CN211100735U - Kitchen waste and sludge co-processing system - Google Patents

Abstract

The utility model discloses a kitchen garbage and mud cooperative processing system, including the sieve formula sorting unit who is used for the kitchen garbage screening that connects gradually, be used for the crushing sorting unit who selects separately of the gained fine crushing kitchen material behind the screening, be used for to smash the oil water separating equipment that the kitchen thick liquids that sorting unit divides the choice carried out the oil-water separation processing, be used for mud and the kitchen thick liquids after the processing of deoiling mix the pulping equipment in coordination to and be used for carrying out anaerobic digestion's anaerobic digestion equipment to the mixed thick liquids that the pulping equipment made in coordination. The kitchen waste can reduce the content of inorganic matters after being classified, sorted and deslagged, and the anaerobic fermentation efficiency is improved. Meanwhile, the abrasion to the inside of the tank body is reduced. On one hand, the deoiling treatment can collect and recycle the waste oil (such as biodiesel and the like) and increase the project benefit. On the other hand, the content of grease in the slurry can be reduced, the specific adhesion and isolation characteristics of the grease are realized, and the anaerobic reaction effect is improved after the grease is removed.

Description

Kitchen waste and sludge co-processing system

Technical Field

The utility model belongs to the technical field of organic solid waste treatment facility, especially, relate to a kitchen garbage and mud cooperative processing system.

Background

Kitchen waste, commonly known as swill, also known as swill and hogwash, is a domestic waste formed in the process of domestic consumption by residents, is extremely easy to rot and deteriorate, emits foul smell, and spreads bacteria and viruses. The main components of the kitchen waste comprise rice and flour food residues, vegetables, animal and vegetable oil, meat and bones and the like, and the kitchen waste comprises starch, cellulose, protein, lipid and inorganic salt in terms of chemical composition. The kitchen waste is mainly characterized by high moisture, high salinity and high organic matter content, is easy to rot and deteriorate, is easy to breed germs, and can have bad influence on physical and mental health of residents if not properly treated, such as swill pigs, swill-cooked dirty oil and the like. Anaerobic digestion technology is generally used for kitchen waste treatment, biogas generated by anaerobic digestion of kitchen waste is generally used for power generation, purification and compression and is difficult to efficiently utilize, and biogas residues generated by anaerobic digestion need to be treated and disposed.

Municipal sludge has the following characteristics: high water content, low heat value and high fluidity; is easy to be biodegraded and rotten; the organic matter content is high, and the organic matter is rich in N, P and various trace elements; the heavy metal species and content are high. The characteristics cause the sludge treatment process on the market to have the problems. The high organic matter content causes the sludge to easily generate odor and secondary pollution such as percolate and the like in the landfill process, and seriously harms the surrounding environment and underground water sources; the high water content causes that a large amount of auxiliary fuel is added for sludge incineration, the treatment cost is greatly increased, and toxic and harmful gases such as dioxin and the like are generated. The high heavy metal content results in limited use of sludge compost products, which are 'valuable and unmarketable' in the market. Compared with the processes, the anaerobic digestion technology is utilized to treat the political sludge, so that secondary pollution can be reduced to the maximum extent, the methane which can be used as clean energy can be generated, and the reduction, the recycling and the harmlessness of the solid waste are effectively realized.

At present, the sludge is generally treated with municipal sewage in a combined way, and treated with anaerobic digestion alone. The method has the advantages that the method has a separate kitchen waste treatment technology and a separate fecal waste treatment technology, but the separate treatment method has the problems of high cost, complex management, poor treatment effect, secondary pollution and the like.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome the not enough of prior art, provide a kitchen garbage and mud cooperative processing system who improves anaerobic fermentation efficiency and effect.

In order to solve the technical problem, the utility model discloses a following technical scheme:

the utility model provides a kitchen garbage and mud coprocessing system, is including the screen type sorting facilities that is used for the kitchen garbage screening that connects gradually, the crushing sorting facilities that is used for the crushing sorting of the gained fine crushing kitchen material after the screening, be used for carrying out the oil water separation equipment that deoils the kitchen thick liquids that smashes the sorting facilities and select separately, be used for mud and the cooperation pulping equipment that deoils the mixed thick liquids of kitchen thick liquids after handling, and be used for carrying out anaerobic digestion's anaerobic digestion equipment to the mixed thick liquids that the pulping equipment made in coordination.

The kitchen waste can reduce the content of inorganic matters after being classified, sorted and deslagged, and the anaerobic fermentation efficiency is improved. Meanwhile, the abrasion to the inside of the tank body is reduced.

On one hand, the deoiling treatment can collect and recycle the waste oil (such as biodiesel and the like) and increase the project benefit. On the other hand, the content of grease in the slurry can be reduced, the specific adhesion and isolation characteristics of the grease are realized, and the anaerobic reaction effect is improved after the grease is removed.

As a further improvement of the above technical solution:

the screen type separation equipment is provided with a feed inlet, a waste residue outlet and a slurry outlet, the crushing separation equipment is provided with a feed inlet, a waste residue outlet and a slurry outlet, the oil-water separation equipment is provided with a feed inlet, an oil outlet, a water phase outlet and a residue outlet, the cooperative pulping equipment is provided with a feed inlet and a mixed slurry outlet, and the anaerobic digestion equipment is provided with a feed inlet, a methane outlet and a residue liquid outlet; the slurry outlet of the screen type sorting equipment is communicated with the feed inlet of the crushing sorting equipment, the slurry outlet of the crushing sorting equipment is communicated with the feed inlet of the oil-water separation equipment, the water phase outlet and the slag outlet of the oil-water separation equipment are communicated with the feed inlet of the cooperative pulping equipment, and the mixed slurry discharge port of the cooperative pulping equipment is communicated with the feed inlet of the anaerobic digestion equipment.

