KR102194977B1 - Food garbage treatment apparatus - Google Patents

Abstract

The present invention. A first treatment unit including a first fermentation tank containing a fermentation agent and an input unit and a first discharge unit communicating with the first fermentation tank; A second processing unit communicating with the first discharging unit and including a second fermenting tank containing a fermenting agent and a second discharging unit communicating with the second fermenting tank; A third processing unit in communication with the second discharge unit and including a heater; A cooling unit for cooling the gas supplied from the second processing unit and a deodorizing unit for deodorizing the gas cooled in the cooling unit, and the first processing unit includes a bottom surface of the first fermentation tank A first transfer conveyor disposed in the vicinity to the vicinity of the first discharge part, and a first stirring part disposed adjacent to the first transfer conveyor,
The second processing unit includes a second transfer conveyor disposed near the bottom surface of the second fermentation tank to the vicinity of the second discharge unit, and a second stirring unit disposed adjacent to the second transfer conveyor, and the first stirring The unit may be connected to the first conveying conveyor to interlock with the first conveying conveyor, and the second stirring part may be connected to the second conveying conveyor to provide a food waste disposal apparatus that interlocks with the second conveying conveyor.

Description

Food garbage treatment apparatus

The embodiment relates to a food waste disposal apparatus.

In general, food waste discharged from homes or restaurants is collected in a separate public collection box to remove moisture and landfilled, or separately processed and used as feed or compost for livestock.

Most of these food wastes are collected while wet. Therefore, it is true that food waste has a high moisture content and a large volume. As described above, if the garbage is high in moisture, it can be easily decayed, and if the volume is large, the weight increases, so there is a problem in handling and handling in transportation and processing.

On the other hand, food waste is most desirable to minimize the amount of food consumed and left, so the ordered diet system is widely implemented as a social enlightenment as part of an effort to reduce the amount of food left behind, but its effectiveness is very poor. to be.

Therefore, it is desirable to actively reduce food waste in the waste generation area, and a food waste disposal apparatus was developed for this purpose.

Conventional food waste disposal apparatuses allow not only to reduce the weight by drying wet food waste by heating, but also to reduce the volume by crushing finely.

However, most of the conventional food waste disposal devices are structurally complex with numerous devices for implementing a number of processes in order to crush and heat food waste to remove moisture and then send the treated waste to a separate collection box, resulting in high manufacturing cost and frequent use. It is an obstacle to commercialization due to failure.

In addition, conventionally, most food waste treatment devices installed in kitchens have a problem in that they cannot completely remove odors generated during food waste treatment. In other words, since odors generated during food waste treatment are often leaked to the outside and pollute the indoor air, not only causes discomfort to users, but also exposes to various sources of pollution for hygiene.

A registered patent filed by the present applicant to solve such problems

Publication No. 10-1306679, "Food Waste Disposal Device", simplifies the structure of the food waste treatment device and includes a condenser that circulates a refrigerant to the cooling coil to remove moisture from the exhaust from the food waste, thereby disposing of conventional food waste. Compared to the device, the manufacturing cost can be significantly reduced, while the product defect rate can be lowered, and the odor generated in the food waste treatment process can be effectively removed.

However, in order to implement a cooling method that uses a cooling coil and a condenser to circulate the refrigerant in the food waste disposal device, there is a problem that maintenance cost increases because the refrigerant is periodically replenished. In addition, the cooling coil and the refrigerant are circulated. Because it requires a condenser to be used, the cost to purchase it is high, which causes the manufacturing cost to rise, and there is a problem in that installation is difficult because there is a risk of leakage of refrigerant when the cooling coil is damaged and a complicated configuration during installation.

Meanwhile, since most conventional food waste disposal apparatuses are fixedly installed in certain places in the kitchen, there is a large problem of space limitations that cannot be used in a kitchen in a narrow space where it is difficult to install the food waste disposal apparatus.

