JP6714194B1 - Equipment for Organic Fertilizer Production by Energy Chemical Engineering Cogeneration for Livestock and Poultry Feces - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an organic fertilizer production facility by energy chemical engineering cogeneration for livestock and poultry feces. SOLUTION: The stool collection tank 1, an aerobic fermentation tank 2, an anaerobic reaction chamber 3, a biogas collection device 4, and a control box 6 for controlling the entire equipment are included. A stacking device 21 for making livestock and poultry feces into a longitudinal shape, and a ventilation device 22 for ventilation are provided inside the anaerobic reaction chamber. A solid-liquid separation device 31 for separating the slurry is provided, and a biogas treatment device 41 for dehydrating, removing dust, and desulfurizing the biogas generated in the anaerobic reaction chamber is provided inside the biogas collection device. A facility for producing organic fertilizer by energy chemical engineering cogeneration for livestock and poultry feces, which is characterized by: [Selection diagram] Figure 1

Description

TECHNICAL FIELD The present invention relates to an organic fertilizer production facility by energy chemical engineering cogeneration for livestock and poultry feces.

In recent years, China's rural livestock and poultry breeding industry has developed rapidly, with family households and large enterprises. The livestock and poultry meat products produced greatly enhance the food and drink of urban and rural residents. However, livestock and poultry breeding, especially scaled breeding, can produce more feces and sewage, which, if not properly managed, can cause environmental pollution around the farm and can cause large numbers of mosquito breeding. , Could pollute surrounding water sources and seriously limit sustainable development of the livestock and poultry breeding industry.

Currently, there are two methods for treating livestock and poultry feces in the prior art, one is to compost livestock and poultry feces, the disadvantages are large floor area, long cycle and upside down. The present invention requires two methods because the anaerobic fermentation is expensive but the cost of the anaerobic fermentation process is high and odorous gas is generated. In combination, it will provide an organic fertilizer production facility by energy chemical engineering cogeneration for livestock and poultry faeces.

In view of the above existing problems, the present invention provides a facility for producing organic fertilizer by energy chemical engineering cogeneration for livestock and poultry feces.

The technical solution of the present invention is an organic fertilizer production facility by energy chemical engineering cogeneration for livestock and poultry feces, which comprises:
A faecal collection tank,
An aerobic fermentation tank connected to a faecal collection tank for sterilization of livestock and poultry feces, a stacking device for forming livestock and poultry feces into a longitudinal shape, and a ventilation device for ventilation The
An anaerobic reaction chamber connected to an aerobic fermentation tank for decomposing livestock and poultry faeces to prepare biogas and organic fertilizer, inside which a livestock and poultry faeces are rotated back and forth to produce biogas slurry. A solid-liquid separation device for separation is provided,
A biogas slurry collection tank below the solid-liquid separator to collect the biogas slurry,
A spray device connected to the biogas slurry collection tank by a lift pump for spraying the separated biogas slurry on livestock and poultry faeces,
A biogas collection device controlled in the anaerobic reaction chamber, and a biogas treatment device for dehydrating, removing dust, and desulfurizing the biogas generated in the anaerobic reaction chamber are provided therein.
And the control box for controlling the whole installation is included.

In the above solving means, in the fecal collection tank,
A sieve plate at the entrance to sort out large pieces of livestock and poultry faeces,
A moisture meter inside the faecal collection tank to monitor the water content of livestock and poultry feces,
A supply tank above the faecal collection tank for adjusting the water content of livestock and poultry feces,
An agitator located in the fecal collection tank for agitating the feces.
In the above solution means, the stacking device,
A supply hopper and a metering conveyor connected to the lower end of the storage hopper above the aerobic fermentation tank for supplying and monitoring the supply,
A truck at the top inside of the aerobic fermentation tank,
A stacking groove slidably provided on the track by a load-bearing arm,
Here, the stacking groove communicates with the metering conveyor and is used for stacking livestock and poultry feces in the storage hopper to the elongated shape compost in the aerobic fermentation tank, and the load-bearing arms are connected via the hydraulic telescopic rod. Connected to the stacking groove and used to control the raising and lowering of the stacking groove, it is possible to stack livestock and poultry feces without manual work,
To save time and labor, a capsize device is provided inside the stacking ditch to capsize the compost, livestock and poultry faeces should be capsized for uniform fermentation of the livestock and poultry faeces during composting, The device can automatically capsize without destroying the compost shape.

In the above solving means, in the aerobic fermentation tank,
The heat exchanger further includes an internal heat exchanger, and the heat radiating end of the heat exchanger communicates with the inside of the biogas collection tank to transfer the heat generated in the aerobic fermentation tank to the biogas collection tank, thereby forming a biogas slurry. Used to spray the anaerobic reaction chamber through the spray device after heating, increasing the number and growth rate of methanogens in the fermentate, converting the heat generated in the aerobic fermentation tank It is used for utilization, eco-friendly, and the heating equipment of biogas recovery tank is omitted, which saves cost.