Still be equipped with centrifugal dehydration equipment between crushing sorting equipment and the oil water separating equipment, centrifugal dehydration equipment is equipped with feed inlet, filtrating export and slag charge export, crushing sorting equipment's thick liquids export and centrifugal dehydration equipment's feed inlet intercommunication, centrifugal dehydration equipment's filtrating export and oil water separating equipment's feed inlet intercommunication, centrifugal dehydration equipment's slag charge export and slurrying equipment's feed inlet intercommunication in coordination.

Crushing sorting equipment and centrifugal dehydration equipment still have in proper order to link to have desanding equipment and store up thick liquid equipment, desanding equipment is equipped with entry, waste residue export and thick liquid export, and crushing sorting equipment's thick liquid export communicates with the entry of desanding equipment, and desanding equipment's thick liquid export communicates with the entry of storing up thick liquid equipment, store up thick liquid equipment's export with centrifugal dehydration equipment's feed inlet intercommunication.

The kitchen waste collection device is characterized by further comprising a kitchen waste collection hopper and a sludge collection hopper, wherein the kitchen waste collection hopper is provided with a filtrate outlet and a slag outlet, the filtrate outlet of the kitchen waste collection hopper is communicated with an inlet of the pulp storage device, and the slag outlet of the kitchen waste collection hopper is communicated with a feed inlet of the screen type separation device through a shaftless spiral elevator; the sludge receiving hopper is communicated with a feed inlet of the cooperative pulping equipment through a screw conveyer.

Be equipped with between sieve formula sorting unit and the crushing sorting unit and stir the pulp machine, stir the pulp machine and be equipped with feed inlet, waste residue export and thick liquids export, stir the feed inlet of pulp machine and sieve formula sorting unit's thick liquids export intercommunication, stir the thick liquids export of pulp machine and smash sorting unit's feed inlet intercommunication.

Still include the waste residue and collect the fill, the waste residue export of sieve formula sorting unit, crushing sorting unit, pulp grinder and degritting equipment all is through screw conveyer and waste residue collection fill intercommunication.

The screen type sorting equipment comprises a shell, a stirring shaft capable of rotating in the circumferential direction and a screen cylinder capable of rotating in the circumferential direction relative to the stirring shaft, wherein the screen cylinder is positioned in the shell, two ends of the screen cylinder in the axial direction of the screen cylinder are opened, the axial directions of the screen cylinder and the stirring shaft are parallel or coaxial, and the stirring shaft penetrates through the screen cylinder and penetrates through two end faces of the shell in the axial direction of the stirring shaft; the shell is provided with a feed inlet, a waste residue outlet and a slurry outlet, the feed inlet and the waste residue outlet are respectively arranged on two sides of the screen cylinder along the axial direction of the stirring shaft, the slurry outlet is arranged between the feed inlet and the waste residue outlet, the opening of the feed inlet is upward, and the openings of the waste residue outlet and the slurry outlet are downward; a plurality of stirring mechanisms are arranged on the section of the stirring shaft in the shell, and the stirring mechanisms are arranged at intervals along the axial direction of the stirring shaft; every rabbling mechanism includes two harrow boards groups that set up relatively, and every harrow board group includes a plurality of harrow boards, and a plurality of harrow boards are the heliciform and arrange on the axis direction of (mixing) shaft, the projection of harrow board group on the cross-section of perpendicular to (mixing) shaft axis is fan-shaped, fan-shaped central angle < 180 °.

From this, the heliciform structure has the function with material propulsive forward, and the rake board group that sets up relatively can be raised and thrown the kitchen garbage in the removal at the (mixing) shaft rotation in-process, produces the stirring effect to kitchen garbage, makes kitchen garbage contact screen cloth structure many times to sieve many times, not only can improve screening efficiency, can also reduce kitchen garbage winding and hanging material phenomenon.

The principle of the equipment for separating the kitchen waste is as follows: the kitchen waste is driven by the stirring mechanism to move from the head part of the shell to the tail part of the shell in the rotating process of the stirring shaft, and meanwhile, the kitchen waste can be lifted and thrown off by the stirring mechanism. Meanwhile, the screen drum rotates around the axis of the screen drum, so that the kitchen waste smaller than the diameter of the screen hole is thrown out of the screen drum through the screen hole. And the kitchen waste which can not pass through the sieve holes of the sieve drum is gradually moved to the tail part of the shell under the pushing of the stirring mechanism and is discharged through the discharge hole.

In order to further reduce the phenomena of kitchen waste winding and hanging, the central angle of the fan shape is not more than 90 degrees.

The shell is provided with a material collecting hopper with a downward opening, the material collecting hopper is arranged between the feeding hole and the discharging hole, and the screened materials after separation are collected.

In order to fix the screen drum and ensure that the screen drum can rotate around the axis of the screen drum, two sides of the axis direction of the screen drum are respectively provided with a slewing bearing, the outer ring of the slewing bearing is fixedly connected with the screen drum, the inner ring of the slewing bearing is fixedly connected with the shell, and the shell is provided with a driving mechanism which is in transmission connection with the outer ring of the slewing bearing.

Mounting plates fixedly connected with the outer wall of the shell are respectively arranged on two sides of the screen cylinder along the axis direction, and the inner ring of the slewing bearing is fixedly connected with the mounting plates; one of the mounting plates is provided with a driving mechanism which is in transmission connection with the outer ring of the slewing bearing so as to drive the screen drum to rotate.

