CN215466969U - Crushing and solid-liquid separating device and garbage disposal device - Google Patents

Abstract

The utility model discloses a crushing and solid-liquid separating device and a garbage disposal device, wherein the crushing and solid-liquid separating device comprises a box body, a feed inlet, a discharge outlet positioned at the upper end of the box body and a liquid discharge outlet positioned at the lower end of the box body are arranged on the box body, a spiral conveying shaft is longitudinally arranged in the box body, the spiral conveying shaft is connected with a driving device for driving the spiral conveying shaft to rotate, a spiral blade of the spiral conveying shaft is positioned in a solid-liquid separating barrel, the solid-liquid separating barrel is positioned in the box body and is communicated with the feed inlet, the discharge outlet and the liquid discharge outlet, and a cutter forming shearing force with the spiral blade on the spiral conveying shaft is arranged on the inner wall of the solid-liquid separating barrel. This scheme makes solid rebound, and liquid moves down old realization solid-liquid separation, adopts helical blade and cutter cooperation to produce the shearing force, carries and smashes synchronous, and whole equipment only needs a power supply can realize that rubbish is smashed, solid-liquid separation, and the integrated level of equipment is high, and is small, the processing of being convenient for, and equipment cost and use cost are low, the application of occasions such as family of being convenient for, dining room, restaurant.

Description

Crushing and solid-liquid separating device and garbage disposal device

Technical Field

The utility model relates to the field of environment-friendly equipment, in particular to a crushing and solid-liquid separating device and a garbage disposal device.

Background

The garbage classification refers to a general term of a series of activities for classifying and storing, classifying and putting in and classifying and transporting garbage according to a certain rule or standard so as to convert the garbage into public resources.

With the rapid development of the economy of China, the garbage classification becomes a current hot topic, and the garbage classification action is actively carried out all over the country.

The kitchen waste is an important kind of waste, contains extremely high moisture and organic matters, is easy to decay and generates stink. After proper treatment and processing, the biomass can be converted into new resources, the characteristics of high organic matter content enable the biomass to be used as fertilizer and feed after strict treatment, methane can be generated to be used as fuel or power generation, and the grease part can be used for preparing biofuel.

When kitchen garbage is treated, solid-liquid separation and crushing are needed, and the conventional crushing and solid-liquid separation device adopts a structure disclosed by application number 2017208281515, wherein two motor-driven rotating shafts are provided with crushing knives to realize primary crushing, and then raking teeth driven by a cylinder are adopted to carry out secondary crushing and discharging, and finally, the solid-liquid separation effect is increased through a vibration motor.

The structure of the device needs a plurality of power sources for crushing, discharging and solid-liquid separation, the device has complex structure, high cost and high energy consumption for operation, and is obviously uneconomical for families, restaurants, dining halls and other areas.

SUMMERY OF THE UTILITY MODEL

The present invention has been made to solve the above-mentioned problems occurring in the prior art, and an object of the present invention is to provide a crushing and solid-liquid separating apparatus and a garbage disposal apparatus.

The purpose of the utility model is realized by the following technical scheme:

the crushing and solid-liquid separation device comprises a box body, wherein a feed inlet, a discharge outlet and a liquid discharge outlet are formed in the upper end of the box body, the liquid discharge outlet is formed in the lower end of the box body, a spiral conveying shaft is longitudinally arranged on the box body and connected with a driving device for driving the spiral conveying shaft to rotate, a spiral blade of the spiral conveying shaft is located in a solid-liquid separation barrel, the solid-liquid separation barrel is located in the box body and communicated with the feed inlet, the discharge outlet and the liquid discharge outlet, and a cutter forming a shearing force with the spiral blade is arranged on the inner wall of the solid-liquid separation barrel.

Preferably, in the above pulverization and solid-liquid separation apparatus, the spiral blades have micropores formed therein.

Preferably, in the crushing and solid-liquid separating device, the pitch of the helical blade is gradually reduced from bottom to top.

Preferably, in the crushing and solid-liquid separating device, the cutter is horizontally arranged and extends into a notch formed on the spiral blade.

Preferably, in the crushing and solid-liquid separating device, the pitch of the part of the helical blade at least above the cutter at the highest position is gradually reduced from bottom to top.

Preferably, in the crushing and solid-liquid separating device, the solid-liquid separating barrel is suspended in the box body.

