CN214735262U - Dirty two-stage anaerobic treatment device of scale pig raising excrement - Google Patents
Dirty two-stage anaerobic treatment device of scale pig raising excrement Download PDFInfo
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Abstract
The utility model belongs to the technical field of water pollution deals with, specifically be a dirty two-stage anaerobic treatment device of scale pig raising excrement. The device comprises a second-stage solid manure separator, a material homogenizing adjusting tank, a sedimentation tank, a first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor, a second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor, a trace element methane yield-increasing nutrient salt adding system, a second-stage medium-temperature anaerobic discharging buffer tank, an air source high-temperature heat pump, a water source heat pump and four plate heat exchangers; the utility model discloses an innovative high temperature + medium temperature two-stage anaerobic treatment process handles scale pig raising factory and mixes excrement dirt, has improved the treatment effeciency of excrement dirt greatly, for newly-built or current scale pig farm excrement dirt provides new processing thinking and scheme, the utility model discloses the device operation is stable, energy-conserving, high-efficient, marsh gas output is high, treatment effeciency is high, save the anaerobic reactor investment in methane content, has wide application prospect in the marsh gas.
Description
Technical Field
The utility model belongs to the technical field of water pollution handles, concretely relates to dirty two-stage anaerobic treatment device of scale pig raising excrement.
Background
In recent years, the animal husbandry in China is continuously and stably developed, the large-scale breeding level is obviously improved, the meat, egg and milk supply is guaranteed, but a large amount of breeding waste is not practically and effectively treated and utilized, and the method is a big problem of environmental management.
The method controls the excrement discharge of the livestock farm and promotes the comprehensive utilization of the livestock excrement, becomes the basic premise of the current healthy development of the breeding industry, and is the hard requirement of the environmental protection law and the pollution control regulation of the livestock and poultry scale breeding. In the comprehensive control of livestock and poultry breeding manure, the construction and operation conditions of infrastructure determine whether the livestock and poultry manure can be comprehensively utilized, and are basic conditions for measuring the standard construction of farms in China. According to the suggestion on promoting the resource utilization of the livestock and poultry breeding waste, which is published in 2017, a scientific standard, clear authority and powerful constraint livestock and poultry breeding waste resource utilization system is established and a breeding cycle development mechanism is constructed in 2020, the national livestock and poultry manure comprehensive utilization rate reaches over 75 percent, the manure treatment facility equipment matching rate of a large-scale farm reaches over 95 percent, and the large-scale farm is 100 percent in advance one year. However, the achievement difficulty of the goal is very high at present, the current situation of the concentrated pig raising excrement treatment in China is not optimistic at present, and many enterprises mainly adopt the mode of simple black film biogas anaerobic treatment and biogas slurry returning, which means that the treatment process is simple and extensive and organic pollutants cannot be removed efficiently; products such as biogas residues, biogas slurry and the like cannot be effectively utilized, and most pollutants enter water bodies in a surface runoff manner after the biogas slurry is returned to the field, so that the products become main causes of pollution of water bodies such as riverways and the like.
As for the domestic pig raising excrement treatment process, the following process routes are mainly adopted:
firstly, solid-liquid separation is carried out, a multi-stage solid manure separator is conventionally adopted, solid matters in manure are firstly separated, the separated solid manure and straws and the like are subjected to combined composting for resource utilization, the separated liquid is subjected to anaerobic treatment by adopting a conventional upflow anaerobic sludge blanket process (UASB), biogas can be utilized, and biogas slurry after anaerobic treatment enters a deep aerobic and denitrification treatment process system or directly enters a large biogas slurry storage tank for stabilization treatment and then is returned to the field for utilization;
secondly, solid-liquid separation is not carried out, a full-mixing type continuous stirring anaerobic reactor is directly adopted for treatment, and the solid content of the excrement is generally only 2-3%, so that the process usually needs to be added with high-content inherent machine wastes such as straws, kitchen waste and the like for combined anaerobic fermentation. And performing solid-liquid separation after anaerobic treatment, wherein biogas residues can be composted, and biogas slurry is subjected to advanced treatment or enters a large storage pool for stabilization treatment.
The two modes are applied to domestic large-scale pig farms. However, the above processes all have the following disadvantages: (1) most anaerobic systems for treating excrement are difficult to normally operate under the low-temperature condition in winter, the treatment effect is poor, and even a lot of anaerobic systems are directly shut down under the winter condition; (2) when solid-liquid separation is not carried out, a fully mixed continuous stirrer anaerobic reaction system (CSTR) which is commonly adopted in China adopts a top stirring mode or a side stirring mode, and because light feeds remained in pig raising excrement are light, a scum layer is often formed at the top of an anaerobic reactor, so that the treatment effect of an anaerobic treatment system is influenced; meanwhile, due to the fact that organic wastes such as straws and the like are added for combined anaerobic fermentation, although the carbon-nitrogen ratio of the mixed material is improved, cellulose which is difficult to degrade biochemically is decomposed and dissolved in biogas slurry in the anaerobic fermentation process of the process, and the difficulty of further advanced treatment of the subsequent biogas slurry is large. (3) When solid-liquid separation is carried out firstly, a conventional UASB anaerobic treatment process is generally adopted in China, solid manure is difficult to be completely separated by solid manure separation, and residual light solid manure often floats on the top of the anaerobic reactor to form a scum layer, so that the normal treatment effect of the anaerobic reactor is influenced. Meanwhile, as the solid manure is separated, the methane generated by an anaerobic system is reduced by more than 50 percent, and the fertilizer efficiency of the separated solid manure is lower than that of the compost of anaerobic biogas residues.
In addition, the black film methane technology adopted by many large-scale pig-raising enterprises at present is used by many enterprises due to simple structure and low investment. However, this is only to save the cost of the treatment investment of the manure, and it is not an advance of the process. The disadvantages are that: (1) the reactor structure adopts the form of digging pits and laying HDPE impermeable membranes, so that the feces cannot be leaked at the bottom of the tank to pollute the underground water; (2) meanwhile, the HDPE film for top sealing is difficult to ensure the risk of methane leakage under the condition that the film is punctured by an external force. (3) Solid manure or anaerobic sludge is often deposited at the bottom of the black film methane tank, and the sludge is difficult to clean due to large volume and is difficult to empty the black film methane tank; (3) the process mode of returning biogas slurry to fields is mostly adopted in the process of adopting 'black film biogas', the biogas slurry is not further subjected to advanced treatment, and the process mode is an important source of domestic non-point source pollution.