Therefore, when food waste is generated, it is possible to quickly and easily dispose of food waste, while reducing manufacturing cost and maintenance cost, and a practical and applicable technology for a food waste disposal device capable of implementing a minimal space design with a simple configuration. This is an urgent need.

Korean Patent Registration No. 10-0890206 (announced on April 3, 2009)

An object of the present invention is to provide a food waste disposal apparatus for drying and pulverizing while decomposing organic substances of food waste.

In addition, an object of the present invention is to provide a food waste treatment apparatus capable of effectively performing fermentation and drying of food waste.

In addition, an object of the present invention is to provide a food waste disposal apparatus capable of effectively removing gases generated during fermentation and drying of food waste.

The problem to be solved by the present invention is not limited to the problems mentioned above, and other problems that are not mentioned herein will be clearly understood by those skilled in the art from the following description.

In an embodiment, a first fermentation tank containing a fermenter, a first processing unit including an input unit and a first discharge unit in communication with the first fermentation tank, a second fermentation tank in communication with the first discharge unit and containing a fermentation agent, and the A second processing unit including a second discharge unit in communication with a second fermentation tank, a third processing unit in communication with the second discharge unit and including a heater, and a gas supplied from the second processing unit in communication with the second fermentation tank And a cooling unit for cooling the cooling unit and a deodorizing unit for deodorizing the gas cooled in the cooling unit, and the first processing unit includes a first transfer conveyor disposed near the bottom surface of the first fermentation tank to the vicinity of the first discharge unit , A first stirring unit disposed adjacent to the first transfer conveyor, and the second processing unit includes a second transfer conveyor disposed from the vicinity of the bottom surface of the second fermentation tank to the vicinity of the second discharge unit, and the second And a second stirring unit disposed adjacent to the transfer conveyor, and the first stirring unit is connected to the first transfer conveyor and interlocked with the first transfer conveyor, and the second stirring unit is connected to the second transfer conveyor. It is possible to provide a food waste disposal apparatus linked to the second transfer conveyor.

Preferably, the cooling unit includes a housing and a heat exchange unit including an isolated first space unit and a second space unit, the heat exchange unit is disposed in the first space unit, and an inlet of the first space unit is the second processing unit And, the outlet of the first space part is connected to an inlet of the deodorization part, and the inlet of the second space part may be connected to an outlet of the deodorization part.

Preferably, the housing includes a first outlet and a second outlet and a partition wall disposed in the second space, the first outlet is disposed above the second outlet, and the partition wall is based on a vertical direction. As such, it may be disposed between the first outlet and the second outlet, disposed to be inclined downward, and disposed below the inlet of the second space.

Preferably, it is disposed between the second processing unit and the inlet of the second space, and includes an exhaust housing including a first flow path, a second flow path, and a third flow path inside, and the exhaust housing includes the first flow path And an inlet connected to the second processing part, an outlet connected to the second flow path and the second space part, and an exhaust port connected to the third flow path and the outside, wherein the first flow path and the second flow path Is partitioned, the third flow path connects the first flow path and the second flow path, and the third flow path may be disposed below the first flow path and the second flow path.

Preferably, the third processing unit includes a third discharge unit and a discharge door for selectively opening and closing the third discharge unit, and the discharge door includes a discharge plate including a curved surface and a driving unit for rotating the discharge plate. , The third processing unit may further include a heater block and a fan heater, and food waste flowing into the third processing unit may be heated by the heater block and the fan heater.

Preferably, the first stirring unit and the second stirring unit each include a shaft and a blade coupled to the shaft, wherein the blade is disposed perpendicular to the first unit blade coupled to the shaft and the first unit blade It may include a second unit blade.

Preferably, a plurality of blades are disposed at intervals along the longitudinal direction of the shaft, and the plurality of blades may be disposed to be twisted from each other based on the rotation direction of the shaft.

Preferably, the first processing unit may further include a motor and a chain connecting the motor, the first transfer conveyor, and the first stirring unit.

Preferably, the second processing unit may further include a motor and a chain connecting the motor, the second transfer conveyor, and the second stirring unit.