Preferably, in the crushing and solid-liquid separating device, at least part of the first bottom plate and/or the barrel wall of the solid-liquid separating barrel is a filter plate.

Preferably, in the crushing and solid-liquid separating device, the wall of the solid-liquid separating barrel comprises a pipe body, a support ring and a filtering sleeve positioned at the bottom, which are assembled into a whole.

Preferably, in the crushing and solid-liquid separating device, the second bottom plate of the box body is provided with the liquid discharge port, and the outer wall of the spiral conveying shaft is provided with a liquid discharge blade close to the second bottom plate.

Preferably, in the crushing and solid-liquid separating apparatus, the second bottom plate is provided with a baffle plate having a notch, the liquid discharge port is located in a triangular region surrounded by the baffle plate, and the liquid discharge blade is located in a region surrounded by the baffle plate and drives the fluid to move in a direction of the liquid discharge port.

Preferably, in the crushing and solid-liquid separation device, the feed inlet is positioned on a side plate of the box body and is connected with an output port of the automatic feeder.

Preferably, in the crushing and solid-liquid separation device, one end of a material receiving groove plate of the automatic feeder is connected to a side plate where the feed inlet is located, a feed hopper is arranged on the material receiving groove plate, and a filter hole is formed in the side plate of the material receiving groove plate connected to the box body.

Preferably, in the crushing and solid-liquid separation device, a filtrate hole is formed in a material receiving groove plate of the automatic feeder, a diversion groove is formed in the lower portion of the material receiving groove plate, the lower end of an inclined plate at the bottom of the diversion groove is connected with a second bottom plate of the box body, and a notch communicated with the diversion groove is formed in a side plate of the box body.

Preferably, in the crushing and solid-liquid separation device, a baffle plate positioned above the feed inlet is arranged in the box body, a through hole and a liquid leakage hole are formed in the baffle plate, and the hole wall of the through hole is attached to the outer wall of the solid-liquid separation barrel.

A waste treatment apparatus comprising any one of the above-described comminution and solid-liquid separation apparatus.

The technical scheme of the utility model has the advantages that:

1. this scheme is through adopting the auger delivery axle of indulging putting, makes solid rebound, and liquid moves down to can realize solid-liquid separation effectively, adopt helical blade and cutter cooperation to produce the shearing force simultaneously, can realize the smashing of solid in the transport, whole equipment only needs a power supply can realize that rubbish is smashed, solid-liquid separation, the integrated level of equipment is high, and is small, and the processing of being convenient for, and equipment cost and use cost are low, the application of occasions such as the family of being convenient for, dining room, restaurant.

2. The upper part of the spiral blade adopts a variable pitch structure, so that the extrusion force can be effectively and continuously increased in the conveying process, and the effect of solid-liquid separation is improved.

3. The spiral blade of this scheme forms the breach on, and the cutter stretches into in the incision, area is cuted in the increase that can the at utmost to improve crushing effect, be favorable to simplifying the structure simultaneously.

4. The spiral blades of the scheme are provided with micropores, so that liquid generated in extrusion can flow downwards conveniently, the dryness of output garbage can be improved, and the solid-liquid separation efficiency can be improved.

5. The solid-liquid separation bucket of this scheme adopts and hangs the mode of establishing, can avoid the discharge liquid to flow back in the solid-liquid separation bucket, simultaneously, has increased liquid storage space, is favorable to reducing flowing back pressure.

6. The lateral wall structural design of the solid-liquid separation bucket of this scheme can adapt to different regional extrusion force and the crushing degree difference of rubbish effectively, avoids the problem that the dry rubbish after outlet blockage and crushing leaks outward, is favorable to improving solid-liquid separation's quality.

7. This scheme can increase drainage rate effectively through the design of guide plate and flowing back blade, improves drainage efficiency.

8. The automatic feeder is further added, and the automatic feeder is provided with the liquid discharge structure, so that the liquid discharge channel can be effectively increased, the liquid discharge is accelerated, the solid-liquid separation efficiency is improved, and the subsequent garbage conveying efficiency and the subsequent crushing effect are improved.

9. This scheme increases the feeder hopper and is favorable to increasing the regional storage space of feeding, increases the filtration pore simultaneously on the curb plate, when rubbish is remained in a large amount of kitchens, can further increase liquid discharge channel to accelerate the discharge of liquid, combine the setting of baffle, the liquid reflux that can avoid effectively separating influences the problem of separation effect in rubbish.