The two rake plates of the two opposite rake plate groups correspond one to one, and the two rake plates which correspond to each other are respectively arranged at two ends of the radial direction of the circular section which is vertical to the axis of the stirring shaft.

The opposite surfaces of the two corresponding rake plates are back to the other rake plate to form a curved surface, so that the functions of raising and forward propelling the kitchen waste by the stirring mechanism are further improved.

In order to conveniently replace the harrow plate, a plurality of lantern rings uniformly distributed along the axial direction of the stirring shaft are arranged on the stirring shaft, and the harrow plate is connected to the lantern rings through a connecting shaft.

The screen drum is characterized in that a water spraying pipe is arranged on the shell, and a nozzle which extends into the shell and extends towards the screen drum is communicated with the water spraying pipe. The setting of spray pipe is favorable to the organic matter in the kitchen garbage to be dissolved in high temperature aquatic on the one hand, improves the recycle of organic matter, and on the other hand, under the washing of high temperature water, can effectively wash grease and the material on the sealing shell wall to the collecting hopper, the mesh jam of reducible sieve section of thick bamboo.

The housing is arranged on an underframe for fixing the housing.

Compared with the prior art, the utility model has the advantages of:

(1) the system realizes the cooperative treatment of the kitchen waste and the municipal sludge, saves the occupied area, reduces the production cost, simplifies the management procedure and improves the energy utilization rate by the cooperation of substances.

(2) The system equipment adopts multi-stage separation, the inorganic matter content is reduced after the kitchen waste is deslagged, the anaerobic fermentation efficiency is improved, and meanwhile, the abrasion to the inner part of the tank body is reduced. The inorganic matter removal rate can reach more than 95 percent, the granularity, the uniformity, the inorganic matter content and the like can meet the requirements of subsequent anaerobic fermentation, and the gas production rate of the subsequent anaerobic fermentation and the like are effectively improved.

(3) On one hand, the deoiling treatment can collect and recycle the waste oil (such as biodiesel and the like) and increase the project benefit. On the other hand, the method can reduce the content of grease in the slurry, has the specific adhesion and isolation characteristics of the grease, and increases the anaerobic reaction effect after removal

(4) The process can be applied to various types of waste, such as sludge, kitchen waste, livestock and poultry manure, organic waste in the vegetable market and the like.

(5) The sludge and the kitchen waste can be treated cooperatively, natural gas and nutrient soil can be produced, biogas slurry in the process is recycled, external emission is reduced, and recycling, emission reduction and harmless treatment of the sludge, the excrement and the kitchen waste are realized.

Drawings

Fig. 1 is a schematic diagram of a kitchen waste and sludge co-processing system of the embodiment of the utility model.

Fig. 2 is a schematic perspective view of a screen type sorting apparatus according to an embodiment of the present invention.

Fig. 3 is a schematic side view of a screen type sorting apparatus according to an embodiment of the present invention.

Fig. 4 is a schematic front view of a sieve type sorting apparatus according to an embodiment of the present invention.

Fig. 5 is a sectional view a-a of fig. 3.

Fig. 6 is a sectional view B-B of fig. 4.

Fig. 7 is a cross-sectional view taken along line C-C of fig. 4.

Fig. 8 is a cross-sectional view taken along line D-D of fig. 4.

Fig. 9 is an enlarged view of the structure at a in fig. 5.

Fig. 10 is a schematic perspective view of the rotary shaft raking device.

Fig. 11 is a schematic perspective view of a screen drum.

Illustration of the drawings: 10. a screen type sorting device; 20. crushing and sorting equipment; 30. an oil-water separation device; 40. a cooperative pulping apparatus; 50. an anaerobic digestion unit; 60. a centrifugal dewatering device; 70. sand removing equipment; 80. a slurry storage device; 90. a kitchen waste receiving hopper; 100. a sludge receiving hopper; 110. a shaftless screw elevator; 120. a screw conveyor; 130. stirring a pulp machine; 140. a waste residue collecting hopper; 150. an in-line heater; 160. a grease storage tank; 170. a liquid storage tank; 180. slag storage tank; 190. a screw pump; 200. a collecting and transporting vehicle; 210. a filtrate tank; 220. a sludge transport vehicle; 230. a solid-liquid separation device; 240. a sewage treatment system; 250. a deodorizing device; 1. a housing; 11. a feed inlet; 12. a discharge port; 13. a collection hopper; 14. a water spray pipe; 141. a nozzle; 15. an end closing plate; 16. a connecting plate; 17. sealing and pressing strips; 18. mounting a plate; 19. a stink collecting port; 2. A stirring shaft; 3. a screen cylinder; 31. an end connecting disc; 32. a screen drum carrier; 33. a filter plate; 4. a rake board group; 41. raking a plate; 42. a connecting shaft; 5. a slewing bearing; 51. an outer ring; 52. an inner ring; 6. a drive device; 7. a drive mechanism; 71. a drive motor; 72. a drive gear; 8. a collar; 9. a chassis; 101. and (4) a water inlet pipe.

Detailed Description

The invention is further described below with reference to specific preferred embodiments, without thereby limiting the scope of protection of the invention.