The utility model provides a problem to existence in the present scale pig raising excrement and sewage treatment process, the utility model provides a high temperature anaerobism + middle temperature anaerobism two-stage intermittent type formula three-dimensional stirring combined treatment method and device, the device mainly includes excrement and sewage homogeneity pond, the all-round intermittent type formula stirring high temperature anaerobic reactor of one-level, the all-round intermittent type formula middle temperature anaerobic reactor of second grade, high temperature anaerobic reactor heat pump temperature guarantee system, one-level high temperature anaerobism ejection of compact heat recovery system, the heat recovery system of the middle temperature anaerobism play water of second grade, marsh gas is handled and is utilized the system, marsh slag compost system etc. and trace element throws marsh gas yield increase system etc..
Disclosure of Invention
An object of the utility model is to provide a dirty two-stage anaerobic treatment device of dirty processing efficiency of excrement, marsh gas output are high, the small investment of scale pig raising excrement.
The utility model provides a large-scale pig raising excrement two-stage anaerobic treatment device, which comprises a second-stage solid excrement separator, a material homogenizing adjusting tank, a sedimentation tank, a first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor, a second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor, a trace element methane yield-increasing nutritive salt adding system, a second-stage medium-temperature anaerobic discharging buffer tank, an air source high-temperature heat pump, a water source heat pump and four plate heat exchangers; wherein:
the second-stage solid manure separator adopts a rotary drum type pig manure dry-temperature separator for twice separation; the device is used for separating solid manure from sewage from the manure storage pool;
the material homogenizing adjusting tank is internally provided with a stirrer and a thermometer, and the outer part of the material homogenizing adjusting tank is provided with a heat-insulating layer; used for adjusting the concentration of the excrement;
the sedimentation tank is used for settling the excrement;
the upper part of the inner side of the two-stage full-mixing type intermittent stirring high-temperature anaerobic reactor is provided with a stirring, slag breaking and mixing propeller, the lower part of the inner side is symmetrically provided with stirring propellers, and the stirring propellers have the functions of preventing vortex and destroying a scum layer; the outside of the heat-insulating layer is provided with a heat-insulating layer (for example, the outside is provided with a 50mm polyurethane foam heat-insulating layer and a color steel plate); the top of the biogas storage cabinet adopts a biogas storage cabinet structure; the side surface of the bottom of the sand tank is provided with a vent, and the bottom of the sand tank is externally provided with a sand setting groove;
the primary full-mixing type intermittent stirring high-temperature anaerobic reactor is structurally different from the secondary full-mixing type intermittent stirring high-temperature anaerobic reactor in that the top of the primary full-mixing type intermittent stirring high-temperature anaerobic reactor is of a sealed structure, and the rest structures are the same;
the second-stage medium-temperature anaerobic discharging buffer tank is internally provided with a material mixing stirrer and a second temperature sensor, and the side part of the second-stage medium-temperature anaerobic discharging buffer tank is provided with a discharging hole after anaerobic treatment;
the trace element methane yield-increasing nutrient salt adding system is connected with the middle top of the material homogenization adjusting tank through a pipeline and is used for adding trace element nutrient solution into the material homogenization adjusting tank;
the first plate heat exchanger, the water source heat pump and the connected circulating pipeline form a preheating system of the material homogenizing adjusting tank;
the third plate heat exchanger, the water source heat pump and the connected circulating pipeline form a primary high-temperature anaerobic discharging heat energy recovery system,
and the fourth plate heat exchanger, the water source heat pump and a circulating pipeline connected with the fourth plate heat exchanger form a secondary medium-temperature anaerobic discharging heat energy recovery system.
The second plate heat exchanger, the air source high-temperature heat pump and the connected circulating pipeline form a temperature guarantee system of the primary high-temperature anaerobic system;
the excrement in the excrement storage pool is subjected to solid-liquid separation through a secondary excrement-solid separator; part of solid manure and part of original manure separated by the secondary solid manure separator enter a material homogenizing adjusting tank through a conveying mechanism for homogenizing adjustment; separating the excrement with smaller suspended matters into two paths, wherein one path of the excrement with smaller suspended matters enters a sedimentation tank, part of the excrement which is precipitated at the bottom of the sedimentation tank and is not separated from solid excrement is conveyed into a material homogenization adjusting tank through a pipeline, the other path of the excrement is used for conveying one part of the excrement on the upper part of the solid excrement which is precipitated in the sedimentation tank after separation into a separated waste water treatment system through a pipeline, and the other part of the excrement is conveyed into the material homogenization adjusting tank so as to adjust the material concentration in the tank;
the material after being tempered in the material homogeneity adjusting tank enters a first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor through a pipeline; the top of the first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor is provided with a high-temperature pressure system biogas discharge pipeline connected with a biogas purification and utilization system and a high-temperature anaerobic temperature guarantee system formed by the heat exchange and interconnection of a second plate heat exchanger and an air source high-temperature heat pump through pipelines;
the side part of the first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor is connected with the second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor through a third plate heat exchanger by a pipeline; the top parts of the first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor and the second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor are connected with a methane purification and utilization system through pipelines;
the side part of the second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor is connected with a second-stage medium-temperature anaerobic discharge buffer tank through a pipeline; the bottom of the second-stage medium-temperature anaerobic discharge buffer tank is in thermal circulation interactive connection with a fourth plate heat exchanger through a pipeline; a discharge hole after anaerobic treatment is formed in the side part of the second-stage medium-temperature anaerobic discharge buffer tank;
the upper side part of the secondary full-mixing type intermittent stirring medium-temperature anaerobic reactor is connected with a top waste gas discharge pipe and an overflow outlet after anaerobic treatment in a branching way through a water seal pipe; is connected with an external methane purification and utilization system through a methane outlet arranged at the top.
Furthermore, a coarse filter screen for coarse filtration of 40-60 meshes is arranged in the rotary drum type pig manure dry-warm separator for twice separation, and a fine filter screen for fine filtration of 300-400 meshes is arranged for twice separation.
Furthermore, the separated wastewater treatment system adopts an upflow anaerobic sludge blanket UASB or a black film methane tank anaerobic system.