10. The garbage treatment device can effectively realize the separation of solid organic matters, water and oil, realize the recycling of the solid organic matters and the oil, and discharge the water after filtering, can effectively improve the harmfulness of drainage, and has good environmental friendliness.

11. The garbage disposal device is provided with the cleaning faucet, so that an operator can conveniently clean personal hygiene and clean the table top and the inside of the device, and the maintenance and the improvement of the surrounding environment are facilitated.

Drawings

FIG. 1 is a sectional view of a crushing and solid-liquid separating apparatus according to the present invention;

FIG. 2 is a perspective view of the crushing and solid-liquid separating apparatus of the present invention (the front plate member is hidden in the drawing);

FIG. 3 is a front view of the crushing and solid-liquid separating apparatus of the present invention;

FIG. 4 is a partial perspective view of the screw conveyor shaft, baffle, deflector and drainage vane region of the comminution and solid-liquid separation device of the utility model;

FIG. 5 is a partial perspective view of the screw shaft and the drain blade of the crushing and solid-liquid separating apparatus according to the present invention;

FIG. 6 is an enlarged view of area A of FIG. 1;

FIG. 7 is an enlarged view of area B of FIG. 1;

FIG. 8 is a cross-sectional view of the integrated waste management device of the present invention;

fig. 9 is a front view of the integrated garbage disposal apparatus of the present invention.

Detailed Description

Objects, advantages and features of the present invention will be illustrated and explained by the following non-limiting description of preferred embodiments. The embodiments are merely exemplary for applying the technical solutions of the present invention, and any technical solution formed by replacing or converting the equivalent thereof falls within the scope of the present invention claimed.

In the description of the schemes, it should be noted that the terms "center", "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the embodiment, the operator is used as a reference, and the direction close to the operator is a proximal end, and the direction away from the operator is a distal end.

The following describes a crushing and solid-liquid separating device disclosed by the present invention with reference to the accompanying drawings, which can be used for garbage disposal, especially for kitchen waste disposal, and can also be used for crushing and solid-liquid separating of other materials, such as fruits, vegetables, and herbs, and the following embodiments will be described by taking kitchen waste disposal as an example, as shown in fig. 1, and the device includes a box 100, and a screw conveying shaft 200 and a solid-liquid separating barrel 400 which are located in the box 100.

The box body 100 can be designed into corresponding shapes according to different requirements, as shown in fig. 1 and fig. 2, the box body 100 is a hollow cuboid or cylinder or regular polygonal prism. The box body 100 is provided with a feed inlet 110, a discharge outlet 120 and a liquid outlet 130, the feed inlet 110 is used for feeding kitchen garbage to be treated into a spiral conveying shaft 200 in the box body 100 for conveying and crushing, the discharge outlet 120 is used for discharging crushed dry garbage to the outside of the box body 100, and the liquid outlet 130 is used for discharging waste liquid obtained after solid-liquid separation to the outside of the box body 100.

The positions of the solid-liquid separation barrel and the solid-liquid separation barrel on the box body 100 can be adjusted according to different application scenarios, and in a preferred embodiment, as shown in fig. 1, the feed inlet 110 is located at the middle-lower position of the box body 100 and is equivalent to the inlet height on the side plate 150 of the solid-liquid separation barrel 200. The discharge hole 120 is located at the upper end of the box 100, and may be located at the top region of the side wall of the box 100, or may be located on the top plate 160 of the box 100, preferably on the top plate 160. The drain port 130 is located at the lower end of the box 100, and may also be located at the bottom of the side wall of the box 100 or on a second bottom plate 140 of the box, as shown in fig. 4, on the second bottom plate 140.

As shown in fig. 1, the feed inlet 110 is communicated with and positioned opposite to an inlet 430 of the solid-liquid separation barrel 400, the inlet 430 of the solid-liquid separation barrel 400 is positioned at the bottom of the barrel wall 420, an observation port 470 is arranged beside the inlet 430, and as shown in fig. 3, an observation window 170 for covering the observation port 470 is arranged on a side plate of the box body 100.

As shown in fig. 1 and 2, the solid-liquid separation barrel 400 is suspended in the box 100, and is specifically fixed at the bottom of the top plate 160 of the box 100, and the discharge port 120 is located in the area enclosed by the top plate 160 of the solid-liquid separation barrel 300. The kitchen waste enters the bottom of the solid-liquid separation tank 400 through the inlet 110 and the inlet 430, and is then conveyed upward by the spiral conveying shaft 200.

