CN220216208U - Garbage hydrolyzing device capable of removing solid phase substances - Google Patents

Abstract

The application discloses can remove solid matter's rubbish hydrolysis unit, it can utilize the hydrolysate to hydrolysise organic rubbish, organic rubbish contains can be by the solid matter of hydrolysate hydrolysis and can not be by the solid matter of hydrolysate hydrolysis, can not be by the solid matter of hydrolysate hydrolysis include precipitate and floater, its characterized in that, can remove solid matter's rubbish hydrolysis unit includes a device main part and a edulcoration mechanism, wherein edulcoration mechanism includes a floater removal component, the floater removal component is installed in the device main part, the device main part in hydrolysis chamber top side form with the communication port of hydrolysis chamber intercommunication, take away the floater is moved away via the communication port the hydrolysis chamber removes the floater on thick liquid surface.

Description

Garbage hydrolyzing device capable of removing solid phase substances

Technical Field

The utility model relates to the field of garbage treatment equipment, in particular to a garbage hydrolysis device capable of removing solid-phase substances.

Background

The organic garbage is also called wet garbage, and refers to the waste containing organic components in the household garbage, and mainly comprises paper, fiber, bamboo and wood, kitchen vegetable residues and the like.

At present, after the organic garbage is classified and recycled, a hydrolysis device is needed to hydrolyze and acidify degradable organic matters in the organic garbage into a liquid phase by means of a hydrolysis liquid so as to carry out subsequent fermentation. The existing hydrolysis equipment is usually provided with a filter plate, after the organic garbage is hydrolyzed, slurry obtained by hydrolysis is filtered by the filter plate, wherein solid-phase garbage which is mixed in the slurry and cannot be hydrolyzed by hydrolysis liquid cannot pass through a filter hole to stay in the hydrolysis equipment, the equipment is required to be stopped after the hydrolysis, and the solid-phase garbage which stays in the hydrolysis equipment is required to be manually cleaned, so that the existing hydrolysis equipment is low in hydrolysis efficiency. In addition, the filter holes of the filter plates are easily blocked by solid-phase garbage, and the obtained slurry cannot be filtered, so that the filter plates are required to be cleaned or replaced manually at regular intervals to ensure the filtering effect.

Disclosure of Invention

An advantage of the present utility model is to provide a waste hydrolyzing apparatus that can remove solid phase material that is not hydrolyzable in organic waste.

Another advantage of the present utility model is to provide a waste hydrolyzing apparatus that can remove solid phase material, which can retain a partially hydrolyzed slurry after hydrolysis to provide the desired flora for hydrolysis for the next hydrolysis, saving the use of hydrolysis solution.

To achieve at least one of the above advantages of the present utility model, there is provided a solid phase substance-removable garbage hydrolyzing apparatus capable of hydrolyzing organic garbage containing a solid phase substance hydrolyzable by a hydrolysis liquid and a solid phase substance non-hydrolyzable by a hydrolysis liquid, the solid phase substance non-hydrolyzable by a hydrolysis liquid including a precipitate and a float, with a hydrolysis liquid, the solid phase substance-removable garbage hydrolyzing apparatus comprising:

an apparatus body forming a hydrolysis chamber;

the impurity removing mechanism comprises a floater removing component, the floater removing component is arranged on the equipment main body, a communication port communicated with the hydrolysis chamber is formed on the side surface of the top of the hydrolysis chamber, and the floater is removed from the hydrolysis chamber through the communication port by taking away the floater.

According to an embodiment of the present utility model, the float removing member includes at least one pushing and floating object and a power mechanism, the power mechanism includes a power piece and two sets of transmission components, wherein the two sets of transmission components are disposed opposite to each other, the power piece is mounted on the apparatus main body, each set of transmission components includes a transmission belt and two transmission wheels, any one of the transmission wheels is rotatably connected to the power piece, each set of two transmission wheels is mounted on two ends of the transmission belt, two ends of the pushing and floating object are mounted on the two transmission belts, respectively, the pushing and floating object driven by the power mechanism can move in or out of the liquid level of the liquid in the hydrolysis chamber and move in a horizontal direction, each pushing and floating object includes a pushing portion extending between the two transmission belts, and a part of the pushing portion can move in or out of the liquid level.

According to an embodiment of the present utility model, each of the floating objects further includes a mounting portion, wherein two ends of the mounting portion are respectively connected to two driving belts.