Further, the system for adding the trace element biogas yield-increasing nutrient salt comprises a liquid adding pump, a container and related pipelines, wherein the trace element nutrient salt is dissolved under an acidic condition, and liquid medicine is added by the liquid adding pump. Here, the trace elements include iron, cobalt, nickel, calcium, magnesium, molybdenum, and the like.
The two-stage anaerobic treatment device for the feces in the large-scale pig raising comprises the following specific working procedures:
s01, feeding the feces mixed liquid discharged from the pigsty into a feces storage pool, and conveying the feces mixed liquid to a secondary solid-feces separator through a conveying mechanism for secondary solid-liquid separation;
s02, solid manure with the solid content of 25-30% separated by the secondary solid manure separator and part of raw manure enter a material homogenizing adjustment tank through a conveying mechanism for homogenizing adjustment; separating the separated excrement and sewage with suspended matters less than 3000mg/L into two paths, wherein one path of the excrement and sewage enters a sedimentation tank, part of the excrement and sewage which is precipitated at the bottom of the sedimentation tank and is not separated from solid excrement is conveyed into a material homogenization adjusting tank through a pipeline, and the other path of the excrement and sewage at the upper part of the solid excrement and sewage which is separated and precipitated by the sedimentation tank is conveyed to a separated waste water treatment system through a pipeline and is conveyed to a material homogenization adjusting tank; simultaneously, adding a biogas yield-increasing nutrient solution into a material homogenizing adjusting tank by a trace element biogas yield-increasing nutrient salt adding system, mixing and homogenizing partial excrement sewage which is not separated from solid excrement and solid excrement separated by a secondary solid excrement separator in the material homogenizing adjusting tank, and adjusting the material concentration to 5-8% of solid content; the material homogenizing adjusting tank preheating system recovers the discharge heat energy of the first-stage high-temperature anaerobic system and the discharge heat energy of the second-stage medium-temperature anaerobic system, and transfers the heat energy to the circulating water system of the water source heat pump so as to reduce the temperature of anaerobic discharge and increase the temperature of circulating water; the circulating water with the increased temperature transfers the heat energy in the circulating water to the material in the material homogenizing adjusting tank, so that the temperature of the fed material is increased, namely the fed material is preheated;
s03, feeding the material tempered by the material homogenizing adjusting tank into a primary fully-mixed intermittent stirring high-temperature anaerobic reactor through a pipeline, and performing primary high-temperature anaerobic treatment at the normal operation temperature of 52-55 ℃; wherein, the high-temperature anaerobic temperature guarantee system guarantees the high-temperature anaerobic temperature, and the primary high-temperature anaerobic discharge heat energy recovery system recovers the primary heat energy; purifying and utilizing the methane generated by the primary full-mixing type intermittent stirring high-temperature anaerobic reactor by using a methane purification and utilization system;
s04, conveying the sewage subjected to the primary high-temperature oxidation treatment to a secondary full-mixing type intermittent stirring medium-temperature anaerobic reactor through a primary full-mixing type intermittent stirring high-temperature anaerobic reactor and a third plate heat exchanger, performing secondary medium-temperature anaerobic treatment at the normal operation temperature of 30-35 ℃, reducing the temperature of the discharged material to 10-25 ℃ by using a secondary medium-temperature anaerobic discharged material heat energy recovery system, and further recovering heat energy in the discharged material; biogas generated by the secondary moderate-temperature anaerobic system is released to the top of the reactor and is stored by a biogas storage cabinet structure arranged at the top, and meanwhile, the functions of degrading organic pollutants and degassing materials are further realized;
and S05, connecting the side part of the secondary full-mixing type intermittent stirring medium temperature anaerobic reactor with a secondary medium temperature anaerobic discharge buffer tank through a pipeline, and buffering by recovering heat energy in medium temperature anaerobic discharge.
Compared with the prior art, the utility model has the following advantages.
1. The utility model discloses a dirty two-stage anaerobic treatment device of scale pig raising excrement and method adopts high temperature + medium temperature two-stage anaerobic treatment technology to handle the dirty mixed excrement of scale pig raising factory, has solved not enough among the prior art practical application of processing, has improved the dirty treatment effeciency of excrement greatly, and this novel treatment process's innovation point lies in with the advantage:
(1) the first domestic project of treating the large-scale pig raising excrement by adopting a high-temperature and medium-temperature anaerobic process builds a daily treatment capacity of 20m3Exemplary engineering of/d;
(2) the first-stage anaerobic process adopts a high-temperature anaerobic process, so that the reaction rate is high, the retention time is short, and the investment can be reduced;
(3) the primary high-temperature anaerobic section can degrade most organic pollutants (COD 75%, TSS 45-50%), the methane content in the methane generated by the high-temperature anaerobic process is 5-15% higher than that in the methane generated by medium-temperature anaerobic process, and the total yield of the methane is 10-15%;
(4) by adopting a high-temperature anaerobic process, more than 99% of pathogenic bacteria can be killed;
(5) the air source heat pump high-temperature anaerobic temperature guarantee system, the water source heat pump high-temperature anaerobic system discharge and the medium-temperature anaerobic system discharge heat energy are innovatively adopted for heating the tempered mixed material, the heating cost of the high-temperature anaerobic system and the operation cost of the whole system can be greatly saved, and the system can still efficiently operate under the low-temperature condition in winter, so that the system has great advantages compared with the actual situation that most anaerobic systems for treating feces cannot normally operate under the low-temperature condition in winter in China;
(6) and a system for adding the nutrient salt for increasing the yield of the biogas by using the trace elements of iron, cobalt, nickel, calcium, magnesium and molybdenum is innovatively adopted, so that the biogas yield of the process is improved by 15-20%.
2. Along with the continuous increase of domestic large-scale pig farm construction, the utility model discloses a newly-built or current large-scale pig farm excrement and sewage provides new processing thinking and scheme, has overcome current processing technology's weak point, and the actual operation of demonstration engineering proves, and this technology operation is stable, energy-conserving, high-efficient, marsh gas output is high, methane content is high in the marsh gas, the treatment effeciency is high, save anaerobic reactor investment, has wide market perspective.
Drawings
Fig. 1 is a schematic structural diagram of the two-stage anaerobic treatment device for the feces of the large-scale pig raising of the utility model.