Example (b):

as shown in fig. 1, the system for co-processing kitchen waste and sludge in this embodiment includes a kitchen waste receiving hopper 90, a screen type sorting device 10, a pulping machine 130, a crushing and sorting device 20, a waste residue collecting hopper 140, a desanding device 70, a pulp storage device 80, a centrifugal dewatering device 60, an online heater 150, an oil-water separation device 30, a grease storage tank 160, a liquid storage tank 170, a slag storage tank 180, a sludge receiving hopper 100, a co-pulping device 40, and an anaerobic digestion device 50.

Wherein, the screen type sorting device 10, the slurry stirring machine 130, the crushing sorting device 20, the desanding device 70, the slurry storage device 80 and the waste residue collecting hopper 140 form a multi-stage rapid sorting system. The centrifugal dehydration equipment 60, the on-line heater 150, the oil-water separation equipment 30, the grease storage tank 160, the liquid storage tank 170 and the slag storage tank 180 form an oil-water separation system.

The kitchen waste receiving hopper 90 is provided with a filtrate outlet and a slag outlet, the screen type sorting equipment 10 is provided with a feed inlet, a waste slag outlet and a slurry outlet, and the slag outlet of the kitchen waste receiving hopper 90 is communicated with the feed inlet of the screen type sorting equipment 10 through a shaftless spiral elevator 110; the filtrate outlet of the kitchen waste receiving hopper 90 is communicated with the inlet of the pulp storage device 80 through a screw pump 190.

The kitchen waste is discharged to the kitchen waste receiving hopper 90 by the collecting and transporting vehicle 200, the kitchen waste receiving hopper 90 has three functions of storing, leaching and feeding, and a deodorizing device 250 is further arranged above the kitchen waste receiving hopper 90. The volume of the kitchen waste receiving bin 90 can ensure that the kitchen waste collecting and transporting vehicle can discharge at any time and can also ensure that a subsequent sorting system can continuously operate. The bottom of the kitchen waste receiving hopper 90 is provided with a shaftless spiral elevator 110, the shaftless spiral elevator 110 can perform solid-liquid separation in the feeding process, the shaftless spiral elevator 110 conveys the semi-solid substances obtained by extruding and separating the waste to a multistage rapid separation system, meanwhile, the kitchen waste receiving hopper 90 collects the filtrate obtained by extruding and separating the waste by the shaftless spiral elevator 110 and flows into a filtrate pool 210, and the filtrate is conveyed to the slurry storage device 80 through a screw pump 190.

In the multistage quick separation system:

the pulp stirring machine 130 is provided with a feeding hole, a waste residue outlet and a pulp outlet, the crushing and sorting equipment 20 is provided with a feeding hole, a waste residue outlet and a pulp outlet, the feeding hole of the pulp stirring machine 130 is communicated with the pulp outlet of the screen type sorting equipment 10, and the pulp outlet of the pulp stirring machine 130 is communicated with the feeding hole of the crushing and sorting equipment 20.

The desanding device 70 (in this embodiment, an AAe model desander manufactured by the Henan Anyang Allen energy corporation) is provided with an inlet, a waste residue outlet and a slurry outlet, the slurry outlet of the crushing and sorting device 20 is communicated with the inlet of the desanding device 70 through a screw pump 190, the slurry outlet of the desanding device 70 is communicated with the inlet of the slurry storage device 80, the centrifugal dewatering device 60 is provided with a feed inlet, a filtrate outlet and a slag outlet, and the outlet of the slurry storage device 80 is communicated with the feed inlet of the centrifugal dewatering device 60.

The waste residue outlets of the screen type sorting apparatus 10, the crushing and sorting apparatus 20, the pulper 130 and the desanding apparatus 70 are all communicated with a waste residue collecting hopper 140 through a screw conveyor 120.

The smashing and sorting device 20 is mainly used for sorting sundries with particle sizes larger than 50mm in kitchen waste, the continuous stirring machine 130 is mainly used for smashing materials and spraying recycled water to remove the sundries with particle sizes larger than 20mm, the wet-type smashing and sorting device 20 is mainly used for smashing slurry and removing the sundries with particle sizes larger than 8mm, the desanding device 70 is mainly used for removing sundries such as fine ceramic chips, sand and stone and scrap iron, the slurry storage device 80 is mainly used for receiving and mixing filtrate, hot steam is introduced to preheat simultaneously, the temperature of the slurry is kept constant at a certain value, and the feeding requirement of the oil-water separation system is met.

Further, the crushing and sorting device 1, the continuous pulper 130 (in this embodiment, TGC80 type continuous pulper manufactured by nibovista environment equipment corporation) and the wet crushing and sorting device 20 (in this embodiment, SFF1200 type wet crushing and sorting machine manufactured by nibovista environment equipment corporation) are all composed of a filtering outer cylinder, an intermediate crushing and conveying device, a driving device, a filtrate collecting device and the like, and have functions of automatic speed regulation, screening, filtering, conveying, collecting and the like, the running rotating speeds of the filtering outer cylinder and the conveying device can be automatically adjusted, impurities with set particle sizes can be automatically screened out and conveyed to a designated interface position, and the separated slurry can be automatically collected.

In this embodiment, the screw conveyor 120 (in this embodiment, a W L S400 shaftless screw conveyor manufactured by hao-tian environmental protection limited, pout city) has the functions of adjusting the rotating speed and conveying materials in a metering manner, and can convey materials according to the system requirements.