According to an embodiment of the present utility model, the float removing member includes a transfer assembly including a transfer body forming a trash carrying end portion extending into the hydrolysis chamber through the communication port and below a liquid surface and a trash discharging end portion extending out of the hydrolysis chamber through the communication port, the transfer body being movably connected to the power mechanism from the trash carrying end portion toward the trash discharging end portion, the trash discharging end portion being offset from the communication port, the transfer body moving from the trash carrying end portion toward the trash discharging end portion being capable of contacting the float on the liquid surface.

According to an embodiment of the present utility model, the transfer assembly includes a plurality of transfer plates mounted to a surface of the transfer body at intervals, and the transfer plates extend in a direction perpendicular to a moving direction of the transfer body.

According to an embodiment of the present utility model, the apparatus body further forms a feed port communicating with the hydrolysis chamber and at least one drain port communicating with the hydrolysis chamber, the feed port allowing the organic waste to enter the hydrolysis chamber, and the slurry finally obtained by hydrolysis being discharged from the hydrolysis chamber through the drain port.

According to an embodiment of the utility model, the apparatus body comprises a hydrolysis part and a transition part, the hydrolysis part forming the hydrolysis chamber, the feed inlet and the drain outlet.

According to an embodiment of the utility model, the hydrolysis part has a top part and a bottom part lower than the top part, wherein the top part forms the feed inlet, and the bottom part forms the liquid discharge outlet at a preset height.

According to an embodiment of the present utility model, the bottom forms a plurality of the liquid discharge ports at different heights.

According to an embodiment of the utility model, the garbage hydrolyzing device capable of removing solid matters further comprises at least one stirring mechanism, wherein the stirring mechanism comprises a stirring piece and a driving piece, the stirring piece is rotatably connected with the driving piece, and the stirring piece is rotatably arranged in the hydrolyzing chamber.

Drawings

Fig. 1 shows a schematic structure of the garbage hydrolyzing device capable of removing solid matters.

Fig. 2 shows a use scenario of the solid phase substance removable garbage hydrolyzing apparatus according to the present utility model.

FIG. 3 is a cross-sectional view showing an example of the solid phase substance removable garbage hydrolyzing apparatus according to the present utility model

Fig. 4 shows a cross-sectional view of another embodiment of the solid phase material removable garbage hydrolyzing apparatus according to the present utility model.

Fig. 5 shows a schematic view of a part of the structure of the garbage hydrolyzing apparatus capable of removing solid matters according to the present utility model.

Fig. 6 shows a cross-sectional view at an angle to fig. 5.

Detailed Description

The following description is presented to enable one of ordinary skill in the art to make and use the utility model. The preferred embodiments in the following description are by way of example only and other obvious variations will occur to those skilled in the art. The basic principles of the utility model defined in the following description may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the utility model.

It will be appreciated by those skilled in the art that in the present disclosure, the terms "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," etc. refer to an orientation or positional relationship based on that shown in the drawings, which is merely for convenience of description and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore the above terms should not be construed as limiting the present utility model.

It will be understood that the terms "a" and "an" should be interpreted as referring to "at least one" or "one or more," i.e., in one embodiment, the number of elements may be one, while in another embodiment, the number of elements may be plural, and the term "a" should not be interpreted as limiting the number.

Referring to fig. 1 and 2, a solid phase substance-removable garbage hydrolyzing apparatus for hydrolyzing organic garbage using a hydrolysis liquid according to a preferred embodiment of the present utility model will be described in detail below.

The organic garbage comprises solid phase substances which can be hydrolyzed by the hydrolysate and solid phase substances which can not be hydrolyzed by the hydrolysate, and the solid phase substances which can not be hydrolyzed by the hydrolysate comprise sediment and floaters, wherein the sediment refers to the solid phase substances which can not be hydrolyzed by the hydrolysate and have the density higher than that of the hydrolysate, such as bones, sand stones and the like; the float refers to a solid phase substance which is not hydrolyzed by the hydrolyzed solution and has a density smaller than that of the hydrolyzed solution, such as plastic, wood block, etc.

The garbage hydrolyzing device capable of removing solid substances comprises a device main body 10 and a impurity removing mechanism 20.

Referring to fig. 3, in particular, the apparatus body 10 forms a hydrolysis chamber 1001.

Referring to fig. 4 and 5, the apparatus body 10 preferably further forms a feed port 1002 communicating with the hydrolysis chamber 1001 and at least one drain port 1003 communicating with the hydrolysis chamber 1001.