FIG. 2 is a schematic diagram of the second-stage fully-mixed intermittent stirring intermediate-temperature anaerobic reactor shown in FIG. 1.
FIG. 3 is a schematic structural view of the one-stage fully-mixed intermittent stirring high-temperature anaerobic reactor shown in FIG. 1.
FIG. 4 is a schematic structural diagram of the secondary mesophilic anaerobic discharge surge tank of FIG. 1.
Reference numbers in the figures: 1 is a feces storage tank, 2 is a secondary solid feces separator, 3 is a transmission mechanism, 4 is a sedimentation tank, 5 is a separated wastewater treatment system, 6 is a material homogenization adjusting tank, 7 is a primary fully-mixed type intermittent stirring high-temperature anaerobic reactor, 701 is a sealed structure, 8 is a secondary fully-mixed type intermittent stirring medium-temperature anaerobic reactor, 801 is a stirring slag breaking mixing propeller, 802 is an air vent, 803 is a second heat insulation layer, 804 is a methane storage cabinet structure, 805 is a side stirring propeller, 806 is a bottom sand settling tank, 807 is a water seal pipe, 808 is a waste gas discharge pipe, 809 is an overflow outlet after anaerobic treatment, 810 is a methane outlet, 9 is a secondary anaerobic medium-temperature discharge buffer tank, 901 is a discharge port, 902 is a second temperature sensor, 903 is a material mixing stirrer, 10 is a high-temperature anaerobic temperature guarantee system, 11 is a third plate type heat exchanger, 12 is a secondary medium-temperature anaerobic discharge heat energy recovery system, 13 is a water source heat pump, 14 is a first plate heat exchanger, 15 is a trace element methane yield-increasing nutrient salt adding system, 16 is a methane purification and utilization system, 17 is an air source high-temperature heat pump, 18 is a second plate heat exchanger, 19 is a fourth plate heat exchanger, 20 is a material homogenization adjusting tank preheating system, and 21 is a primary high-temperature anaerobic discharge heat energy recovery system.
Detailed Description
The invention will be further described with reference to the following examples and the accompanying drawings. The described embodiments are only some, but not all embodiments of the invention. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.
In the description of the present invention, it is to be understood that the terms "exterior", "bottom", "top", "side", and the like, indicate positional or positional relationships and are used merely for convenience in describing the present invention and to simplify the description, but do not indicate or imply that the components or elements so referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the invention.
Referring to fig. 1 and 4, the utility model discloses a two-stage anaerobic treatment device for feces in large-scale pig raising, which comprises a two-stage solid feces separator 2, a material homogenizing adjusting tank 6, a one-stage full-mixing type intermittent stirring high-temperature anaerobic reactor 7, a two-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor 8, a two-stage medium-temperature anaerobic discharge buffer tank 9, an air source high-temperature heat pump 17, a water source heat pump 13, a first plate heat exchanger 14, a second plate heat exchanger 18, a third plate heat exchanger 11 and a fourth plate heat exchanger 19;
the second-stage solid manure separator 2 adopts a rotary drum type pig manure dry-temperature separator for twice separation;
the material homogeneity adjusting tank 6 adopts an adjusting tank which is externally provided with a heat-insulating layer and internally provided with a stirrer and a thermometer;
the second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor 8 adopts an intermittent stirring mixing anaerobic reactor which is provided with a stirring slag breaking mixing propeller 801 at the upper inner side, side stirring propellers 805 symmetrically arranged at the lower inner side and having vortex prevention and scum layer destruction effects and a second heat insulation layer 803 at the outer part; the top of the biogas storage cabinet adopts a biogas storage cabinet structure 804, the bottom side of the biogas storage cabinet is provided with a vent 802, and the outer bottom of the biogas storage cabinet is provided with a bottom grit chamber 806;
the difference between the primary fully-mixed intermittent stirring high-temperature anaerobic reactor 7 and the secondary fully-mixed intermittent stirring medium-temperature anaerobic reactor 8 is that the top part adopts a sealed structure 701;
solid manure part after solid-liquid separation of the second-stage solid manure separator 2 is conveyed to an inlet at the top of a material homogenizing adjusting tank 6 to enter the interior, manure water after solid-liquid separation is divided into two paths, one path is used for conveying deposited partial manure which is not subjected to solid manure separation to the material homogenizing adjusting tank 6 through a pipeline from the bottom of a sedimentation tank 4 to adjust the material concentration in the homogenizing adjusting tank, and the other path is used for conveying separated manure water precipitated by the sedimentation tank 4 to a separated waste water treatment system 5 and conveying partial manure water to the material homogenizing adjusting tank 6 through pipelines to adjust the material concentration in the homogenizing adjusting tank; the top of the material homogenizing adjusting tank 6 is connected with a trace element methane yield-increasing nutrient salt adding system 15 through a pipeline; the material after the quality adjustment in the material homogeneity adjusting tank 6 enters a first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor 7 through a pipeline; the primary full-mixing type intermittent stirring high-temperature anaerobic reactor 7 is of a full-closed structure, and a 50mm polyurethane foam heat-insulating layer and a color steel plate are arranged outside the reactor; the top of the first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor 7 is provided with a high-temperature pressure system biogas discharge pipeline connected with a biogas purification and utilization system 16 and a high-temperature anaerobic temperature guarantee system 10 formed by the heat mutual connection of a second plate heat exchanger 18 and an air source high-temperature heat pump 17 through pipelines; the side part of the first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor 7 is connected with a second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor 8 through a third plate heat exchanger 11 by a pipeline; the top of the second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor 8 is connected with a methane purification and utilization system 16 through a pipeline; the side part of the second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor 8 is connected with a second-stage medium-temperature anaerobic discharge buffer tank 9 through a pipeline; the bottom of the second-stage medium-temperature anaerobic discharge buffer tank 9 is in thermal circulation interactive connection with the fourth plate heat exchanger 19 through a pipeline, and a discharge hole 901 after anaerobic treatment is formed in the side part of the second-stage medium-temperature anaerobic discharge buffer tank 9; the first plate heat exchanger 14, the third plate heat exchanger 11 and the fourth plate heat exchanger 19 are respectively connected with the water source heat pump 13 through circulating pipelines.