In the above solution means, the solid-liquid separation device,
An inverted V-shaped conveyor belt and a sieve hole for separating the biogas slurry are provided on the conveyor belt,
A differential motor for driving the conveyor belt.

In the above solving means, a fertilizer production device for converting the biogas residue produced in the anaerobic reaction chamber into organic fertilizer is connected to the outlet of the anaerobic reaction chamber, and the fertilizer production device is configured to remove biogas residue. A drying device for dehydrating the product, and a granulating device for granulating the dehydrated biogas residue into organic fertilizer particles are included.

In the above solution, the exhaust ports of the fecal collection tank and the aerobic fermentation tank are each connected to the biogas treatment device.

Further, the biogas treatment device is connected to the biogas collection tank, and sends the separated liquid to the biogas collection tank for reuse, thereby avoiding the processing discharge of the separated liquid and forming a recycling. ..
The operating principle of the present invention is as follows.

Farm livestock and poultry faeces are screened to remove large debris and then sent to a faecal collection tank, moisture analyzer monitors the water content of livestock and poultry faeces and adjusts the water content of livestock and poultry feces In order to control the feed tank to adjust the water content of livestock and poultry feces by adding dry material to the faecal collection tank by the control box, the agitator continuously agitates and adjusts during the addition process. After completion of feeding, the feed machine pulls livestock and poultry feces into the storage hopper of the aerobic fermentation tank, and after the stacking groove is moved to the proper position on the truck by the load-bearing arm, the hydraulic telescopic rod is aerobic fermented The stacking groove is placed on the bottom of the tank, the quantitative conveyor opens, and the livestock and poultry feces in the storage hopper are transported to the stacking groove, the capsizing device keeps overturning during the transportation process, and the livestock and poultry feces are aerobic fermentation tank. Stacked on the bottom of the plant, it grows into a longitudinal compost for aerobic fermentation and is continuously ventilated by a ventilator during the fermentation process to supply the oxygen required for aerobic fermentation, completing the aerobic fermentation. After that, the livestock and poultry feces are pulled up to the anaerobic reaction chamber by the feeder, the differential motor of the solid-liquid separator periodically performs periodic reversal, drives the conveyor belt for reciprocating motion, and And poultry feces are inverted on the conveyor belt by the action of gravity, the biogas slurry contained in livestock and poultry feces is flowed from the sieve hole to the biogas slurry collection tank, and a large amount of livestock and poultry feces are generated during the aerobic fermentation process. Of heat, which is collected from the endothermic end of the heat exchange device located on the inner wall of the aerobic fermentation tank, and then the heat radiating end of the heat exchange device heats the biogas slurry in the biogas collection tank. Then, the heated biogas slurry is lifted by a lift pump to a spray device and sprayed on livestock and poultry feces in the anaerobic reaction chamber to increase the number and breeding rate of methanogens in fermented livestock and poultry feces. After the anaerobic reaction is completed, the biogas residue enters the fertilizer production equipment to be dried and granulated to produce organic fertilizer, and the produced biogas is dehydrated, dedusted and desulfurized by the biogas treatment equipment. Enter the biogas collector for power generation and gas supply.

The beneficial effects of the present invention are as follows.
The production facility of the organic fertilizer by the energy chemical engineering cogeneration for livestock and poultry feces provided by the present invention, after adjusting the water content for the collected livestock and poultry feces, first, aerobic fermentation, stacking The placement of the device automatically stacks livestock and poultry faeces into a longitudinal shape, and a capping device is placed inside the stacking device to adjust the shape during composting as well as composting during the aerobic fermentation process. The endothermic end of the heat exchange device is placed in the aerobic fermentation tank at the same time, and the heat generated in the anaerobic fermentation is used to heat the biogas slurry in the anaerobic reaction chamber, utilizing the waste heat. The solid-liquid separator is installed in the anaerobic reaction tank to separate the biogas slurry in livestock and poultry feces by gravity, and at the same time, the spray device is installed to anaerobically heat the biogas slurry. Re-spray the reaction chamber to increase the number of methane bacteria and the regeneration rate of fermentation. In summary, the present invention has advantages such as easy to produce, high efficiency, energy saving and environmental friendly.

FIG. 1 is a schematic diagram of the overall structure of the present invention. FIG. 2 is a schematic view of the stacking device of the present invention.