The inlet 1002 allows the organic garbage to enter the hydrolysis chamber 1001, and the solid substance that can be hydrolyzed by the hydrolysis liquid contacts with the hydrolysis liquid in the hydrolysis chamber 1001 to perform hydrolysis reaction, and finally the hydrolyzed slurry is discharged from the hydrolysis chamber 1001 through the outlet 1003.

The impurity removing mechanism 20 is provided to the apparatus main body 10 so as to be capable of bringing the sediment and/or the float in the organic waste out of the hydrolysis chamber 1001.

The impurity removing mechanism 20 includes a sediment removing member 21, wherein the sediment removing member 21 is configured to remove the sediment located in the hydrolysis chamber 1001 and deposited at the bottom of the hydrolysis chamber 1001.

Referring to fig. 4, the sediment removal assembly 21 includes a transport assembly 211 and a driver 212. The delivery assembly 211 includes a delivery body 2111. The delivery body 2111 forms a low end portion 21111 at the bottom of the hydrolysis chamber 1001 and a first high end portion 21112 higher than the low end portion 21111 outside the hydrolysis chamber 1001, wherein the delivery body 2111 is movably connected to the driving member 212 from the low end portion 21111 toward the first high end portion 21112.

In this way, the sediment in the organic waste entering the hydrolysis chamber 1001 from the feed inlet 1002 may settle down under the force of gravity and then fall onto the upper surface of the lower end portion 21111 to be carried away from the hydrolysis chamber 1001 by the conveying body 2111 moving from the lower end portion 21111 towards the first upper end portion 21112.

It should be noted that the floats in the organic garbage can fall to the upper surface of the conveying assembly 211 as the liquid level drops after the solid phase material hydrolyzable by the hydrolysis liquid is hydrolyzed and discharged from the liquid outlet 1003 to the hydrolysis chamber 1001, so as to be carried out of the hydrolysis chamber 1001 by the driven conveying body 2111.

Referring to fig. 5, that is, the apparatus body 10 is formed with a first through hole 1004 at a side wall through which a part of the delivery body 2111 passes, to form the first high end portion 21112 outside the hydrolysis chamber 1001.

Referring to fig. 4, the conveying body 2111 preferably forms a second Gao Duanbu 21113 at the other side opposite to the first high end 21112, and the second high end 21113 is higher than the low end 21111, so that the first high end 21112 and the second high end 21113 can limit the organic waste falling into the hydrolysis chamber 1001 so that the organic waste can fall within a region corresponding to the low end 21111.

Specifically, the apparatus body 10 includes a hydrolysis portion 11, and the hydrolysis portion 11 forms the hydrolysis chamber 1001, the feed port 1002, the drain port 1003, and the first through port 1004. The first high end 21112 protrudes out of the hydrolysis chamber 1001 through the first port 1004.

Preferably, the device body 10 further comprises a transition portion 12. One end of the hydrolysis part 11 extends obliquely upwards at a preset angle to form the transition part 12. In this way, the hydrolysis liquid carried by the conveyor assembly 211 may flow back again into the hydrolysis chamber 1001 along the inner wall of the transition portion 12.

Preferably, the apparatus body 10 forms an outlet 1005 facing downward at an end of the transition portion 12 away from the hydrolysis portion 11, and the outlet 1005 is used for discharging the sediment carried by the conveying assembly 211.

Preferably, the hydrolysis part 11 has a top 111 and a bottom 112 lower than the top 111, wherein the top 111 forms the feed port 1002 and the bottom 112 forms the drain port 1003.

It should be noted that the bottom 112 forms the drain port 1003 at a predetermined height, so that a part of the slurry obtained by the hydrolysis reaction can be discharged from the hydrolysis chamber 1001 through the drain port 1003, and another part of the slurry remains in the hydrolysis chamber 1001 to provide the hydrolyzed strain for the next hydrolysis.

Preferably, the bottom 112 is formed with a plurality of the liquid discharge ports 1003 at different heights. The amount of slurry retained in the hydrolysis chamber 1001 is controlled by controlling the opening and closing of the drain ports 1003 at different heights.

Referring to fig. 4, the delivery assembly 211 preferably further includes a plurality of stops 2112. The stoppers 2112 are mounted to a surface of the delivery body 2111 at intervals, and the stoppers 2112 extend in a delivery direction perpendicular to the delivery body 2111. The stopper 2112 is configured to support the substance delivered by the delivery body 2111, so as to prevent the substance delivered by the delivery body 2111 from falling back into the hydrolysis chamber 1001 due to excessive mass or/and too little friction with the delivery body 2111.