Preferably, the first outlet may communicate with the third processing unit.

Preferably, the exhaust housing may further include a stopper blocking the exhaust port.

According to the embodiment, the organic material of the food waste is decomposed through three steps, while the food waste is dried and pulverized at the same time, thereby providing an advantageous effect of effectively removing the food waste.

According to the embodiment, a transport conveyor for transporting food waste is configured to be interlocked with a stirrer and used to stir the food waste and the fermenting agent, thereby providing an advantageous effect of decomposing and drying the food waste more effectively.

According to the embodiment, an advantageous effect of effectively removing foreign substances from exhaust gas of the second processing unit through the exhaust housing is provided.

According to the embodiment, the deodorized exhaust gas is configured to flow into the housing of the cooling unit, thereby providing an advantageous effect of effectively discharging the exhaust gas.

According to the embodiment, it provides an advantageous effect of removing foreign substances from deodorized exhaust gas.

1 is a view showing a food waste disposal apparatus according to an embodiment;
2 is a cross-sectional view of the food waste disposal apparatus shown in FIG. 1;
3 is a plan view showing the interior of the food waste treatment apparatus shown in FIG. 1;
4 is a view showing a first key portion, a second processing portion, and a third processing portion shown in FIG. 2;
5 is a view showing a first processing unit;
6 is a view showing a first stirring unit,
7 is a view showing the scraper shown in FIG. 5;
8 is a view showing a connection state of the first conveying conveyor and the first stirring unit,
9 is a perspective view of a first processing unit,
10 is a view showing an operating state of the first transfer conveyor and the first stirring unit,
11 is a view showing a second processing unit;
12 is a view showing a connection state of a second transfer conveyor and a second stirring unit;
13 is a perspective view of a first processing unit,
14 is a view showing an operating state of the second transfer conveyor and the second stirring unit;
15 is a view showing a third processing unit;
16 is a perspective view of a food waste device showing a path of exhaust gas;
17 is a perspective view of an exhaust housing,
18 is a view showing a connection state of an exhaust housing and a cooling unit;
19 is a view showing a connection state of the cooling unit and the deodorizing unit,
20 is a view showing a cooling unit.

Objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments in conjunction with the accompanying drawings. In addition, terms or words used in this specification and claims should not be construed as being limited to a conventional or dictionary meaning, and the inventor appropriately defines the concept of terms in order to describe his own invention in the best way. Based on the principle that it is possible, it should be interpreted as a meaning and concept consistent with the technical idea of the present invention. In addition, in describing the present invention, detailed descriptions of related known technologies that may unnecessarily obscure the subject matter of the present invention will be omitted.

1 is a view showing a food waste disposal apparatus according to an embodiment, FIG. 2 is a cross-sectional view of the food waste disposal apparatus shown in FIG. 1, and FIG. 3 is a view showing the interior of the food waste disposal apparatus shown in FIG. It is a plan view, and FIG. 4 is a diagram illustrating a first key portion, a second processing portion, and a third processing portion shown in FIG. 2, and FIG. 5 is a diagram illustrating a first processing portion.

1 to 5, the food waste disposal apparatus according to the embodiment includes a first processing unit 100, a second processing unit 200, a third processing unit 300, a cooling unit 400, and It may include a deodorizing unit 500 and a control unit 600. In the drawings below, the x-axis direction is the length direction of the food waste disposal apparatus, the y-axis direction is the width direction of the food waste disposal apparatus, and the z-axis direction is the height direction of the food waste disposal apparatus.

Food waste is put into the input unit 10. The food waste put into the input unit 10 is disassembled, dried, pulverized and discharged through the first processing unit 100, the second processing unit 200, and the third processing unit 300.

The first processing unit 100 decomposes and pulverizes organic substances in food waste. The first processing unit 100 may include a first fermentation tank 110, a first stirring unit 120, a first transfer conveyor 130, a motor 140, and a first discharge unit 150.