As shown in fig. 1, the spiral conveying shaft 200 includes a hollow shaft 220 rotatably disposed on the box 100, an axis of the hollow shaft 220 is at least parallel to an axis of the box 100, and is preferably coaxial with both the box 100 and the solid-liquid separation barrel 400, the hollow shaft 220 passes through a first bottom plate 410 of the solid-liquid separation barrel 400, two ends of the hollow shaft 220 are respectively connected to a bearing 240 disposed on a top plate 160 and a second bottom plate 140 of the box 100 through a joint 230, and a sealing ring 250 disposed above the bearing 240 is sleeved on the joint 230 connected to at least the second bottom plate 140.

As shown in fig. 1 and fig. 2, one of the joints 230 is connected to a driving device 300 for driving the hollow shaft 220 to rotate, the driving device 300 may be a speed reduction motor, in this case, the driving device 300 is located above or below the spiral conveying shaft 200, and a torque output rotating shaft thereof is coaxial with the hollow shaft 220. In another embodiment, the driving device 300 may also be driven by a structure of a motor 310 and a transmission mechanism 320, and the transmission mechanism may be a transmission structure formed by a belt and a synchronizing wheel 320, or a gear transmission structure, or a transmission structure formed by a sprocket and a chain. At this time, the motor 310 may be fixed to a side of the case 100, thereby simplifying a mounting structure of the motor 310.

As shown in fig. 1, the hollow shaft 220 is provided with a helical blade 210, the helical blade 210 is located in the solid-liquid separation tank 400 and extends from the top surface of the first bottom plate 410 of the solid-liquid separation tank 400 to the bottom close to the top plate 160 of the box 100, when the driving device 300 drives the hollow shaft 220 to rotate, the kitchen waste in the solid-liquid separation tank 400 can be driven to move from bottom to top to the discharge port 120 by the rotation of the helical blade 210, and simultaneously, the liquid is discharged from the liquid outlet hole 440 of the solid-liquid separation tank 400 into the box 100 and discharged from the liquid discharge port 130 under the action of the self gravity and the centrifugal force generated by the rotation of the helical blade 210.

Further, as shown in fig. 1, the outer edge 214 of the spiral blade 210 is close to the inner wall of the solid-liquid separation barrel 400 surrounding the outer periphery thereof, so that the conveying of the kitchen waste can be ensured to the maximum extent, and the spiral blade can be ensured to sufficiently extrude the kitchen waste in the solid-liquid separation barrel 400, so as to separate the waste liquid from the solid in the solid-liquid separation barrel.

Further, in order to facilitate the downward flow of the liquid generated during the transportation and extrusion, a plurality of micro-holes (not shown) are formed on the spiral blade, and the size of the micro-holes is required to meet the requirement of the liquid passing, and preferably, the pore diameter of the micro-holes is between 10 and 20 mm.

In order to improve the extrusion effect, the helical blade 210 adopts a variable-pitch structure, specifically, the pitch of the helical blade 210 is sequentially reduced from bottom to top, so that when kitchen waste is conveyed upwards, the extrusion force is gradually increased due to the gradual reduction of the space, and the extrusion dehydration can be effectively realized. More preferably, because the inner wall of the solid-liquid separation barrel 400 is also provided with the cutter 500, in order to facilitate the installation of the subsequent helical blade 210 in the solid-liquid separation barrel 400, the pitch of at least the part of the helical blade 210 above the highest cutter 500 is reduced from bottom to top.

Meanwhile, the cutters 500 are matched with the helical blades 210 for shearing, so that the kitchen waste can be effectively crushed, as shown in fig. 4, a plurality of layers of cutters 500 are further arranged on the inner surface of the barrel wall of the solid-liquid separation barrel 400, each layer is provided with a plurality of cutters 500 and is uniformly distributed, preferably, each cutter 500 is four, and the number of layers of the cutters 500 is designed according to different sizes, preferably 2-4 layers. As shown in fig. 5 and 6, each of the cutting knives 500 is horizontally disposed and extends into the notch 211 formed on the spiral blade 210, and the upper and lower surfaces of the cutting knife 500 are respectively close to the upper and lower cutting edges 212, 213 of the notch 211, so that when the spiral blade 210 rotates, the cutting knife 500 cooperates with the cutting knife 500 to form a shearing force to shear the kitchen waste to achieve crushing.