The crushing and sorting device 1 is a device developed by the applicant independently, and as shown in fig. 2, comprises a shell 1, a stirring shaft 2, a driving device 6 for driving the stirring shaft 2 to rotate circumferentially, a screen cylinder 3, and a driving mechanism 7 for driving the screen cylinder 3 to rotate circumferentially relative to the stirring shaft 2. On a chassis 9 was located to casing 1, a sieve section of thick bamboo 3 was located casing 1, and sieve section of thick bamboo 3 was opened along the both ends of 3 axis directions of a sieve section of thick bamboo, and sieve section of thick bamboo 3 is parallel or coaxial with (mixing) shaft 2's axis direction, and (mixing) shaft 2 wears to locate in the sieve section of thick bamboo 3 and runs through casing 1 along two terminal surfaces of (mixing) shaft 2 axis direction. As shown in fig. 3, the driving device 6 is installed on the base frame and is composed of a speed-regulating driving motor, a belt and a belt pulley, and the belt pulley is fixedly connected with the stirring shaft 2. The driving motor is in transmission connection with the belt pulley by adopting a belt, so that the rotating speed of the stirring shaft 2 is controlled by driving and adjusting the rotating speed of the speed-regulating driving motor.

The shell 1 is provided with a feed inlet 11, a waste residue outlet 12 and a slurry outlet 13, the feed inlet 11 and the waste residue outlet 12 are respectively arranged on two sides of the screen cylinder 3 along the axial direction of the stirring shaft 2, the slurry outlet 13 is arranged between the feed inlet 11 and the waste residue outlet 12, the slurry outlet 13 is used for collecting sieved materials after separation, and the waste residue outlet 12 is used for collecting sieved materials after separation. The inlet 11 is open upwardly and the slag outlet 12 and the slurry outlet 13 are open downwardly. Further, the top wall of the sealing case has a foul-collecting port 19. The shell 1 adopts a closed structure, so that odor can be prevented from being dispersed, and the air quality in a workshop can be effectively improved. As shown in figure 2, the part of the shell 1 provided with the screen drum 3 is box-shaped, two ends of the shell are cylindrical structures, and the feed inlet 11 and the waste residue outlet 12 are arranged on the corresponding cylindrical structures. In addition, be equipped with the spray pipe 14 with outside inlet tube 101 intercommunication on the box structure of casing 1, the lower extreme of spray pipe 14 is equipped with a plurality of nozzles 141 that stretch into in the casing 1, and kitchen garbage mixes with the high temperature water of supplying through inlet tube 101, is favorable to the organic matter in the kitchen garbage to dissolve in the high temperature water on the one hand, improves the recycle of organic matter, and on the other hand, under the washing of high temperature water, can effectively wash grease and the material on the sealed casing wall to thick liquids export 13, the mesh jam of reducible gyration outer screen section of thick bamboo 3. The water inlet pipe 101 is provided with a water quantity adjusting device, and the water inlet quantity can be actually adjusted according to the operation condition on site.

As shown in fig. 11, the screen cylinder 3 is detachably connected by a screen cylinder bracket 32, a filter plate 33 and the like, the multiple stages of screen cylinder brackets 32 are of uniform specification and model, and the filter plate 33 is of the same specification and model, so that the equipment installation and replacement are convenient. The mesh aperture on the filter plate 33 can be adjusted in advance during manufacturing so as to meet the requirements of the filter aperture in different stages of the kitchen waste. Therefore, in the working process of the kitchen waste rotary screen, different screen structures can be replaced according to the specific conditions of the kitchen waste or the screen structures so as to meet the specific working requirements. The sieve pores on the filter plate 33 adopt a structure of double-end big and small, and the pore walls adopt smooth arc surfaces, so that the phenomenon of hanging materials generated by kitchen waste can be further reduced.

Continuing to refer to fig. 11, the two sides of the screen cylinder 3 along the axial direction are respectively provided with a mounting plate 18 fixedly connected with the outer wall of the box-shaped structure of the casing 1, the mounting plate 18 is a semi-ring structure, as shown in fig. 8, the mounting plate 18 is parallel to and spaced from the end sealing plate 15 of the casing 1, the upper part is connected with the end sealing plate 15 of the casing 1 through a connecting plate 16, and the lower part is fixedly connected with the bottom frame 9 through bolts. The two sides of the axial direction of the screen cylinder 3 are respectively provided with a slewing bearing 5, and the slewing bearings 5 are positioned in a space enclosed by the mounting plate 18, the end sealing plate 15 of the shell 1 and the connecting plate 16. The inner ring 52 of the slewing bearing 5 is fixedly connected with the mounting plate 18 through bolts, and the outer ring 51 of the slewing bearing 5 is fixedly connected with the end connecting disc 31 of the screen cylinder 3 through bolts. The screen cylinder 3 is thus supported in the housing 1 by two slewing bearings 5. As shown in fig. 7 and 8, the driving mechanism 7 includes a driving motor 71, and a driving gear 72 drivingly connected to the driving motor 71, the driving motor 71 being mounted on an outer end surface of one of the mounting plates 18, and the driving gear 72 being mounted on an inner end surface of the one mounting plate 18 and meshing with the outer race 51 of the slewing bearing 5. The speed of the driving motor 71 is adjustable, so that the rotating speed of the rotary outer screen drum 3 is adjustable. The end connecting disc 31 of the screen drum 3 is connected with the sealing shell 1 through the sealing pressing strip 17, the end connecting disc 31 and the feeding end are also sealed through the sealing pressing strip 17, and the fact that interference and leakage between the screen drum 31 and the static sealing shell 1 in the rotating process are avoided is guaranteed.