Fermentation agent (F) is accommodated in the first fermentation tank 110, the fermentation agent (F) may be aerobic microorganisms and culture broth. In addition, the food waste input through the input unit 10 is accommodated in the first fermentation tank 110. The first fermentation tank 110 may have a shape of Sanggwanghahyeop. The first discharge unit 150 may be discharged at the upper end of the first fermentation tank 110. The first fermentation tank 110 may include an inclined surface extending from the first discharge unit 150 to the bottom surface.

The first stirring unit 120 is disposed under the first fermentation tank 110. And the first stirring unit 120 is disposed adjacent to the first transfer conveyor (130). This is to perform a stirring operation of the food waste and the fermenter F by using the flow of food waste caused by the movement of the first transfer conveyor 130.

6 is a view showing the first stirring unit 120.

5 and 6, the first stirring unit 120 may include a shaft 131 and blades 122A, 122B, and 122C. The blades 122A, 122B, and 122C may include a first unit blade 121_1 and a second unit blade 121_2.

The first unit blade 121_1 is disposed on the shaft 131. The second unit blade 121_2 is disposed at the end of the first unit blade 121_1. At this time. The second unit blade 121_2 is disposed perpendicular to the first unit blade 121_1.

The shaft 131 is rotatably disposed on the outer structure of the first processing unit 100. The shaft 131 may be disposed such that the length direction of the shaft 131 is the width direction of the food waste disposal apparatus.

The first transfer conveyor 130 is disposed from the first discharge unit 150 to the vicinity of the bottom surface of the first fermentation tank 110. The first transfer conveyor 130 serves to mix the food waste and the fermentation agent (F), or to transfer the food waste to the first discharge unit 150.

The first transfer conveyor 130 may include a shaft 131, a sprocket 132, and a chain 133. The shaft 131 is rotatably disposed on the outer structure of the first processing unit 100. The shaft 131 may be disposed such that the longitudinal direction of the shaft 131 is the width direction of the food waste treatment apparatus. The sprocket 132 is disposed at the end of the shaft 131. The chain 133 is coupled to the sprocket 132.

7 is a view showing the scraper shown in FIG. 5.

5 and 7, the scraper 160 is disposed on the chain 133. The scraper 160 serves to sweep or sweep away food waste. The scraper 160 may be disposed such that the length direction of the scraper 160 is the width direction of the food waste treatment apparatus.

The scraper 160 may include a first part 161 and a second part 162. The first part 161 is coupled to the chain 133, and the second part 162 may be disposed in a curved shape in the first part 161. A plurality of scrapers 160 may be disposed on the chain 133. In this case, the scraper 160 may be arranged by mixing a first scraper 160A on which the second part 162 is disposed on the lower side and a second scraper 160B on which the second part 162 is disposed on the upper side.

FIG. 8 is a diagram illustrating a connection state of the first transfer conveyor 130 and the first stirring unit 120, and FIG. 9 is a perspective view of the first processing unit 100.

5, 8, and 9, when the first conveying conveyor 130 is moved by the rotation of the motor 140, the first stirring unit 120 is moved in connection therewith. The first sprocket 170 is disposed at the end of the shaft 121 of the first stirring unit 120. In addition, the second sprocket 180 is also disposed at the end of the shaft 131 of the first transfer conveyor 130. The chain 190 is connected to the first sprocket 170 and the second sprocket 180 and is connected to the motor 140. The chain 190 may be arranged to have a triangular shape. When the motor 140 rotates, the chain 190 moves, and the first transfer conveyor 130 and the first stirring unit 120 rotate at the same time.

10 is a view showing an operating state of the first transfer conveyor 130 and the first stirring unit 120.

3, 5, and 10, by rotation of the motor 140, the first transfer conveyor 130 may be moved in a forward direction or in a reverse direction. It may rotate in a forward direction or in a reverse direction in conjunction with the movement of the first transfer conveyor 130. The controller 600 may control the rotation of the motor 140 to select and perform a stirring operation and a transfer operation of food waste.