In order to facilitate the assembly of the solid-liquid separation barrel 400 with the cutter 500, the solid-liquid separation barrel 400 is assembled from a plurality of parts, and the cutter 500 is located on some of the members to facilitate the assembly, and the parts constituting the solid-liquid separation barrel 400 will be described in detail below.

In order to realize solid-liquid separation, as shown in fig. 2, liquid outlet holes 440 for discharging liquid from the inside to the outside are formed in the solid-liquid separation tank 400, and the positions of the liquid outlet holes 440 may be designed as needed, for example, the liquid outlet holes may be formed in the first bottom plate 410 of the solid-liquid separation tank 400, the filter holes may be formed in the tank wall 420 of the solid-liquid separation tank 400, or the liquid outlet holes may be formed in both the first bottom plate 410 and the tank wall 420.

In a preferred embodiment, the liquid outlet hole 440 is formed in the first bottom plate 410, and the liquid outlet hole 440 is formed in a lower area of the barrel wall 420, specifically, as shown in fig. 2, the barrel wall 420 of the solid-liquid separation barrel 400 includes a pipe 421, a support ring 422 and a filter sleeve 423 located at the bottom, which are assembled into a whole, and are coaxially arranged and fixed together from top to bottom according to the sequence of the pipe 421, the support ring 422, the pipe 421, the support ring 422 and the filter sleeve 423, and of course, the number and the length of the pipe 421, the support ring 422 and the filter sleeve 423 may be adaptively adjusted according to other needs. The inner wall of the support ring 422 is provided with the cutter 500, and the depth of the support ring 422 is shallow and the size is small, so that the cutter 500 and the support ring 422 can be processed and formed by welding, integral injection molding and other modes.

The reason why the upper end uses the tube 421 without the liquid outlet hole 440 and the lower end uses the filter sleeve 423 with the liquid outlet hole 440 is that: in the lower region of the solid-liquid separation barrel, the pressure received by the garbage is large, and the garbage is not completely crushed, so that the situation of blocking the liquid outlet hole 440 is not easy to occur, and when the garbage moves to the upper region, because the extrusion force is large and the garbage is sufficiently crushed, if the solid-liquid separation barrel is also provided with the liquid outlet hole 440, the blockage is easily caused, and the crushed material is discharged out of the solid-liquid separation barrel from the liquid outlet hole 440 and is mixed with the liquid discharged from the liquid outlet hole 440, so that the problem of insufficient solid-liquid separation is caused.

Simultaneously, go out liquid hole 440 can be the mesh, also can the round hole of dot matrix distribution, and is preferred, it is rectangular hole to go out liquid hole 440 to can increase drainage rate, guarantee solid-liquid separation bucket 400's structural strength simultaneously.

Because the solid-liquid separation barrel 400 is in a suspended state, a certain height difference exists between the solid-liquid separation barrel 400 and the liquid outlet 130, so that the liquid storage barrel has a certain liquid storage capacity, can effectively store liquid discharged from the solid-liquid separation barrel 400, reduces the possibility of liquid flowing back into the solid-liquid separation barrel 400, and is beneficial to improving the separation efficiency.

Further, as shown in fig. 4, in order to accelerate the discharge of the liquid in the casing 100, a baffle 600 provided around the outer periphery of the screw shaft 200 is provided on the second bottom plate 140 of the casing 100, the baffle 600 is perpendicular to the second bottom plate 140 and has an approximately C-shape, the drain port 130 is provided in a space surrounded by the baffle 600, a bent portion 620 bent toward the inside of the space surrounded by the baffle 600 is provided at one end of the baffle 600, and the drain port 130 is provided in a triangular region 630 surrounded by the bent portion 620 and a main region of the baffle 600.

As shown in fig. 4, the outer wall of the spiral conveying shaft 200 is provided with a drainage blade 700 disposed in the guide plate 600, the drainage blade 700 rotates along with the hollow shaft 220, and introduces the liquid outside the guide plate 600 into the area enclosed by the guide plate 600 and conveys the liquid to the drainage port 130 at the triangular area 630, and when the water flow and the bent portion 620 are blocked, the water flow can be accelerated into the drainage port 130, so that the drainage speed can be greatly increased.

For convenience of feeding, the feeding hole 110 may be connected to an upper hopper (not shown), the upper hopper may be fixed to the side plate 150 of the box 100, or may be fixed to a bracket, and a bottom plate of the upper hopper is an inclined plate.