Wherein, the upper side part of the second-stage complete mixing type intermittent stirring medium temperature anaerobic reactor 8 is branched by a water seal pipe 807 and connected with a top waste gas discharge pipe 808 and an overflow outlet 809 after anaerobic treatment; is connected with the biogas purification and utilization system 16 through a biogas outlet 810 arranged at the top.
The biogas purification and utilization system 16 is used for conveying biogas generated by the primary high-temperature anaerobic treatment and biogas generated by the secondary medium-temperature anaerobic treatment to the biogas purification and utilization system 16, and the biogas can be used for preheating mixed materials in the homogenizing adjusting tank by steam generated by a biogas steam boiler so as to save the cost of the heating system.
Wherein, the water source heat pump 13 is used for recovering the heat energy in the first-stage high-temperature anaerobic system discharging and the second-stage medium-temperature anaerobic discharging so as to heat the anaerobic system feeding, thereby achieving the purpose of saving the heating cost.
The high-temperature anaerobic temperature guaranteeing system 10 has a very strict temperature range required by the high-temperature anaerobic process compared with the medium-temperature anaerobic process, the temperature required by normal operation is 52-55 ℃, and the anaerobic treatment efficiency is rapidly reduced when the temperature is lower than 50 ℃ or higher than 57 ℃, so that the temperature guaranteeing system is very important for the high-temperature anaerobic process; the utility model discloses the technology does not adopt the mode of other heats, like electrical heating, steam heating, solar heating etc. because there is the problem that the heating cost is high or efficient in the heating methods of this type, the utility model discloses the novelty provides and adopts air source high temperature heat pump system to heat the material, opens through opening of the temperature sensor control air source high temperature heat pump that sets up in the high temperature reaction simultaneously and stops. The high-temperature anaerobic guarantee system comprises a high-temperature air source heat pump and a plate type heat exchange system which are used and prepared.
Wherein, the drum-type pig manure dry-warm separator for twice separation is provided with a coarse filter screen for once separation by coarse filtration of 40-60 meshes, and a fine separation filter screen for twice separation by fine filtration of 300-400 meshes.
Wherein, the separated wastewater treatment system 5 adopts an up-flow anaerobic sludge blanket UASB or a black film methane tank anaerobic system; the separated wastewater can adopt an optimal Munsen environment membrane coupling up-flow anaerobic sludge blanket process (MCUASB), and the invention patent publication numbers thereof are as follows: CN 111470623A, or other conventional UASB or black film biogas processes, and performing anaerobic treatment and subsequent aerobic biochemical treatment which may be required.
Wherein, the second-stage medium temperature anaerobic discharging buffer tank 9 adopts a buffer tank structure with a material mixing stirrer 903 and a second temperature sensor 902 arranged inside, and the side part is provided with a buffer tank structure of a discharging port 901 after anaerobic treatment.
Wherein, the microelement methane yield-increasing nutrient salt adding system 15 adopts a system which dissolves nutrient salt under the acid condition and adds the nutrient salt through a dosing pump; a large number of researches and practices prove that for large-scale pig raising, anaerobic fermentation is carried out on high solid manure-containing sewage, the activity of anaerobic microorganisms and the treatment efficiency of an anaerobic system can be improved by adding trace elements such as iron, cobalt, nickel, calcium, magnesium, molybdenum and the like, and meanwhile, compared with a system without adding the nutrient salts, the biogas yield can be improved by more than 10%. The utility model discloses the technology novelty proposes to add the microorganism growth promoter that can promote anaerobic microorganism to grow in the dirty anaerobic treatment system of high solid content rate excrement to improve anaerobic system's treatment effeciency and marsh gas output. The nutrient salt will be added to the material homogenization conditioning tank 6.
The first plate heat exchanger 14, the water source heat pump 13 and a connected circulation pipeline form a material homogenizing adjusting tank preheating system 20, the third plate heat exchanger 11, the water source heat pump 13 and a connected circulation pipeline form a primary high-temperature anaerobic discharging heat energy recovery system 21, and the fourth plate heat exchanger 19, the water source heat pump 13 and a connected circulation pipeline form a secondary medium-temperature anaerobic discharging heat energy recovery system 12.
Wherein, the first-stage high-temperature anaerobic discharge heat energy recovery system 21 can enter a subsequent medium-temperature anaerobic system only after cooling due to the high temperature (52-55 ℃) of the high-temperature anaerobic discharge. Therefore, the process innovatively provides that a water source heat pump heat energy recovery system is adopted, the high-temperature anaerobic treatment temperature is reduced to (30-35 ℃) through the water source heat pump heat exchange system, the temperature of discharged materials is reduced, and the recovered heat energy is used for preheating mixed excrement in the material homogenizing adjusting tank 6, so that the operating cost of the high-temperature anaerobic temperature guaranteeing heat pump system is reduced. The cooled material automatically flows to a secondary full-mixing type intermittent stirring medium-temperature anaerobic reactor under the action of gravity to perform medium-temperature anaerobic treatment; the primary high-temperature anaerobic discharge heat energy recovery system consists of a heat exchanger and a water source heat pump system.
The second plate heat exchanger 18, the air source high-temperature heat pump 17 and the connected circulating pipeline form a high-temperature anaerobic temperature guarantee system 10.
Wherein, discharging after anaerobic treatment: the discharged material treated by the process is separated into biogas residue and biogas slurry by solid-liquid separation equipment, the biogas residue and organic wastes such as straws and the like can be subjected to combined composting to prepare efficient organic fertilizer, the biogas slurry can enter a large biogas slurry stable storage tank for stabilization and then is returned to the field, or is mixed with other biogas slurry for advanced treatment such as aerobic biochemical treatment and the like, so as to meet the required discharge requirement.