As shown in fig. 10, a plurality of stirring mechanisms are arranged on a section of the stirring shaft 2 in the housing 1, the plurality of stirring mechanisms are uniformly distributed at intervals along the axial direction of the stirring shaft 2, each stirring mechanism comprises two oppositely arranged rake plate groups 4, each rake plate group 4 comprises a plurality of rake plates 41, the plurality of rake plates 41 are spirally arranged along the axial direction of the stirring shaft 2, as shown in fig. 6, the projection of the rake plate groups 4 on the section perpendicular to the axial direction of the stirring shaft 2 is a sector, and the central angle α of the sector is not more than 90 °.

As shown in fig. 5 and 7, the stirring shaft 2 is formed by hollow circular tubes and is formed by a plurality of transmission shaft sections, the transmission shaft sections are connected by joint bearings 21, and the rear transmission shaft section has a function of automatically adjusting the rotating speed so as to improve the working efficiency. The stirring shaft 2 is provided with a plurality of lantern rings 8 which are uniformly distributed along the axial direction of the stirring shaft 2, and the harrow plate 41 is connected to the lantern rings 8 through a connecting shaft 42.

The harrow plate 41 and the connecting shaft 42 are flexibly connected, and when larger garbage enters a gap between the harrow plate 41 and the inner wall of the rotary outer screen drum 3 to form jamming, the harrow plate 41 can automatically buffer and avoid in time, so that the phenomenon of material jamming is reduced.

From this, the heliciform structure has the function with the material impels forward, and relative rake board group 4 that sets up can be kicked up and thrown at the (mixing) shaft 2 rotation in-process to the kitchen garbage in the motion, produces the stirring effect to kitchen garbage, makes kitchen garbage contact screen structure many times to sieve many times, not only can improve screening efficiency, can also reduce the winding of kitchen garbage and hang the material.

Wherein, the harrow plates 41 of two opposite harrow plate groups 4 are in one-to-one correspondence, and the two harrow plates 41 which are in mutual correspondence are respectively arranged at two ends of the radial direction of the circular section which is vertical to the axial line of the stirring shaft 2. The opposite surfaces of the two rake plates 41 corresponding to each other are recessed back to the other rake plate 41 to form a curved surface, so as to further improve the functions of raising and pushing the kitchen waste forward by the stirring mechanism.

The rake plate 41 adopts a uniform type rake plate structure, and is convenient to install and replace.

This sorting unit passes through drive arrangement 6 and 7 and drives respectively the rabbling mechanism and the outer sieve section of thick bamboo 3 of gyration in sealed housing to carry out screening treatment with the kitchen garbage of different volumes, (mixing) shaft 2 is rotatory around the axis of self under drive arrangement 6's drive, and kitchen garbage moves from 1 head of sealed housing to 1 afterbody of sealed housing under the rabbling mechanism drive on (mixing) shaft 2, and rabbling mechanism can be raised partial kitchen garbage and throw off simultaneously. Meanwhile, the rotary outer screen drum 3 is driven by the driving mechanism 7 to rotate around the axis of the rotary outer screen drum 3, so that kitchen waste smaller than the diameter of the screen holes is thrown out of the rotary outer screen drum 3 through the screen holes and reaches the slurry outlet 13 at the bottom of the sealing shell 1 to be collected, and then is discharged through the slurry outlet 13. And the kitchen waste which can not pass through the sieve holes of the rotary outer sieve drum gradually moves to the tail part of the sealing shell 1 under the pushing of the stirring mechanism and is discharged through the waste residue outlet 12.

In the working process of the kitchen waste sorting device, the stirring shaft 2 and the rotary outer screen drum 3 are independently controlled by corresponding driving devices respectively, and the corresponding rotating speed of the kitchen waste sorting device can be adjusted in real time in the actual operation process.

The axis of (mixing) shaft 2 and the outer sieve section of thick bamboo 3 of gyration can set up to coaxial line and parallel two kinds, and two kinds of (mixing) shaft 2 and the outer sieve section of thick bamboo 3 of gyration are concentric and decentraction promptly, when having the great volume rubbish of unable timely discharge when the primary election, great volume rubbish can get into the position in great clearance between 3 inner walls of the outer sieve section of thick bamboo of rabbling mechanism and gyration, makes the rabbling mechanism in time dodge and reduce the emergence of card material phenomenon.

Through the adjustment, the screening of the kitchen waste in different stages and different particle sizes can be realized. Such as: when impurities with the particle size larger than 50mm in the kitchen waste are roughly screened, the mesh aperture of the rotary outer screen cylinder is set to be phi 50mm, the stirring shaft 2 and the stirring mechanism form a rotary shaft swinging and raking device, the rotary shaft swinging and raking device and the rotary outer screen cylinder are set to be in a non-concentric structural form, then the rotating speeds of the rotary shaft swinging and raking device and the rotary outer screen cylinder are adjusted according to the discharging condition of the materials at the impurity discharge port at the tail part of the sealing shell, when the content of small particles in the materials at the impurity discharge port at the tail part of the sealing shell is large, the rotating speed of the rotary shaft swinging and raking device can be reduced or stopped, and meanwhile, the rotating. When the sundries with the particle size larger than 8mm in the kitchen waste are finely screened, the rotating shaft swinging and raking device and the rotary outer screen cylinder are arranged in a concentric structure mode, the mesh aperture of the rotary outer screen cylinder is set to be phi 8mm, the rotating speed of the rotating shaft swinging and raking device is increased, the crushing function is increased, and the rotating speed of the rotary outer screen cylinder is increased, so that the centrifugal separation effect is improved.