In one example, the driver 212 is implemented to include a motor and the delivery body 2111 is implemented to include a flight.

It should be noted that the hydrolysis part 11 forms a communication port 1101 at the top 111, which communicates with the hydrolysis chamber 1001.

Referring to fig. 3 and 4, further, the impurity removing mechanism 20 further includes a float removing member 22 for removing the float on the surface of the slurry through the communication port 1101 after the completion of the hydrolysis.

Referring to fig. 3, in one embodiment, the drift-removal member 22 includes a transfer assembly 221A and a power mechanism 222A. The transfer assembly 221A includes a transfer body 2211A, the transfer body 2211A forming a trash end 22111A extending into the hydrolysis chamber 1001 through the communication port 1101 and below the liquid surface and a trash end 22112A extending out of the hydrolysis chamber 1001 through the communication port 1101. The transfer body 2211A is movably connected to the power mechanism 222A from the impurity-carrying end 22111A to the impurity-discharging end 22112A. The impurity removing end portion 22112A is offset from the communication port 1101. The transfer body 2211A moving from the impurity-carrying end portion 22111A to the impurity-discharging end portion 22112A can be brought into contact with the float on the liquid surface and provide a supporting force for the float, so that the float floating on the liquid surface can be moved with the transfer body 2211A moving out of the hydrolysis chamber 1001 from the communication port 1101 and discharged from the impurity-discharging end portion 22112A.

Preferably, the transfer assembly 221A further includes a plurality of displacement plates 2212A. A plurality of the displacement preventing plates 2212A are installed at intervals on the surface of the transfer body 2211A, and the displacement preventing plates 2212A extend in a direction perpendicular to the moving direction of the transfer body 2211A. The displacement preventing plate 2212A is configured to provide a partial supporting force for the floating objects conveyed by the conveying body 2211A, so as to prevent the floating objects conveyed by the conveying body 2211A from falling into the hydrolysis chamber 1001 again due to excessive mass or/and too small friction with the conveying body 2211A.

In one example, the power mechanism 222A includes, but is not limited to, a motor, a driven roller driven by the motor, and the like. The transfer body 2211A is implemented to include a link plate.

Referring to fig. 4, as a deformable matter, the float removing member 22 includes at least one push-float object 221 and a power mechanism 222.

Specifically, the floating object 221 is drivably connected to the power mechanism 222, and the floating object 221 is disposed below the liquid surface that can partially penetrate the hydrolysis chamber 1001 through the communication port 1101, so as to drive the floating object on the liquid surface of the hydrolysis chamber 1001 to move toward the edge of the communication port 1101.

Referring to fig. 6, preferably, the hydrolysis part 11 forms at least one notch 1102 at the edge of the communication port 1101. During the process that the power mechanism 222 drives the floating objects 221 to approach the notch 1102, the floating objects 221 push part of the slurry and the floating objects together to the notch 1102, and the stirred slurry is gushed up to lift the floating objects to the height, so that the floating objects can be moved out of the hydrolysis chamber 1001 from the notch 1102.

Referring to fig. 5, in a preferred embodiment, the power mechanism 222 includes a power member 2221 and two sets of transmission assemblies 2222, wherein the two sets of transmission assemblies 2222 are disposed opposite each other. The power element 2221 is mounted to the apparatus body 10. Each set of the transmission assemblies 2222 includes a transmission belt 22221 and two transmission wheels 22222. Any one of the drive wheels 22222 is rotatably coupled to the power element 2221. The two driving wheels 22222 of each set are respectively mounted at two ends of the driving belt 22221, and the driving wheel 22222 driven by the power element 2221 drives the other driving wheel 22222 to rotate in the same direction by means of the driving belt 22221. Both ends of the floating object 221 are respectively mounted on the two driving belts 22221. The power mechanism 222 drives the floating objects 221 to move in or out of the liquid surface and move in the horizontal direction.

