of the water chamber 151. The water chamber temperature sensor 153 may be installed on the inner surface of the water chamber 151 or may be installed on the water chamber heater 152. The water chamber temperature sensor 153 detects the temperature in the water chamber 151. In this way, based on the temperature data in the water chamber 151 sensed by the water chamber temperature sensor 153, the control unit 170, which will be described later, keeps the temperature in the water chamber 151 appropriate.

The stirring blade driving unit 160 drives the stirring blade 120. The stirring blade driving unit 160 allows the stirring blade 120 to be driven. The stirring blade driving unit 160 includes a hydraulic motor 161, a hydraulic supply pipe 162, a hydraulic supply unit 163, a directional control valve 164, and a pressure adjustment valve 165.

The hydraulic motor 161 is connected to the stirring blade 120. In addition, the hydraulic motor 161 is connected to the reducer (R), the reducer (R) may be connected to the stirring blade (120). The hydraulic motor 161 provides a driving force to the stirring blade 120. The hydraulic motor 161 rotates the stirring blade 120 by receiving hydraulic pressure.

One end of the hydraulic supply pipe 162 is connected to the hydraulic motor 161. Hereinafter, a direction connected to the hydraulic motor 161 in the hydraulic supply pipe 162 is referred to as a downstream side, and the opposite direction is referred to as an upstream side.

The hydraulic supply unit 163 is located in the hydraulic supply pipe 162 to supply oil. The hydraulic supply unit 163 is located on the upstream side of the hydraulic supply pipe 162.

The directional control valve 164 is located in the hydraulic supply pipe 162 so that the direction of the oil supplied through the hydraulic supply unit 163 is supplied in the forward or reverse direction. Accordingly, the stirring blade 120 rotates forward or reverse. The directional control valve 164 may be located on the downstream side of the hydraulic supply unit 163.

The pressure adjustment valve 165 is located in the hydraulic supply pipe 162. The pressure control valve 165 may be located between the hydraulic supply unit 163 and the directional control valve 164. The pressure adjustment valve 165 may control the load of the hydraulic motor 161 driving the stirring blade 120 with pressure. The pressure adjustment valve 165 adjusts the pressure of the oil to be within a set range. The pressure control valve 165 may be additionally provided with a pressure switch 166 and a pressure gauge 167. The hydraulic motor 161 is located at one end of the hydraulic supply pipe 162 and is located adjacent to the stirring blade 120. When the pressure switch 166 reaches the set pressure, it is determined that the stirring blade 120 is in an overload state. Accordingly, it is possible to notify that the stirring blade 120 is in an overload state through a warning light (not shown). In addition, the pressure gauge 167 may display the current pressure state of the supplied oil.

5 is a block diagram functionally showing a configuration related to operation control of an organic waste treatment apparatus according to an embodiment of the present invention.

Referring to FIG. 5, the controller 170 controls components of the organic waste treatment apparatus 10.

The controller 170 receives temperature information inside the air chamber 131 and temperature information inside the water chamber 151 from the air chamber temperature sensor 135 and the water chamber temperature sensor 135. When a set temperature is reached based on a signal from such a sensor, the operation of the air chamber heater 134 and the water chamber heater 152 is controlled to be stopped. In addition, the control unit 170 receives pressure information of the oil supplied from the stirring blade driving unit 160 from the pressure adjusting valve 165.

The control unit 170 may be provided to receive a signal from the user input unit I. The user input unit I allows the user to set the set temperatures of the air chamber 131 and the water chamber 151. In addition, the user input unit (I) is capable of setting a set amount of oil supplied to the stirring blade driving unit 160 by the user. In this way, when an operation command is input through the user input unit I, the control unit 170 controls the driving of the stirring blade 120 through the stirring blade driving unit 160.

6 is a view showing an organic waste treatment apparatus according to another embodiment.

6, the organic waste treatment apparatus 10a according to another embodiment is an embodiment in which the air circulation unit 140 is modified. In this embodiment, the discharge part blower 142 is located adjacent to the air discharge part 110b on the upstream side of the air discharge pipe 141. And, the condenser 143 is located on the downstream side of the discharge blower 142. In addition, a water separator 144 is located on the downstream side of the condenser 143.

Configurations other than the air circulation unit 140 are the same as or similar to the organic waste treatment apparatus 10 of FIG. 1, so a repeated description will be omitted.

7 is a view showing an organic waste treatment apparatus according to another embodiment.