The stirring operation may be performed in a form of repeating movement of the first transfer conveyor 130 and the first stirring unit 120 from the forward direction to the reverse direction and from the reverse direction to the forward direction in a short cycle. The first stirring unit 120 is disposed adjacent to the lower end of the first conveying conveyor 130 to effectively perform a stirring operation in the space between the first stirring unit 120 and the first conveying conveyor 130.

The first scraper (160A) and the second scraper (160B) having different directionality, in the process of repeating the movement of the first transfer conveyor 130 from the forward direction to the reverse direction and from the reverse direction to the forward direction, the food waste and fermenter (F) It has the advantage of inducing it to mix well.

The transfer operation may be performed in a form of continuously moving the first transfer conveyor 130 and the first stirring unit 120 in a forward or reverse direction for a predetermined time.

The food waste is transported by the first transport conveyor 130 and supplied to the first discharge unit 150. The supplied food waste is discharged to the first discharge unit 150 and supplied to the second processing unit 200. The cutter 151 may be disposed near the top of the first transfer conveyor 130. The food waste transferred to the vicinity of the upper end of the first transfer conveyor 130 may be cut and supplied to the second processing unit 200.

11 is a diagram illustrating the second processing unit 200.

Referring to FIG. 11, the second processing unit 200 decomposes and pulverizes the organic material of the food waste supplied from the first processing unit 100 again. The second processing unit 200 may include a second fermentation tank 210, a second stirring unit 220, a second transfer conveyor 230, a motor 240, and a second discharge unit 250.

A fermenting agent (F) is accommodated in the second fermentation tank 210, and the fermenting agent (F) may be an aerobic microorganism and a culture solution. In addition, food waste inputted through the first discharge unit 150 of the first processing unit 100 is accommodated in the second fermentation tank 210. The second fermentation tank 210 may have a shape of Sanggwanghahyeop. The second discharge unit 250 may be discharged at the upper end of the second fermentation tank 210. The second fermentation tank 210 may include an inclined surface extending from the second discharge unit 250 to the bottom surface. A heating block 201 may be disposed on the inclined surface. The heating block 201 heats the mixture of the food waste and the fermenting agent (F) transferred by the second transfer conveyor 230. This is due to the endothermic heat of the food waste, the temperature may be lowered, to maintain the active temperature of the aerobic microorganisms through heating.

The second stirring unit 220 is disposed under the second fermentation tank 210. In addition, the second stirring unit 220 is disposed adjacent to the second transfer conveyor 230. This is to perform a stirring operation of the food waste and the fermenting agent F by using the flow of food waste caused by the movement of the second transfer conveyor 230. The second stirring unit 220 may include a driving stirrer 220A and a driven stirrer 220B, and a chain 133 connecting the driving stirrer 220A and the driven stirrer 220B. The driving stirrer 220A is connected to the motor 140. The shape and function of the driving stirrer 220A and the driven stirrer 220B may be the same as those of the first stirrer 120.

The second transfer conveyor 230 is disposed from the second discharge unit 250 to the vicinity of the bottom surface of the second fermentation tank 210. The second conveying conveyor 230 serves to mix the food waste and the fermentation agent (F), or to transfer the food waste to the second discharge unit 250.

The second transfer conveyor 230 may include a shaft 221, a sprocket 232, and a chain 233. The shaft 221 is rotatably disposed on the outer structure of the second processing unit 200. The shaft 221 may be disposed such that the longitudinal direction of the shaft 221 is the width direction of the food waste disposal apparatus. The sprocket 232 is disposed at the end of the shaft 221. The chain 233 is coupled to the sprocket 232.

A plurality of scrapers 260 may be disposed on the chain 233. In the scraper 260, a first scraper 260A and a second scraper 260B having different directions may be mixed.

12 is a diagram illustrating a connection state of the second transfer conveyor 230 and the second stirring unit 220, and FIG. 13 is a perspective view of the first processing unit 100.