In a more preferable mode, as shown in fig. 1 and fig. 2, the feeding inlet 110 is connected to an output 820 of an automatic feeder 800, the automatic feeder 800 may have various possible structures, and in a preferred embodiment, as shown in fig. 2 and fig. 7, the automatic feeder 800 includes a horizontally lying or inclined receiving chute plate 810, the receiving chute plate 810 is a plate member having a longitudinal section in a C shape, a U shape or a v-21274, the plate member has an upward opening and serves as a feeding inlet 830, one end of the plate member is fixed to the side plate 150 where the feeding inlet 110 is located, and the end of the plate member has at least the output 820 where the feeding inlet 110 is in a consistent and opposite shape, and the other end of the receiving chute plate 810 is provided with a sealing plate 840.

The automatic feeder 800 further includes a conveying mechanism for driving the material falling onto the receiving chute plate 810 to be conveyed towards the feeding port 110, the conveying mechanism may be a push plate (not shown in the figure) capable of reciprocating along the axis direction of the receiving chute plate 810, the push plate is connected with a linear driving device for driving the linear movement of the push plate, and the linear driving device may be an air cylinder, a hydraulic cylinder, etc., and is fixed on the sealing plate 840.

In a more preferred embodiment, the conveying mechanism adopts spiral conveying, in this case, as shown in fig. 7, the bottom area of the material receiving chute plate is circular arc-shaped, the conveying mechanism includes a rotating shaft 850 coaxial with the material receiving chute plate, the rotating shaft 850 is rotatably erected on the sealing plate and the side plate 150 of the box body 100, the rotating shaft 850 is provided with a spiral conveying blade 860, and one end of the rotating shaft 850 extending out of the sealing plate 840 is connected to a conveying motor 870 for driving the rotating shaft to rotate.

In order to accelerate solid-liquid separation and increase a liquid discharge channel, as shown in fig. 2, a filtrate hole 811 is formed on the material receiving groove plate 810, a diversion groove 1000 is arranged at the lower part of the material receiving groove plate 810, two sides of the material receiving groove plate 810 are fixed on two side plates of the diversion groove 1000, and the two side plates of the diversion groove and the two side plates of the corresponding side of the box body are both parts of a plate.

Meanwhile, as shown in fig. 2, the bottom of the guiding gutter 1000 is a sloping plate 1100, and one end 1110 of the sloping plate 1100 close to the box body is lower than the opposite end. A notch 151 is formed in the side plate 150 where the feed port 110 is located, and the notch 151 extends upwards from the lower end of the side plate 150 to a height close to the feed port 110, but may also be lower; the width of the notch 151 may be the same as the width of the side plate 150 where the notch 151 is located, and may also be larger than or smaller than the width of the side plate where the notch is located, the lower end 1110 of the inclined plate 1100 is connected to one side of the second bottom plate 140 corresponding to the notch 151, so that the liquid entering the guiding gutter 1000 can flow to the liquid discharge port 130 through the notch 151 under the action of the inclined plate 1100 and the self gravity, and the two side plates of the guiding gutter 1000 and the two side plates of the box body.

Further, in order to facilitate feeding and increase a liquid separation channel, as shown in fig. 1 and fig. 2, a feeding hopper 900 is disposed on the material receiving chute plate 810, the feeding hopper 900 covers the side plate 150 where the feeding port 110 is located, a discharging port of the feeding hopper 900 is in butt joint with the feeding port 830 of the material receiving chute plate 810, each side plate 910 of the feeding hopper 900 and the side plate on the corresponding side of the guiding chute 1000 are parts of a plate, and meanwhile, the end plate 920 of the feeding hopper 900 and the side plate where the feeding port 110 is located are also parts of a plate.

The side plate where the feeding hole 110 is located is formed with filtering holes 152, the filtering holes 152 are distributed from a height equivalent to the feeding hole to a position close to the top of the side plate, the filtering holes 152 are also formed in a plurality of rows of long holes, so that when a large amount of kitchen waste is not delivered into the automatic feeder 800 in time, liquid in the kitchen waste at the feeding hopper 900 can enter the box 100 through the filtering holes 152 at the side plate to be discharged.