Here, 1-feces collection tank, 11-sieving plate, 12-moisture meter, 13-supply tank, 14-stirring device, 2-aerobic fermentation tank, 21-stacking device, 211-storage hopper, 21
2-quantitative conveyor, 213-track, 214-stacking groove, 2141-load-bearing arm, 2142-hydraulic telescopic rod, 2143-capsulating device, 22-ventilator, 23-heat exchange device, 3-anaerobic reaction chamber, 31 -Solid-liquid separation device, 311-conveyor belt, 312-differential motor, 32-biogas slurry collection tank, 33-lift pump, 34-spray device, 4-biogas collection device, 41-biogas treatment device, 5 -Fertilizer production equipment, 51-drying equipment, 52-granulation equipment, 6-control box.

The materials and reagents used in the examples are either conventional in the art or commercially available unless otherwise stated.
Example 1
A facility for the production of organic fertilizers by energy chemical engineering cogeneration for livestock and poultry faeces.
Fecal collection tank 1
An aerobic fermentation tank 2 connected to a faecal collection tank for sterilization of livestock and poultry feces,
A stacking device 21 for forming livestock and poultry feces in a longitudinal shape, and a ventilation device 22 for ventilation are provided inside thereof.
An anaerobic reaction chamber 3 connected to an aerobic fermentation tank 2 for decomposing livestock and poultry feces to prepare biogas and organic fertilizer, inside which livestock and poultry feces are rotated back and forth to produce biogas. A solid-liquid separation device 31 for separating the slurry is provided, and the solid-liquid separation device 31 includes a conveyor belt 311 arranged in an inverted V shape, and a differential motor 3 for driving the conveyor belt.
12, a sieve hole for separating the biogas slurry is provided on the conveyor belt 311;
A biogas slurry collection tank 32 below the solid-liquid separator 31 for collecting the biogas slurry,
The lift pump 3 is used to spray the separated biogas slurry on livestock and poultry feces.
A spray device 34 connected to the biogas slurry collection tank 32 by 3.
A fertilizer manufacturing device 5 for converting the biogas residue produced in the anaerobic reaction chamber 3 into an organic fertilizer is connected to the outlet of the anaerobic reaction chamber 3, and the fertilizer manufacturing device 5 collects the biogas residue. It includes a drying device 51 for dehydrating and a granulating device 52 for granulating the dehydrated biogas residue into organic fertilizer particles.
A biogas collection device 4 controlled in the anaerobic reaction chamber 3 and a biogas treatment device 41 for dehydrating, removing dust, and desulfurizing the biogas generated in the anaerobic reaction chamber 3 are provided therein.
And a control box 6 for controlling the entire equipment,
The control box 6 includes a stacking device 21, a ventilation device 22 and a ventilation device 22 via relays, respectively.
It is connected to the differential motor 312, the lift pump 33, and the biogas collection device 4.

Example 2
Example 2 is basically the same as Example 1, with the difference that the faecal collection tank 1 has a sieve plate 11 at the inlet for selecting large debris in livestock and poultry feces, and livestock and poultry feces. The moisture meter 12 inside the stool collection tank 1 to monitor the water content of the stool, the supply tank 13 above the stool collection tank 1 to adjust the water content of livestock and poultry stool, and the stool A stirring device 14 inside the stool collection tank 1 for stirring.
Test 1
The faeces collection tank 1 of the equipment provided in Examples 1 and 2, respectively, is used to collect and treat feces. As a result, in the stool collection tank 1 in which the sieve plate 11 is not provided in Example 1, foreign matter in the stool adheres to the equipment and the water content of the stool cannot be adjusted, so that it is difficult to compost in the aerobic fermentation tank 2. However, the sieve plate 11 in the second embodiment can remove foreign matter and can adjust the water content of feces in the supply tank 13.
Conclusion: Sieve plate 11, moisture meter 12, supply tank 13 and agitator 14 in the fecal collection tank 1.
The provision of not only can prevent foreign matter in the feces from affecting the operation of the apparatus, but can also adjust the water content of the feces.

Example 3
The third embodiment is basically the same as the first embodiment, except that the stacking device 21
Storage hopper 211 above the aerobic fermentation tank 2 for feeding and monitoring the feed rate
And a quantifying conveyor 212 connected to the lower end of the storage hopper 211, a track 213 on the inner upper side of the aerobic fermentation tank 2, and a stacking groove 214 slidably provided on the track 213 by a load bearing arm 2141. The stacking groove 214 communicates with the quantitative conveyer 212, and the livestock and poultry feces in the storage hopper 211 are aerobically fermented.
2 is used for stacking into the longitudinally shaped compost, the load-bearing arm 2141 is connected to the stacking groove 214 via the hydraulic telescopic rod 2142, and is used for controlling the raising and lowering of the stacking groove 214. It is shown.
Test 2
Feces are stacked using the stacking device 21 of the equipment provided in Examples 1 and 3, respectively. As a result, one stacking time of the stacking device 21 in Example 1 is 54 minutes, and the time required for composting of the same size by the stacking device 21 in Example 3 is 13 minutes.
Conclusion: Using the stacking device in Example 3 significantly reduces stacking time.