11 to 13, when the second conveying conveyor 230 is moved by the rotation of the motor 240, the second stirring unit 220 is moved in connection therewith. A third sprocket 270 is disposed in the driving stirrer 220A of the second stirring unit 220. In addition, the fourth sprocket 280 is also disposed at the end of the shaft 231 of the second transfer conveyor 230. The chain 290 is connected to the third sprocket 270 and the fourth sprocket 280 and is connected to the motor 240. The chain 280 may be arranged to have a triangular shape. When the motor 240 rotates, the chain 290 moves, and the second conveying conveyor 230 and the second stirring part 220 rotate at the same time.

14 is a view showing an operating state of the second transfer conveyor 230 and the second stirring unit 220.

11 to 14, by rotation of the motor 140, the second transfer conveyor 230 may be moved in a forward direction or in a reverse direction. In conjunction with the movement of the second transfer conveyor 230, it may rotate in a forward direction or in a reverse direction. The controller 600 may control the rotation of the motor 240 to select and perform a stirring operation and a transfer operation of food waste.

The stirring operation may be performed in a form of repeating movement of the second transfer conveyor 230 and the second stirring unit 220 from the forward direction to the reverse direction and from the reverse direction to the forward direction in a short cycle. The second stirring unit 220 is disposed adjacent to the lower end of the second conveying conveyor 230 to effectively perform a stirring operation in the space between the second stirring unit 220 and the second conveying conveyor 230.

The first scraper (260A) and the second scraper (260B) having different directions, in the process of repeating the movement of the second transfer conveyor 230 from the forward direction to the reverse direction and from the reverse direction to the forward direction, the food waste and fermentation agent (F) It has the advantage of inducing it to mix well.

The transfer operation may be performed in a form of continuously moving the second transfer conveyor 230 and the second stirring unit 220 in a forward or reverse direction for a predetermined time.

The food waste is conveyed by the second conveying conveyor 230 and supplied to the second discharge unit 250. The supplied food waste is discharged to the second discharge unit 250 and supplied to the third processing unit 300. The cutter 251 may be disposed near the upper end of the second transfer conveyor 230. The food waste transferred to the vicinity of the upper end of the second transfer conveyor 230 may be cut and supplied to the third processing unit 300.

3 and 4, the third processing unit 300 may include a fan heater 310, a heater block 311, and a third stirring unit 320. The third stirring unit 320 may have the same function and shape as the second stirring unit 220. The fan heater 310 indirectly heats the food waste supplied to the third processing unit 300. The heater block 311 directly heats the food waste supplied to the third processing unit 300 to dry it. The food waste supplied to the third processing unit 300 may be heated in combination by the fan heater 310 and the heater block 311.

15 is a diagram illustrating the third processing unit 300.

Referring to FIG. 15, the third processing unit 300 includes a discharge door that selectively opens and closes the third discharge unit and the third discharge unit, and the discharge door includes a discharge plate including a curved surface and a driving unit for rotating the discharge plate. can do. The curved discharge plate may rotate to push the food waste that has passed through the third discharge unit to the outside. The rotating shaft of the discharge plate may be arranged such that its longitudinal direction is the width direction of the food waste disposal apparatus. Food waste discharged to the third discharging unit can be put in a collection bag.

16 is a perspective view of a food waste apparatus showing a path of exhaust gas.

Referring to FIG. 16, the exhaust housing 700 is connected to the second processing unit 200. And the exhaust housing 700 is connected to the cooling unit 400. The cooling unit 400 is connected to the deodorizing unit 500. The exhaust gas G generated from the second processing unit 200 is supplied to the cooling unit 400 through the exhaust housing 700. The exhaust gas supplied to the cooling unit 400 is cooled and supplied to the deodorizing unit 500. The exhaust gas deodorized by the deodorizing unit 500 may be supplied to the cooling unit 400 and discharged to the outside.

17 is a perspective view of the exhaust housing 700. 18 is a diagram illustrating a connection state between the exhaust housing 700 and the cooling unit 400.