The working process of the large-scale pig-raising excrement two-stage anaerobic treatment device is as follows:
s01, feeding the feces mixed liquid discharged from the pigsty into a feces storage pool 1, and conveying the feces mixed liquid to a secondary solid-feces separator 2 through a conveying mechanism for secondary solid-liquid separation; the method comprises the following steps that (1) excrement mixed liquid discharged from a pigsty enters an excrement storage pool 1, a stirrer for preventing solid precipitation is generally arranged in the pool, and the solid content of the excrement mixed liquid is generally 2-3%; one part of the feces mixed liquid enters a subsequent material homogenizing and adjusting tank 6, the other part of the feces mixed liquid enters a secondary solid feces separator 2, and the separated solid feces and part of the original feces enter the material homogenizing and adjusting tank 6;
s02, solid manure with a solid content of 25-30% separated by the secondary solid manure separator 2 and part of raw manure enter a material homogenizing and adjusting tank 6 through a conveying mechanism 3 for homogenizing and adjusting, the separated manure with suspended matters smaller than 3000mg/L is divided into two paths, one path is used for conveying the precipitated part of the manure without the separated solid manure to the material homogenizing and adjusting tank 6 through a pipeline from the bottom of a sedimentation tank 4, and the other path is used for conveying the separated part of the manure on the upper part of the solid manure precipitated by the sedimentation tank 4 to a separated waste water treatment system 5 and part of the separated part of the manure to the material homogenizing and adjusting tank 6 through pipelines; meanwhile, a yield-increasing nutrient salt is added into the material homogenization adjusting tank 6 by a trace element biogas yield-increasing nutrient salt adding system 15 for iron, cobalt, nickel, calcium, magnesium and molybdenum, part of the excrement sewage which is not separated into solid excrement and the solid excrement separated by the secondary solid excrement separator 2 are mixed and homogenized in the material homogenization adjusting tank 6, and the material concentration is adjusted to about 5-8% of solid content; wherein, the material homogeneity adjusting tank preheating system 20 transfers the heat energy to the circulating water system of the water source heat pump 13, the anaerobic discharging temperature is reduced, and the circulating water temperature is increased; the circulating water with the increased temperature transfers the heat energy in the circulating water to the material in the material homogenizing and adjusting tank 6, so that the temperature of the fed material is increased, namely the fed material is preheated; wherein the solid content of the separated solid manure is generally 25-30%, the crude solid manure contains more pig hair, volatile organic matters in the solid manure account for about 60-65% of the total solid, and the volatile organic matters in the separated fine solid manure account for about 80-85% of the total solid; homogenizing and adjusting the separated solid manure and part of the original manure in a material homogenizing and adjusting tank 6, and adjusting the solid content of the material in the material homogenizing and adjusting tank 6 to about 5-8% to be used as a high-temperature and medium-temperature two-stage anaerobic feeding material; the dissolubility COD of the separated waste water is about 12000-15000 mg/L under the normal condition, and the suspended substance TSS: 1500-2500 mg/L, TN: 1200-1500 mg/L, NH4 is N: 600-800 mg/L, TP: 100-200 mg/L;
s03, feeding the material tempered by the material homogenizing adjusting tank 6 into a first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor 7 through a pipeline, and performing first-stage high-temperature anaerobic treatment at the normal operation temperature of 52-55 ℃; wherein, the high-temperature anaerobic temperature guarantee system 10 is used for high-temperature anaerobic temperature guarantee, and the primary high-temperature anaerobic discharge heat energy recovery system 21 is used for primary heat energy recovery; purifying and utilizing the biogas generated by the primary full-mixing type intermittent stirring high-temperature anaerobic reactor 7 by a biogas purification and utilization system 16; the material homogenizing adjusting tank 6 is used for mixing and homogenizing part of excrement sewage which is not subjected to solid excrement separation and solid excrement separated by the solid-liquid separator, and adjusting the material concentration to about 5-8% of solid content; the material adjusting tank is provided with a heat preservation measure, and a stirrer is arranged in the material adjusting tank to homogenize and imitate the precipitation of solid matters; feeding the homogenized material to a subsequent anaerobic system in an intermittent manner, wherein the conventional feeding period is 3-6 hours, namely, feeding is carried out for 4-8 times every day;
s04, conveying the sewage subjected to the primary high-temperature oxidation treatment to a secondary full-mixing type intermittent stirring intermediate-temperature anaerobic reactor 8 by a primary full-mixing type intermittent stirring high-temperature anaerobic reactor 7 through a third plate heat exchanger 11, performing secondary intermediate-temperature anaerobic treatment at the normal operation temperature of 30-35 ℃, reducing the temperature of the discharged material to about 10-25 ℃ by a secondary intermediate-temperature anaerobic discharged material heat energy recovery system 12, and further recovering heat energy in the discharged material; biogas in the materials is released to the top of the reactor and is stored by a biogas storage cabinet structure 801 arranged at the top, so that the functions of further degrading organic pollutants and degassing the materials are synchronously realized; wherein, the material after tempering enters a first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor 7, a side stirring plug flow system, an anti-vortex system and a scum layer damage system thereof are arranged in the reactor, a heat preservation measure is arranged outside, the Organic Load (OLR) is designed to be 2-6 kgCOD/m3.d conventionally, and the hydraulic retention time HRT is about 14 days; the normal operation temperature is 52-55 ℃, more than 75-80% of anaerobic degradable organic matters are rapidly degraded in the high-temperature anaerobic treatment section, meanwhile, the killing rate of pathogenic bacteria is higher than 99%, the methane content in the anaerobically generated biogas is 15-20% higher than that in the conventional medium-temperature anaerobic treatment, the anaerobic reaction rate is faster than that in the medium-temperature anaerobic treatment, and therefore the volume of the whole anaerobic treatment system can be reduced by about 30%; the secondary full-mixing type intermittent stirring medium temperature anaerobic reactor 8 is used for further degrading organic pollutants which cannot be completely degraded in the material by medium temperature anaerobic process by further utilizing the stability advantage of the medium temperature anaerobic process; an intermittent side stirring system, a vortex prevention system and a scum layer damage prevention system are arranged in the medium-temperature full-mixing type intermittent stirring anaerobic reactor, and a heat preservation measure is arranged outside the reactor; meanwhile, as the reactor is provided with a shorter stirring period, the biogas in the materials can be further released to the top of the reactor and is stored by a double-film biogas pressure-stabilizing storage cabinet arranged at the top, so that the functions of further degrading organic pollutants and degassing the materials are synchronously realized; a double-membrane biogas storage cabinet arranged at the top of the reactor is provided with a biogas pressure sensor, and the start and stop of subsequent biogas utilization facilities are realized through pressure control;
s05, connecting the side part of the secondary full-mixing type intermittent stirring medium temperature anaerobic reactor 8 with a secondary medium temperature anaerobic discharge buffer tank 9 through a pipeline, and buffering heat energy recovery in medium temperature anaerobic discharge; wherein, the second-stage medium-temperature anaerobic discharge buffer tank 9 is provided with a heat preservation measure; the whole anaerobic system is in intermittent feeding and intermittent discharging.