In the oil-water separation system:

the oil-water separation device 30 (the embodiment adopts an AUPR type high-efficiency full-automatic oil separator produced by Shenzhen Auprin science and technology Limited company) is provided with a feed inlet, a grease outlet, a water phase outlet and a slag outlet, a filtrate outlet of the centrifugal dehydration device 60 (the embodiment adopts an L W series horizontal screw centrifuge produced by Jinhua Shenzhou centrifuge Limited company) is communicated with an inlet of the online heater 150, an outlet of the online heater 150 is communicated with the feed inlet of the oil-water separation device 30, the grease outlet of the oil-water separation device 30 is communicated with the grease storage tank 160, the water phase outlet of the oil-water separation device 30 is communicated with an inlet of the liquid storage tank 170, and slag outlets of the oil-water separation device 30 and the centrifugal dehydration device 60 are communicated with an inlet of the slag storage tank 180 through the.

Slurry preheated by steam in the slurry storage device 80 is pumped to the centrifugal dehydration device 60 through a screw pump, the centrifuged filtrate enters the online heater 150, the online heater 150 is simultaneously introduced with hot steam in a waste heat system for heating, the filtrate is heated to 85 +/-5 ℃ by the steam and then enters the oil-water separation device 30 for three-phase separation, wherein the grease is stored in the grease storage tank 160, the water phase enters the liquid storage tank 170, part of the water phase is recycled as high-temperature recycled water, the residual water phase enters the cooperative pulping device 40 and is cooperatively pulped with municipal sludge, and slag after centrifugal dehydration and three-phase separation is conveyed to the slag storage tank 180 for caching through the screw conveyor 120 and is cooperatively pulped.

Municipal sludge is transported by the sludge transport vehicle 220 to the sludge receiving hopper 100 for buffering, and simultaneously the sludge is transported to the cooperative pulping apparatus 40 by the screw conveyor 120 arranged at the bottom of the sludge receiving hopper 100.

The cooperative pulping equipment 40 (in this embodiment, the cooperative pulping equipment is composed of a stainless steel tank and stirring equipment made of 316L, and the rotating speed of the stirring equipment is adjustable) is provided with a feed inlet and a mixed pulp outlet, the anaerobic digestion equipment 50 (in this embodiment, an ATOM (anaerobic digester) assembly type anaerobic reactor manufactured by Qingdao Tian Nippon environmental corporation is adopted) is provided with a feed inlet, a methane outlet and a slag liquid outlet, outlets of the liquid storage tank 170 and the slag storage tank 180 are both communicated with the feed inlet of the cooperative pulping equipment 40, and the mixed pulp outlet of the cooperative pulping equipment 40 is communicated with the feed inlet of the anaerobic digestion equipment 50 through a screw pump 190.

The cooperative pulping equipment 40 is mainly used for hydrolyzing and acidifying the municipal sludge, the water phase separated by the oil-water separation system, the slag materials after centrifugal dehydration and three-phase separation and the system reuse biogas slurry together, and preparing the slurry meeting the requirement of anaerobic digestion after mixing and stirring.

The anaerobic digestion equipment 50 is formed by connecting a plurality of anaerobic digestion tanks in series, and slurry generated by the cooperative pulping equipment 40 is pumped to the anaerobic digestion equipment 50 through a screw pump 190 to carry out anaerobic digestion reaction. The system adopts mesophilic anaerobic digestion, the water content is about 90 percent, the temperature is about 38 ℃, organic matters are degraded in a mesophilic anaerobic digestion tank, one part of generated biogas is used for a steam boiler, the generated steam is used for heating a multistage rapid sorting system and an oil-water separation system, one part of biogas is used for biogas power generation, a supply system automatically uses electricity, and the rest biogas is purified and stored in a biogas tank and is recycled; and (3) performing filter pressing dehydration on the mixture of the biogas residues and the biogas slurry after anaerobic digestion by using a solid-liquid separation device 230 until the biogas residues with the water content of 50-60 percent are obtained, performing aerobic composting on the biogas residues to prepare an organic fertilizer, performing reflux utilization on one part of the dehydrated biogas slurry, and performing comprehensive treatment on the rest biogas slurry by using a sewage treatment system 240 to realize resource utilization or discharge.

The above description is only for the preferred embodiment of the present application and should not be taken as limiting the present application in any way, and although the present application has been disclosed in the preferred embodiment, it is not intended to limit the present application, and those skilled in the art should understand that they can make various changes and modifications within the technical scope of the present application without departing from the scope of the present application, and therefore all the changes and modifications can be made within the technical scope of the present application.

Claims (10)

1. The kitchen waste and sludge cooperative processing system is characterized by comprising a screen type sorting device (10) used for screening kitchen waste, a crushing sorting device (20) used for crushing and sorting finely-divided kitchen materials obtained after screening, an oil-water separation device (30) used for deoiling kitchen slurry sorted by the crushing sorting device (20), a cooperative pulping device (40) used for mixing sludge and kitchen slurry subjected to deoiling, and an anaerobic digestion device (50) used for performing anaerobic digestion on the mixed slurry prepared by the cooperative pulping device (40), wherein the screen type sorting device (10) is sequentially connected with the oil-water separation device (30).

2. The kitchen waste and sludge co-processing system according to claim 1, wherein the screen type separation equipment (10) is provided with a feed inlet, a waste residue outlet and a slurry outlet, the crushing separation equipment (20) is provided with a feed inlet, a waste residue outlet and a slurry outlet, the oil-water separation equipment (30) is provided with a feed inlet, an oil outlet, a water phase outlet and a residue outlet, the co-pulping equipment (40) is provided with a feed inlet and a mixed slurry outlet, and the anaerobic digestion equipment (50) is provided with a feed inlet, a methane outlet and a residue liquid outlet; the thick liquids export of sieve formula sorting equipment (10) and the feed inlet intercommunication of smashing sorting equipment (20), the thick liquids export of smashing sorting equipment (20) and the feed inlet intercommunication of oil water separating equipment (30), the water phase export and the slag charge export of oil water separating equipment (30) all communicate with the feed inlet of slurrying equipment (40) in coordination, the mixed thick liquids discharge gate of slurrying equipment (40) in coordination communicates with the feed inlet of anaerobic digestion equipment (50).