16 to 18, the exhaust housing 700 may include a first flow path 710, a second flow path 720, and a third flow path 730. Further, the exhaust housing 700 may include an inlet 740, an outlet 750, and an exhaust port 760. The inlet 740 is disposed in the first flow path 710 and is connected to the second processing unit 200. The outlet 750 is disposed in the third flow path 730 and is connected to the second space S20 of the housing 410 of the cooling unit 400. The exhaust port 760 is disposed in the second flow path 720 to communicate with the outside. The second flow path 720 is disposed below the first flow path 710 and the third flow path 730. The exhaust housing 700 includes a partition wall 701. The partition wall 701 partitions the first flow path 710 and the third flow path 730. The exhaust housing 700 may further include a stopper 761 blocking the exhaust port 760. The stopper 761 is disposed to be detachably attached to the exhaust housing 700. When foreign matter accumulates on the bottom of the exhaust housing 700, the stopper 761 may be opened to remove the foreign matter inside the exhaust housing 700.

By a suction device such as a suction fan, the exhaust gas of the second processing unit 200 is sucked into the first flow path 710 through the inlet 740. The exhaust gas sucked into the first flow path 710 passes through the second flow path 720 and the third flow path 730. In this case, foreign substances in the exhaust gas may be discharged through the exhaust port 760. The exhaust gas passing through the third flow path 730 is transmitted to the first space S10 through the connection pipe P.

19 and a diagram showing a connection state between the cooling unit 400 and the deodorizing unit 500, and FIG. 20 is a view showing the cooling unit 400.

18 to 20, the cooling unit 400 may include a housing 410 and a heat exchange unit 420. The housing 410 includes an isolated first space part S10 and a second space part S20.

The heat exchange part 420 is disposed in the first space part S10. The inlet 740 of the first space S10 communicates with the exhaust housing 700. The outlet of the first space part S10 is connected to the inlet of the deodorization part 500. The second space S20 is empty inside.

The housing 410 may include a partition wall 430. The partition wall 430 is disposed in the second space S20. The partition wall 430 divides the second space S10 into an upper space S21 and a lower space S22 through which a narrow area communicates. The partition wall 430 may be disposed to be inclined downward.

The housing 410 may include a first outlet 411 and a second outlet 412. The first outlet 411 is disposed above the second outlet 412. The partition wall 430 is disposed between the first outlet 411 and the second outlet 412 based on the vertical direction. The first outlet 411 may communicate with the third processing unit 300.

The inlet of the second space part S20 communicates with the outlet of the deodorization part 500. The entrance of the second space part S20 is disposed above the partition wall 430.

In the exhaust housing 700, as shown in G1 of FIG. 20, the exhaust gas flowing into the first space S10 of the cooling unit 400 is cooled in the heat exchange unit 420. The condensate generated during the cooling process can be discharged to the outside. The cooled exhaust gas is supplied to the deodorization unit 500. The odor of the exhaust gas is adsorbed and removed by a multi-stage filter included in the deodorization unit 500. The deodorized exhaust gas is supplied to the second space unit S20 through the cooling unit 420. The exhaust gas supplied to the second space unit S20 is sucked and circulated to the third processing unit 300 through the first outlet 411 of the upper space S21 as shown in G2 of FIG. 20 based on the partition wall 430 do. The exhaust gas discharged through the first outlet 411 is sucked into the third processing unit 300 through the waste heat recovery pipe 301 as shown in P of FIG. 16. By recycling the heat of the exhaust gas discharged to the first outlet 411 in the third processing unit 300, there is an advantage of saving energy.

Further, based on the partition wall 430, as shown in G3 of FIG. 20, some of the exhaust gas is exhausted to the outside through the second outlet 412.

As described above, with reference to the accompanying drawings with respect to the food waste disposal apparatus according to one preferred embodiment of the present invention was looked at in detail.