Example (c):
the embodiment of the utility model is the first demonstration project for treating the large-scale pig raising manure by adopting a high-temperature and medium-temperature two-stage anaerobic process system in China. The project is located in a certain scale pig raising factory of a herding group.
Exemplary engineering scales and parameters are as follows:
raw materials | Material amount (t/d) | TS(%) | Organic matter (%, account for VS) |
Mixture of manure and |
20 | 6 | 80 |
Table 1: demonstration of engineering design scales and parameters
The exemplary project builds the following structures:
1、10m3stirring, heat-preserving homogenizing and adjusting tank;
2、280m3a first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor;
3、140m3a secondary full-mixing type intermittent stirring medium-temperature anaerobic reactor, wherein a double-membrane methane storage cabinet is arranged at the top of the reactor;
4. a secondary full-mixing type intermittent stirring medium-temperature anaerobic discharging buffer tank with stirring and heat preservation functions;
5. a primary full-mixing type intermittent stirring high-temperature anaerobic temperature guarantee vegetable air source high-temperature heat pump heating system;
5. a water source heat pump heat energy recovery system for recovering heat energy of the primary fully-mixed intermittent stirring high-temperature anaerobic discharge and the secondary fully-mixed intermittent stirring medium-temperature anaerobic discharge;
6. discharge heat energy recovery preheats homogeneity adjusting tank mixing material system.
The anaerobic system for high-temperature and medium-temperature anaerobic treatment adopts a fully-mixed intermittent stirring anaerobic reactor system, and the operation is as follows:
preferably, solid manure which is subjected to solid-liquid separation in a plant area and manure which is not subjected to solid-liquid separation are used, the solid content of the material is adjusted to be 6% in a homogenizing adjusting tank, and the mixed material in the homogenizing adjusting tank is preheated through heat energy recovered by one-stage full-mixing type intermittent stirring high-temperature anaerobic discharge and heat energy recovered by two-stage full-mixing type intermittent stirring medium-temperature anaerobic discharge.
The tempered and preheated material is pumped to a first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor system under the action of a feed pump, organic solid manure and soluble COD in the material are hydrolyzed and degraded into water, carbon dioxide and methane under the action of high-temperature anaerobic microorganisms, the anaerobic degradation rate of organic matters in the solid manure is about 45-50%, and the anaerobic degradation rate of the soluble COD is about 75%. Designed first-level full-mixing type intermittent stirring effective volume of 280m3The hydraulic retention time is about 14 days, the operating temperature of the anaerobic reactor is 52-55 ℃, and the operating temperature is guaranteed through an air source high-temperature heat pump heating system.
The material after the first-stage high-temperature anaerobic treatment automatically flows to a second-stage medium-temperature anaerobic treatment system under the action of gravity after heat exchange of a water source heat pump, and the designed second-stage medium-temperature effective volume is 140m3The hydraulic retention time is 7 days, and the operation temperature is about 35 ℃.
After the first-stage high-temperature anaerobic treatment and the second-stage medium-temperature anaerobic treatment, the degradation rate of solid manure in the manure and sewage mixed material is about 50-55%, the degradation rate of soluble COD is 80-85%, and the degradation rate of volatile organic compounds in the solid manure is about 70-80%. 20m3Production of 538Nm methane from manure and sewage mixed material with 6% solid content3The methane yield per unit of material is 26.9Nm3Per ton of material.
Composting the biogas residues after two-stage anaerobic treatment, discharging biogas slurry into the existing black film biogas slurry storage pool, and discharging biogas generated by anaerobic treatment into the existing biogas storage cabinet.
Has the advantages that:
1. the utility model discloses a dirty two-stage anaerobic treatment method of scale pig raising excrement and device adopt innovative high temperature + middle temperature two-stage anaerobic treatment technology to be used for handling the dirty mixed excrement of scale pig raising factory, have solved not enough among the prior art practical application of processing, have improved the dirty treatment effeciency of excrement greatly, and this novel processing method's innovation point and advantage lie in: (1) the first domestic project of treating the large-scale pig raising excrement by adopting a high-temperature and medium-temperature two-stage anaerobic process builds a daily treatment capacity of 20m3Exemplary engineering of/d; (2) the first-stage anaerobic process adopts a high-temperature anaerobic process, so that the reaction rate is high, the retention time is short, and the investment can be reduced; (3) the first-stage high-temperature anaerobic section can degrade most organic pollutants (COD 75%, TSS 45-50%), the methane content in the methane generated by the high-temperature anaerobic process is 5-15% higher than that in the methane generated by the medium-temperature anaerobic process, and the total yield of the methane is 10-15%; (5) the air source heat pump high-temperature anaerobic temperature guarantee system, the water source heat pump high-temperature anaerobic system discharge and the medium-temperature anaerobic system discharge heat energy are innovatively adopted for heating the tempered mixed material, the heating cost of the high-temperature anaerobic system and the operation cost of the whole system can be greatly saved, and the system can still efficiently operate under the low-temperature condition in winter, so that the system has great advantages compared with the actual situation that most anaerobic systems for treating feces cannot normally operate under the low-temperature condition in winter in China; (6) and a system for adding the nutrient salt for increasing the yield of the biogas by using the trace elements of iron, cobalt, nickel, calcium, magnesium and molybdenum is innovatively adopted, so that the biogas yield of the process is improved by 15-20%.
2. With the increasing of domestic large-scale pig farm construction, the process provides a new treatment idea and scheme for the feces of newly-built or existing large-scale pig farms, overcomes the defects of the existing treatment process, and the actual operation of demonstration engineering proves that the process is stable in operation, energy-saving, efficient, high in biogas yield, high in methane content in the biogas, high in treatment efficiency, capable of saving the investment of an anaerobic reactor, and wide in market application prospect.
The preferred embodiments of the present invention disclosed above are intended only to help illustrate the present invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best understand the invention for and utilize the invention. The present invention is limited only by the claims and their full scope and equivalents.