In a more preferred embodiment, as shown in fig. 2 and fig. 4, a baffle 2000 located above the feed port 110 is disposed in the box 100, a via hole 2100 and a liquid leaking hole 2200 are formed on the baffle 2000, a hole wall of the via hole 2100 is attached to an outer wall of the solid-liquid separation barrel 400, and the baffle 2000 is specifically located in the middle of the filtering sleeve 423, so that liquid entering the box 100 through the filtering hole 152 and the liquid leaking hole located above the baffle 2000 can directly fall into the bottom of the box 100 through the liquid leaking hole 2200 without falling back into kitchen waste to be treated entering the feed port 110, which is beneficial to improving solid-liquid separation efficiency.

The scheme further discloses a garbage disposal device, which comprises the crushing and solid-liquid separation device of the embodiment, as shown in the attached drawings 8 and 9, the crushing and solid-liquid separation all-in-one machine 2 of the embodiment comprises a dry garbage conveying pipe 3000 connected with a discharge port 110 of the crushing and solid-liquid separation all-in-one machine 2, a liquid discharge port 130 of the dry garbage conveying pipe 3000 is connected with a liquid discharge pipe 4000, a discharge end of the dry garbage conveying pipe 3000 extends to the upper part of a garbage can 3 through a connecting pipe 6, the liquid discharge pipe 4000 is connected with a liquid inlet of an oil-water separation device 4 through an extending pipe 7, the specific structure of the oil-water separation device 4 is a known technology, the specific structure is not an innovation point of the scheme, and the specific structure is not repeated here. The water outlet of the oil-water separation device 4 is connected to a waste water filtering device 5 (not shown in the figure), the waste water filtering device 5 can be various known small water filtering devices, such as a carbon tank filter, a sand tank filter, or a filter with various water filtering filter elements, and the like, the specific structure thereof is known technology, which is not an innovation point of the scheme, and is not described herein again, and the waste water treated by the waste water filtering device 5 can be discharged to a sewer (for the first time in the figure).

Further, as shown in fig. 8 and fig. 9, the whole crushing and solid-liquid separation integrated machine 2, the garbage can 3 and the oil-water separation device 4 are all arranged in a shell 1, and the height of the shell 1 is not more than 1.5 m. At this moment, the height of the feed inlet of feeder hopper 900 is slightly higher than the top height of auger delivery axle 200, the top of shell 1 have with charge door 12 that the feed inlet of feeder hopper 900 corresponds, charge door 12 is for leaking hopper-shaped, simultaneously, the side of shell 1 includes open closed door 11, door 11 is at least including just right garbage bin 3's part to can make things convenient for garbage bin 3 to follow shift out in the shell 1 and put into. Preferably, the housing 1 has two openable and closable doors 11 on one side, and one of the doors is a split door. Meanwhile, an observation window 14 is formed on the door 11 facing the garbage can 3, and the observation window 14 faces the discharge end of the adapter tube 6.

Finally, after the garbage is dumped, as shown in fig. 8 and 9, a faucet 8 is further provided on the housing 1, and the faucet 8 is preferably a stretchable faucet, in order to facilitate the cleaning of the table top and the washing of hands by the operator. In order to avoid the overflow of the sewage during the cleaning, in a more preferred embodiment, as shown in fig. 8, at least the area of the top of the housing 1 where the feed opening 12 is located is a wash tank 13, so that there is a top exterior of the housing 1 that effectively avoids the overflow of the sewage.

As shown in fig. 8 and fig. 9, most of the top of the housing 1 is the wash basin 13, the rest is a boss, the top angle of the boss facing the door 11 is a chamfer, the chamfer is provided with a control device 9, the control device 9 is used for controlling the operation of the integrated pulverizing and solid-liquid separating machine 2, the garbage can 3 and the oil-water separating device 4, and the integrated pulverizing and solid-liquid separating machine comprises a control screen and a control button, and the specific structure of the integrated pulverizing and solid-liquid separating machine is known in the art, and is not described herein.

When the whole device works, kitchen waste is put into the automatic feeder 800 from the feeding hopper 900, at the moment, the conveying motor of the automatic feeder 800 can be started and stopped by means of manual operation buttons or touch screens, and a sensor can be arranged at the feeding hopper 900 to sense whether materials enter or not to generate a starting signal, and the automatic stopping is controlled by a program.

The automatic feeder 800 conveys kitchen garbage in the automatic feeder to the solid-liquid separation barrel, the spiral conveying shaft rotates to convey the kitchen garbage upwards, the spiral blades are matched with the cutter to shear, meanwhile, the spiral blades extrude to realize solid-liquid separation, crushed solid moves upwards to the discharge port and is output to the garbage can 3 through the dry garbage conveying pipe, separated liquid is conveyed to the oil-water separation device to be separated, and wastewater enters the wastewater filtering device 5 and is discharged after being filtered.