It is to be understood that the above-described embodiment of the present invention is illustrative and non-limiting in all respects, and the scope of the present invention will be indicated by the claims to be described later rather than the detailed description described above. And it should be construed that the meaning and scope of the claims, as well as all changes or deformable forms derived from the equivalent concept, are included in the scope of the present invention.

100: first processing unit 110: first fermentation tank 120: first stirring unit
130: first transfer conveyor 200: second processing unit 201: heating block
210: second fermentation tank 220: second transfer conveyor 230: second stirring unit
300: third processing unit 310: fan heater 311: heater block
400: cooling unit 500: deodorization unit

Claims (11)

A first treatment unit including a first fermentation tank containing a fermentation agent and an input unit and a first discharge unit communicating with the first fermentation tank;
A second processing unit communicating with the first discharging unit and including a second fermenting tank containing a fermenting agent and a second discharging unit communicating with the second fermenting tank;
A third processing unit in communication with the second discharge unit and including a heater;
A cooling unit communicating with the second fermentation tank to cool the gas supplied from the second processing unit; and
It includes a deodorizing unit for deodorizing the gas cooled in the cooling unit,
The first processing unit includes a first transfer conveyor disposed near the bottom surface of the first fermentation tank to the vicinity of the first discharge unit, and a first stirring unit disposed adjacent to the first transfer conveyor,
The second processing unit includes a second transfer conveyor disposed near the bottom surface of the second fermentation tank to the vicinity of the second discharge unit, and a second stirring unit disposed adjacent to the second transfer conveyor,
The first stirring unit is connected to the first conveying conveyor and interlocked with the first conveying conveyor,
The second stirring unit is connected to the second conveying conveyor and interlocked with the second conveying conveyor,
The cooling part includes a housing including an isolated first space part and a second space part and a heat exchange part,
The heat exchange part is disposed in the first space,
The inlet of the first space part is connected to the second processing part,
The outlet of the first space part is connected to the inlet of the deodorization part,
The inlet of the second space part is connected to the outlet of the deodorization part,
The housing includes a first outlet and a second outlet and a partition wall disposed in the second space,
The first outlet is disposed above the second outlet,
The partition wall is disposed between the first outlet and the second outlet based on an up-down direction, is disposed to be inclined downward, and disposed below the entrance of the second space. delete delete The method of claim 1,
An exhaust housing disposed between the second processing unit and the inlet of the second space unit and including a first flow path, a second flow path, and a third flow path inside,
The exhaust housing,
And an inlet connected to the first flow path and the second processing unit, an outlet connected to the second flow path and the second space, and an exhaust port connected to the third flow path and the outside,
The first flow path and the third flow path are partitioned, and the second flow path connects the first flow path and the third flow path,
The second flow path is a food waste disposal apparatus disposed below the first flow path and the third flow path. The method of claim 4,
The third processing unit includes a third discharge unit and a discharge door selectively opening and closing the third discharge unit,
The discharge door includes a discharge plate including a curved surface and a driving part for rotating the discharge plate,
The third processing unit further includes a heater block and a fan heater,
The food waste treatment apparatus in which the food waste flowing into the third treatment unit is heated by the heater block and the fan heater. The method of claim 5
Each of the first stirring unit and the second stirring unit includes a shaft and a blade coupled to the shaft,
The blade is a food waste disposal apparatus comprising a first unit blade coupled to the shaft and a second unit blade disposed perpendicular to the first unit blade. The method of claim 6,
A plurality of blades are disposed at intervals along the longitudinal direction of the shaft,
A food waste disposal apparatus in which a plurality of the blades are disposed to be twisted from each other based on the rotation direction of the shaft. The method of claim 7,
The first processing unit further comprises a motor, and a chain connecting the motor, the first transfer conveyor, and the first stirring unit. The method of claim 7,
The second processing unit further comprises a motor, a chain connecting the motor, the second transfer conveyor, and the second stirring unit. The method of claim 1,
The first outlet is a food waste disposal apparatus that communicates with a third processing unit. The method of claim 4,
The exhaust housing further comprises a stopper blocking the exhaust port.

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