Referring to FIG. 7, the organic waste treatment apparatus 10b according to another embodiment is an embodiment in which the air circulation unit 140 is modified. In this embodiment, the condenser 143 is omitted. In addition, the water separator 144 is positioned adjacent to the air discharge part 110b on the upstream side of the air discharge pipe 141. In addition, the discharge blower 142 is located in a separate pipe connected from the water separator 144. A separate supply control valve is installed in the separate pipe.

Configurations other than the air circulation unit 140 are the same as or similar to the organic waste treatment apparatus 10 of FIG. 1, so a repeated description will be omitted.

The detailed description above is illustrative of the present invention. In addition, the above description is to illustrate a preferred embodiment of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, changes or modifications may be made within the scope of the concept of the invention disclosed in the present specification, the scope equivalent to the disclosed contents, and/or within the scope of technology or knowledge in the art. The above-described embodiments describe the best state for implementing the technical idea of the present invention, and various changes required in specific application fields and uses of the present invention are possible. Therefore, the detailed description of the invention is not intended to limit the invention to the disclosed embodiment. In addition, the appended claims should be construed as including other embodiments.

10, 10a, 10b: organic waste treatment device
110: reaction tank 100a: air inlet
110b: air outlet 111: temperature sensor
112: moisture sensor 120: stirring blade
130: air injection unit 131: air chamber
132: air injection nozzle 133: check valve
134: air chamber heater 135: air chamber temperature sensor
140: air circulation unit 141: air discharge pipe
142: discharge bubble blower 142a: second discharge bubble
143: condenser 144: water separator
145: injection blower 146: deodorization unit
150: reaction tank heating unit 151: water chamber
152: water chamber heater 153: water chamber temperature sensor
160: stirring blade drive unit 161: hydraulic motor
162: hydraulic supply pipe 163: hydraulic supply unit
164: directional control valve 165: pressure control valve
166: pressure switch 167: pressure gauge
170: control unit I: user input unit
R: reducer

Claims (5)

A reaction tank having an air inlet portion and an air outlet portion formed therein, and a container for treating by reacting with aerobic or hydrophilic microorganisms while containing organic waste therein;
A stirring blade installed inside the reaction tank;
An air injection unit coupled to one surface of the reaction tank to inject air heated to a set temperature into the reaction tank;
An air circulation unit connected to the air discharge unit so that the air discharged from the reaction tank is connected to the air injection unit and supplied back to the reaction tank;
A reaction tank heating unit formed on the outer surface of the reaction tank so that the reaction tank maintains an appropriate temperature;
A stirring blade driving unit connected to the stirring blade to drive the stirring blade; And
Organic waste treatment apparatus including a control unit.
The method of claim 1,
The air injection unit
An air chamber coupled to one surface adjacent to the stirring blade in the reaction tank;
An air injection nozzle connected to the air chamber;
A check valve installed on a flow path connecting the air chamber and the air injection nozzle;
An air chamber heater coupled to expose a heating wire to the inner space of the air chamber; And
An organic waste treatment apparatus comprising an air chamber temperature sensor installed in the air chamber or the air chamber heater.
The method of claim 1,
The air circulation unit
An air discharge pipe having one end connected to the air discharge part and the other end connected to the air chamber;
An injection blower which is located in the air discharge pipe and sucks the air inside the reaction tank;
A condenser located in the air discharge pipe, located between the air discharge part and the discharge part blower, or located at a downstream side of the discharge part blower;
A moisture separator located on the air discharge pipe and located on the downstream side of the condenser;
An injection blower positioned on the air discharge pipe and installed on a downstream side connected to the air chamber; And
An organic waste treatment apparatus comprising a deodorizing unit positioned on the air discharge pipe and positioned upstream of the injection blower.
The method of claim 1,
The reaction tank heating unit
A water chamber installed on the outer bottom of the reaction tank;
A water chamber heater installed on the bottom of the wheater chamber; And
Organic waste treatment apparatus comprising a water chamber temperature sensor installed in the water chamber or the water chamber heater.
The method of claim 1,
The stirring blade driving part
A hydraulic motor connected to the stirring blade to provide a driving force to the stirring blade;
A hydraulic supply pipe having one end coupled to the hydraulic motor to supply hydraulic pressure to the hydraulic motor;
A hydraulic supply unit installed in the hydraulic supply pipe to supply oil; And
An organic waste treatment apparatus comprising a supply control valve installed in the hydraulic supply pipe to supply the supplied oil in a forward or reverse direction.

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