The utility model has various embodiments, and all technical solutions formed by adopting equivalent transformation or equivalent transformation are within the protection scope of the utility model.

Claims (13)

1. Crushing and solid-liquid separation equipment, its characterized in that: the device comprises a box body (100), wherein a feeding hole (110), a discharging hole (120) and a liquid discharging hole (130) are formed in the upper end of the box body (100), the liquid discharging hole (130) is formed in the lower end of the box body, a spiral conveying shaft (200) is longitudinally arranged on the box body (100), the spiral conveying shaft (200) is connected with a driving device (300) for driving the spiral conveying shaft to rotate, a spiral blade (210) of the spiral conveying shaft (200) is located in a solid-liquid separation barrel (400), the solid-liquid separation barrel (400) is located in the box body (100) and communicated with the feeding hole (110), the discharging hole (120) and the liquid discharging hole (130), a cutting knife (500) forming shearing force with the spiral blade (210) is arranged on the inner wall of the solid-liquid separation barrel (400), and the cutting knife (500) is horizontally arranged and extends into a notch (211) formed in the spiral blade (210).

2. The crushing and solid-liquid separating apparatus according to claim 1, wherein: the helical blade (210) is formed with micropores.

3. The crushing and solid-liquid separating apparatus according to claim 1, wherein: the pitch of at least the part of the spiral blade (210) above the cutter (500) at the highest position is gradually reduced from bottom to top.

4. The crushing and solid-liquid separating apparatus according to claim 1, wherein: the solid-liquid separation barrel is suspended in the box body.

5. The crushing and solid-liquid separating apparatus according to claim 1, wherein: at least part of the first bottom plate (410) and/or the barrel wall (420) of the solid-liquid separation barrel (400) is a filter plate.

6. The crushing and solid-liquid separating apparatus according to claim 1, wherein: the barrel wall (420) of the solid-liquid separation barrel (400) comprises a pipe body (421), a support ring (422) and a filtering sleeve (423) which is positioned at the bottom, wherein the pipe body and the support ring are assembled into a whole.

7. The crushing and solid-liquid separating apparatus according to claim 1, wherein: the liquid discharge port (130) is formed in the second bottom plate (140) of the box body (100), and liquid discharge blades (700) close to the second bottom plate (140) are arranged on the outer wall of the spiral conveying shaft (200).

8. The crushing and solid-liquid separating apparatus according to claim 7, wherein: the second bottom plate (140) is provided with a guide plate (600) with a notch, the liquid discharge port is positioned in a triangular area enclosed by the guide plate, and the liquid discharge blade (700) is positioned in an area enclosed by the guide plate (600) and drives fluid to move towards the liquid discharge port.

9. The crushing and solid-liquid separating apparatus according to claim 1, wherein: the feed inlet (110) is located on a side plate of the box body and connected with an output port of the automatic feeder (800).

10. The crushing and solid-liquid separating apparatus according to claim 9, wherein: the one end of material receiving groove plate (810) of automatic feeder (800) is connected on the curb plate at feed inlet place, be provided with feeder hopper (900) on material receiving groove plate (810), box (100) are connected material receiving groove plate's curb plate department is formed with the filtration pore.

11. The crushing and solid-liquid separating apparatus according to claim 9, wherein: the automatic feeder is characterized in that a filtrate hole is formed in a material receiving groove plate (810) of the automatic feeder (800), a flow guide groove (1000) is formed in the lower portion of the material receiving groove plate (810), the lower end of an inclined plate (1100) at the bottom of the flow guide groove (1000) is connected with a second bottom plate of the box body, and a notch communicated with the flow guide groove (1000) is formed in a side plate of the box body.

12. The crushing and solid-liquid separating apparatus according to any one of claims 1 to 11, wherein: the liquid-solid separation tank is characterized in that a baffle (2000) positioned above the feeding hole (110) is arranged in the tank body (100), a through hole (2100) and a liquid leakage hole (2200) are formed in the baffle (2000), and the hole wall of the through hole (2100) is attached to the outer wall of the solid-liquid separation tank (400).

13. Garbage treatment device, its characterized in that: comprising the pulverizing and solid-liquid separating apparatus according to any one of claims 1 to 12.

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