Referring to fig. 6, each of the floating objects 221 includes an pushing portion 2211. The pushing portion 2211 extends between the two driving belts 22221, and a part of the pushing portion 2211 can move into or out of the liquid surface. After the power mechanism 222 drives the pushing portion 2211 of the floating object 221 to rotate until the floating object 221 moves partially into the liquid surface, the power mechanism 222 continues to drive the floating object 221 to move along the horizontal direction so as to push part of the slurry and the floating object together towards the notch 1102, and then when the power mechanism 222 drives the pushing portion 2211 of the floating object 221 to rotate out of the liquid surface, an included angle is formed between the pushing portion 2211 and the liquid surface and the floating object pushed by the pushing portion 2211 is lifted so as to apply a pushing force to the floating object and accelerate the floating object to move away from the hydrolysis chamber 1001.

Preferably, each of the floating objects 221 further includes a mounting portion 2212, where two ends of the mounting portion 2212 are respectively connected to two of the driving belts 22221. The pushing portion 2211 extends vertically to form the mounting portion 2212. The mounting portion 2212 is configured to limit the floating object when the power mechanism 222 drives the floating object 221 to move along the horizontal direction to push the floating object on the liquid surface to the edge of the communication port 1101, so as to prevent the floating object from passing over the floating object 221 and returning to the liquid surface again, thereby ensuring the pushing effect.

In one example, the power member 2221 is implemented to include an electric motor.

Referring to fig. 6, further, the solid phase material removable garbage hydrolyzing apparatus further includes at least one stirring mechanism 30.

Specifically, the stirring mechanism 30 includes a stirring member 31 and a driving member 32. The stirring member 31 is rotatably connected to the driving member 32, and the stirring member 31 is rotatably provided in the hydrolysis chamber 1001.

In this way, when the stirring member 31 driven by the driving member 32 rotates in the hydrolysis chamber 1001, the stirring member 31 stirs the organic waste in the hydrolysis chamber 1001 so as to separate the solid phase material hydrolyzable by the hydrolysis liquid, the sediment and the float, and the solid phase material hydrolyzable by the hydrolysis liquid can be uniformly distributed in the hydrolysis chamber 1001, thereby avoiding insufficient hydrolysis of a part of the solid phase material hydrolyzable by the hydrolysis liquid due to accumulation of the organic waste. At the same time, the stirring member 31 can promote sufficient contact between the solid phase substance hydrolyzable by the hydrolysis liquid and the hydrolysis liquid, thereby accelerating the progress of hydrolysis.

In one example, the driver 32 is implemented to include a motor.

Further, the garbage hydrolyzing device capable of removing solid matters further comprises a liquid control pipeline 40.

The liquid control pipe 40 is installed in the hydrolysis chamber 1001. The liquid control pipe 40 has an overflow port 4001 and an overflow port 4002, wherein the overflow port 4002 is at a level lower than that of the overflow port 4001, and the overflow port 4002 communicates with the outside, and the overflow port 4001 is located in the hydrolysis chamber 1001. Thus, when the liquid level in the hydrolysis chamber 1001 exceeds the level at which the overflow port 4001 is located, the hydrolysis liquid can flow into the overflow port 4001 and be discharged from the overflow port 4002, thereby controlling the amount of hydrolysis liquid in the hydrolysis chamber 1001.

Referring to fig. 2, it is worth mentioning that a plurality of solid phase material-removable waste hydrolyzing apparatuses may be used in series, wherein the outlet 1005 of the solid phase material-removable waste hydrolyzing apparatus is aligned with the inlet 1002 of the adjacent solid phase material-removable waste hydrolyzing apparatus. The organic waste enters the hydrolysis chamber 1001 formed by the first solid-phase-material-removable waste hydrolysis device through the feed port 1002 of the device, and is then transported into the hydrolysis chamber 1001 formed by the subsequent solid-phase-material-removable waste hydrolysis device through the sediment removal means 21 provided by each device, and continuous feeding is achieved through cooperation between a plurality of solid-phase-material-removable waste hydrolysis devices connected in series.

The utility model also provides a working method of the garbage hydrolyzing device capable of removing the solid phase substances, which comprises the following steps:

(A) The organic garbage enters the hydrolysis chamber 1001 through the feeding hole 1002 and undergoes hydrolysis reaction with the hydrolysis liquid contained in the hydrolysis chamber 1001, the finally hydrolyzed slurry is discharged out of the hydrolysis chamber 1001 through the liquid discharging hole 1003, and the solid-phase substances which can not be hydrolyzed by the hydrolysis liquid are moved out of the hydrolysis chamber 1001 along with the driven conveying assembly 211.

(a1) The sediment falls to the surface of the conveyor assembly 211 under the force of gravity and is moved out of the hydrolysis chamber 1001 as the conveyor assembly 211 is driven;

(a2) The float is carried out of the hydrolysis chamber 1001 by the float removing member 22.