Claims (4)
1. A large-scale pig raising manure two-stage anaerobic treatment device is characterized by comprising a two-stage solid manure separator, a material homogenizing adjusting tank, a sedimentation tank, a first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor, a second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor, a trace element methane yield-increasing nutritive salt adding system, a second-stage medium-temperature anaerobic discharging buffer tank, an air source high-temperature heat pump, a water source heat pump, a first plate heat exchanger, a second plate heat exchanger, a third plate heat exchanger and a fourth plate heat exchanger; wherein:
the second-stage solid manure separator adopts a rotary drum type pig manure dry-temperature separator for twice separation; the device is used for separating solid manure from sewage from the manure storage pool;
the material homogenizing adjusting tank is internally provided with a stirrer and a thermometer, and the outer part of the material homogenizing adjusting tank is provided with a heat-insulating layer; used for adjusting the concentration of the excrement;
the sedimentation tank is used for settling the excrement;
the upper part of the inner side of the two-stage full-mixing type intermittent stirring high-temperature anaerobic reactor is provided with a stirring, slag breaking and mixing propeller, the lower part of the inner side is symmetrically provided with stirring propellers, and the stirring propellers have the functions of preventing vortex and destroying a scum layer; the outside of the heat-insulating layer is provided with a heat-insulating layer; the top of the biogas storage cabinet adopts a biogas storage cabinet structure; the side surface of the bottom of the sand tank is provided with a vent, and the bottom of the sand tank is externally provided with a sand setting groove;
the primary full-mixing type intermittent stirring high-temperature anaerobic reactor is structurally different from the secondary full-mixing type intermittent stirring high-temperature anaerobic reactor in that the top of the primary full-mixing type intermittent stirring high-temperature anaerobic reactor is of a sealed structure, and the rest structures are the same;
the second-stage medium-temperature anaerobic discharging buffer tank is internally provided with a material mixing stirrer and a second temperature sensor, and the side part of the second-stage medium-temperature anaerobic discharging buffer tank is provided with a discharging hole after anaerobic treatment;
the trace element methane yield-increasing nutrient salt adding system is connected with the middle top of the material homogenization adjusting tank through a pipeline and is used for adding trace element nutrient solution into the material homogenization adjusting tank;
the first plate heat exchanger, the water source heat pump and the connected circulating pipeline form a preheating system of the material homogenizing adjusting tank;
the third plate heat exchanger, the water source heat pump and the connected circulating pipeline form a primary high-temperature anaerobic discharging heat energy recovery system,
the fourth plate heat exchanger, the water source heat pump and the connected circulating pipeline form a secondary medium-temperature anaerobic discharging heat energy recovery system;
the second plate heat exchanger, the air source high-temperature heat pump and the connected circulating pipeline form a temperature guarantee system of the primary high-temperature anaerobic system;
the excrement in the excrement storage pool is subjected to solid-liquid separation through a secondary excrement-solid separator; part of solid manure and part of original manure separated by the secondary solid manure separator enter a material homogenizing adjusting tank through a conveying mechanism for homogenizing adjustment; separating the excrement with smaller suspended matters into two paths, wherein one path of the excrement with smaller suspended matters enters a sedimentation tank, part of the excrement which is precipitated at the bottom of the sedimentation tank and is not separated from solid excrement is conveyed into a material homogenization adjusting tank through a pipeline, the other path of the excrement is used for conveying one part of the excrement on the upper part of the solid excrement which is precipitated in the sedimentation tank after separation into a separated waste water treatment system through a pipeline, and the other part of the excrement is conveyed into the material homogenization adjusting tank so as to adjust the material concentration in the tank;
the material after being tempered in the material homogeneity adjusting tank enters a first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor through a pipeline; the top of the first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor is provided with a high-temperature pressure system biogas discharge pipeline connected with a biogas purification and utilization system and a high-temperature anaerobic temperature guarantee system formed by the heat exchange and interconnection of a second plate heat exchanger and an air source high-temperature heat pump through pipelines;
the side part of the first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor is connected with the second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor through a third plate heat exchanger by a pipeline; the top parts of the first-stage full-mixing type intermittent stirring high-temperature anaerobic reactor and the second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor are connected with a methane purification and utilization system through pipelines;
the side part of the second-stage full-mixing type intermittent stirring medium-temperature anaerobic reactor is connected with a second-stage medium-temperature anaerobic discharge buffer tank through a pipeline; the bottom of the second-stage medium-temperature anaerobic discharge buffer tank is in thermal circulation interactive connection with a fourth plate heat exchanger through a pipeline; a discharge hole after anaerobic treatment is formed in the side part of the second-stage medium-temperature anaerobic discharge buffer tank;
the upper side part of the secondary full-mixing type intermittent stirring medium-temperature anaerobic reactor is connected with a top waste gas discharge pipe and an overflow outlet after anaerobic treatment in a branching way through a water seal pipe; is connected with an external methane purification and utilization system through a methane outlet arranged at the top.
2. The two-stage anaerobic treatment device for feces produced by large-scale pig raising according to claim 1, wherein in the drum-type dry-warm separating machine for twice-separation of pig feces, a coarse filter screen for 40-60 mesh coarse filtration is used for the first separation, and a fine filter screen for 300-400 mesh fine filtration is used for the second separation.
3. The two-stage anaerobic treatment device for large-scale pig raising manure and sewage according to claim 1, wherein the post-separation wastewater treatment system adopts an Upflow Anaerobic Sludge Blanket (UASB) or a black film methane tank anaerobic system.
4. The two-stage anaerobic treatment device for feces and sewage in scale pig raising according to claim 1, wherein the system for adding microelement methane yield-increasing nutritive salt comprises a liquid adding pump, a container and related pipelines, wherein the system for adding microelement nutritive salt dissolves the microelement nutritive salt under acidic conditions, and liquid medicine is added by the liquid adding pump; here, the trace elements include iron, cobalt, nickel, calcium, magnesium, molybdenum.
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CN112624542A (en) * | 2020-12-13 | 2021-04-09 | 复旦大学 | Large-scale pig raising excrement two-stage anaerobic treatment device and method |
CN112624542B (en) * | 2020-12-13 | 2024-10-29 | 复旦大学 | Large-scale pig manure two-stage anaerobic treatment device and method |
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CN112624542B (en) * | 2020-12-13 | 2024-10-29 | 复旦大学 | Large-scale pig manure two-stage anaerobic treatment device and method |
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