3. The kitchen waste and sludge coprocessing system according to claim 2, wherein a centrifugal dewatering device (60) is further arranged between the crushing and sorting device (20) and the oil-water separating device (30), the centrifugal dewatering device (60) is provided with a feed inlet, a filtrate outlet and a slag outlet, the slurry outlet of the crushing and sorting device (20) is communicated with the feed inlet of the centrifugal dewatering device (60), the filtrate outlet of the centrifugal dewatering device (60) is communicated with the feed inlet of the oil-water separating device (30), and the slag outlet of the centrifugal dewatering device (60) is communicated with the feed inlet of the synergetic pulping device (40).

4. The kitchen waste and sludge coprocessing system of claim 3, wherein the crushing and sorting equipment (20) and the centrifugal dewatering equipment (60) are further sequentially connected with a desanding equipment (70) and a slurry storage equipment (80), the desanding equipment (70) is provided with an inlet, a waste residue outlet and a slurry outlet, the slurry outlet of the crushing and sorting equipment (20) is communicated with the inlet of the desanding equipment (70), the slurry outlet of the desanding equipment (70) is communicated with the inlet of the slurry storage equipment (80), and the outlet of the slurry storage equipment (80) is communicated with the feed inlet of the centrifugal dewatering equipment (60).

5. The kitchen waste and sludge co-processing system according to claim 4, further comprising a kitchen waste receiving hopper (90) and a sludge receiving hopper (100), wherein the kitchen waste receiving hopper (90) is provided with a filtrate outlet and a slag outlet, the filtrate outlet of the kitchen waste receiving hopper (90) is communicated with an inlet of a pulp storage device (80), and the slag outlet of the kitchen waste receiving hopper (90) is communicated with a feed inlet of a screen type sorting device (10) through a shaftless screw elevator (110); the sludge receiving hopper (100) is communicated with a feed inlet of the cooperative pulping equipment (40) through a screw conveyer (120).

6. The kitchen waste and sludge co-processing system according to claim 5, wherein a pulp stirrer (130) is arranged between the screen type sorting device (10) and the crushing sorting device (20), the pulp stirrer (130) is provided with a feed inlet, a waste residue outlet and a pulp outlet, the feed inlet of the pulp stirrer (130) is communicated with the pulp outlet of the screen type sorting device (10), and the pulp outlet of the pulp stirrer (130) is communicated with the feed inlet of the crushing sorting device (20).

7. The kitchen waste and sludge co-processing system according to claim 6, further comprising a waste residue collection hopper (140), wherein the waste residue outlets of the screen type sorting device (10), the crushing sorting device (20), the pulper (130) and the desanding device (70) are communicated with the waste residue collection hopper (140) through a screw conveyor (120).

8. The kitchen waste and sludge co-processing system according to any one of claims 2-7, wherein the screen type separation device (10) comprises a housing (1), a stirring shaft (2) capable of rotating circumferentially, and a screen cylinder (3) capable of rotating circumferentially relative to the stirring shaft (2), the screen cylinder (3) is located in the housing (1), two ends of the screen cylinder (3) in the axial direction of the screen cylinder (3) are open, the axial directions of the screen cylinder (3) and the stirring shaft (2) are parallel or coaxial, and the stirring shaft (2) is inserted into the screen cylinder (3) and penetrates through two end faces of the housing (1) in the axial direction of the stirring shaft (2); the shell (1) is provided with a feed inlet (11), a waste residue outlet (12) and a slurry outlet (13), the feed inlet (11) and the waste residue outlet (12) are respectively arranged at two sides of the screen cylinder (3) along the axial direction of the stirring shaft (2), the slurry outlet (13) is arranged between the feed inlet (11) and the waste residue outlet (12), the opening of the feed inlet (11) faces upwards, and the openings of the waste residue outlet (12) and the slurry outlet (13) face downwards; a plurality of stirring mechanisms are arranged on the section of the stirring shaft (2) in the shell (1), and are arranged at intervals along the axial direction of the stirring shaft (2); every rabbling mechanism includes two harrow board groups (4) that set up relatively, and every harrow board group (4) includes a plurality of harrow boards (41), and a plurality of harrow boards (41) are the heliciform and arrange on the axis direction of (mixing) shaft (2), the projection of harrow board group (4) on the cross-section of perpendicular to (mixing) shaft (2) axis is the fan-shaped, fan-shaped central angle < 180 °.

9. The kitchen waste and sludge cooperative treatment system according to claim 8, wherein two sides of the screen drum (3) in the axial direction are respectively provided with a slewing bearing (5), an outer ring (51) of the slewing bearing (5) is fixedly connected with the screen drum (3), an inner ring (52) of the slewing bearing (5) is fixedly connected with the shell (1), and the shell (1) is provided with a driving mechanism (7) in transmission connection with the outer ring (51) of the slewing bearing (5).

10. The kitchen waste and sludge co-processing system according to claim 8, wherein the opposite surfaces of the two rake plates (41) corresponding to each other are recessed away from the other rake plate (41) to form a curved surface.

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