It will be appreciated by persons skilled in the art that the embodiments of the utility model described above and shown in the drawings are by way of example only and are not limiting. The advantages of the present utility model have been fully and effectively realized. The functional and structural principles of the present utility model have been shown and described in the examples and embodiments of the utility model may be modified or practiced without departing from the principles described.

Claims (10)

1. A solid phase material-removable garbage hydrolyzing apparatus capable of hydrolyzing organic garbage using a hydrolyzing liquid, the organic garbage comprising a solid phase material hydrolyzable by the hydrolyzing liquid and a solid phase material non-hydrolyzable by the hydrolyzing liquid, the solid phase material non-hydrolyzable by the hydrolyzing liquid including a precipitate and a float, characterized in that the solid phase material-removable garbage hydrolyzing apparatus comprises:

an apparatus body forming a hydrolysis chamber;

the impurity removing mechanism comprises a floater removing component, the floater removing component is arranged on the equipment main body, a communication port communicated with the hydrolysis chamber is formed on the side surface of the top of the hydrolysis chamber, and the floater is removed from the hydrolysis chamber through the communication port by taking away the floater.

2. The solid phase material-removable garbage hydrolyzing apparatus as claimed in claim 1, wherein the float removing member comprises at least one push-float member and a power mechanism, the power mechanism comprises a power member and two sets of transmission assemblies, wherein the two sets of transmission assemblies are disposed opposite to each other, the power member is mounted to the apparatus main body, each set of transmission assemblies comprises a transmission belt and two transmission wheels, any one of the transmission wheels is rotatably connected to the power member, the two transmission wheels disposed in each set are respectively mounted to both end portions of the transmission belt, both end portions of the push-float member are respectively mounted to the two transmission belts, the push-float member driven by the power mechanism can move into or out of the liquid level in the hydrolyzing chamber and in the horizontal direction, each push-float member comprises a push-float portion extending between the two transmission belts, and part of the push-float portion can move into or out of the liquid level.

3. The solid matter-removable garbage hydrolyzing apparatus as claimed in claim 2, wherein each of said pushing and floating members further comprises a mounting portion, wherein both ends of said mounting portion are respectively connected to two of said transmission belts.

4. The solid phase material removable garbage hydrolyzing apparatus as claimed in claim 1, wherein said float removing member comprises a transfer assembly and a power mechanism, said transfer assembly comprising a transfer body forming a trash carrying end portion extending into said hydrolyzing chamber through said communication port and below the liquid surface and a trash discharging end portion extending out of said hydrolyzing chamber through said communication port, said transfer body being movably connected to said power mechanism from said trash carrying end portion to said trash discharging end portion, said trash discharging end portion being offset from said communication port, said transfer body moving from said trash carrying end portion to said trash discharging end portion being capable of contacting said float on the liquid surface.

5. The solid phase material removable garbage hydrolyzing apparatus as claimed in claim 4, wherein the transfer assembly comprises a plurality of transfer plates installed at intervals on the surface of the transfer body, and the transfer plates extend in a direction perpendicular to the moving direction of the transfer body.

6. The solid matter-removable garbage hydrolyzing apparatus as claimed in claim 1, wherein said apparatus body further forms a feed port communicating with said hydrolyzing chamber and at least one drain port communicating with said hydrolyzing chamber, said feed port allowing said organic garbage to enter said hydrolyzing chamber, and a slurry resulting from hydrolysis being discharged from said hydrolyzing chamber through said drain port.

7. The solid matter-removable garbage hydrolyzing apparatus as claimed in claim 6, wherein said apparatus main body includes a hydrolyzing portion and a transition portion, said hydrolyzing portion forming said hydrolyzing chamber, said feed port and said drain port.

8. The solid phase material removable garbage hydrolyzing apparatus as set forth in claim 7, wherein said hydrolyzing section has a top and a bottom lower than said top, wherein said top forms said inlet and said bottom forms said outlet at a predetermined height.

9. The solid phase material removable garbage hydrolyzing apparatus as claimed in claim 8, wherein said bottom forms a plurality of said liquid discharge ports at different heights.

10. The solid phase material removable garbage hydrolyzing apparatus as set forth in any one of claims 1 to 9, further comprising at least one stirring mechanism including a stirring member and a rotation driving member, the stirring member being rotatably connected to the rotation driving member, the stirring member being rotatably provided in the hydrolyzing chamber.