Example 4
The fourth embodiment is basically the same as the third embodiment, and the difference is that the overturning device 2143 for overturning the compost is provided in the stacking groove 214 of the stacking device 21, as shown in FIG. 2.
Exam 3
Feces are stacked using the stacking devices of the equipment provided in Examples 1, 3 and 4, respectively. As a result, the compost shape stacked by the stacking device 21 in Example 1 and Example 3 is low in the center, low on both sides, is not a normal longitudinal shape, and the capsizing operation in the aerobic fermentation process of the compost is It can be done only manually or by other mechanical means, the compost shape stacked by the stacking device 21 in Example 4 is a normal longitudinal shape, and the overturning operation in the aerobic fermentation process is the direct overturning device 2143. Can be completed by.
Conclusion: The stacking shape by the stacking device in Example 4 is regular, the space in the stacking groove is maximized, and the overturning operation can be directly performed without using additional labor and machine, Material is saved.

Example 5
Example 5 is basically the same as Example 1, with the difference that the aerobic fermentation tank 2 further comprises an internal heat exchanger 23, the heat dissipation end of which is a biogas collection tank. Three
2 communicates with the inside of the aerobic fermentation tank 2, transfers the heat generated in the aerobic fermentation tank 2 to the biogas collection tank 32, heats the biogas slurry, and then sprays the anaerobic reaction chamber 3 via the spray device 34, Used to increase the number and growth rate of methanogens in the fermentate.
Test 4 Verification of Effect of Heat Exchanger 23 on Overall Operating Energy Consumption of Equipment Test Conditions A heating device is arranged in the biogas collection tank 32 in Example 1 to heat the biogas slurry, and then the spray device 34 is used. Spray into the anaerobic reaction chamber 3,
In Example 5, the heat exchange device 23 was used to transfer the heat generated in the aerobic fermentation tank 2 to the biogas slurry collection tank 32 to heat the biogas slurry, and then the anaerobic reaction chamber via the spray device 34. Spray on 3,
The cost and the power consumption of the heating device and the heat exchange device are statistically analyzed.
Results: Table 1 shows the cost and power consumption of the equipment of Examples 1 and 5.
Table 1 Heater and heat exchanger costs and power consumption


Conclusion: The heat exchange device used in Example 5 has low cost, low power consumption, low maintenance cost, and although the energy conversion rate is lower than that of the heating device, it does not consume electric energy.
The use of heat generated by aerobic fermentation in aerobic fermentation tanks is economical and environmentally friendly.

Example 6
Example 6 is basically the same as Example 1, with the difference that the exhaust ports of the fecal collection tank 1 and the aerobic fermentation tank 2 are each connected to a biogas treatment device 41.
Test 5
Test conditions The exhaust ports of the faecal collection tank 1 and the aerobic fermentation tank 2 of the equipment in Example 1 are directly discharged into the air.
The exhaust ports of the faecal collection tank 1 and the aerobic fermentation tank 2 of the equipment in Example 6 are connected to the biogas treatment device 41, respectively.
Result: In Example 1, the exhaust gas was directly discharged into the air to cause air pollution, and the surface of the equipment was corroded. In Example 6, however, the exhaust gas was discharged after the exhaust gas was treated, which is environmentally friendly.
Conclusion: In Example 6, since the exhaust ports of the stool collection tank and the aerobic fermentation tank are connected to the biogas treatment device, air pollution due to exhaust gas is avoided and it is environmentally friendly.

Example 7
Example 7 is basically the same as Example 1, except for the differences.
The faecal collection tank 1 has a sieve plate 1 at the entrance for sorting out large pieces of livestock and poultry feces.
1, a moisture meter 12 inside the fecal collection tank 1 to monitor the water content of livestock and poultry feces, and above the fecal collection tank 1 to adjust the water content of livestock and poultry feces A supply tank 13 and a stirring device 14 inside the stool collection tank 1 for stirring the stool,
including.
The stacking device 21 includes a storage hopper 211 above the aerobic fermentation tank 2 for supplying and monitoring the supply amount, and a fixed quantity conveyor 212 connected to the lower end of the storage hopper 211.
And a track 213 on the upper inside of the aerobic fermentation tank 2, and a stacking groove 214 slidably provided on the track 213 by a load bearing arm 2141.
Here, the stacking 214 groove communicates with the quantitative conveyor 212, and is used for stacking livestock and poultry feces in the storage hopper 211 into the longitudinally-shaped compost in the aerobic fermentation tank 2, and the load-bearing arm 2141 is It is connected to the stacking groove 214 via a hydraulic expansion/contraction rod 2142 and is used to control the elevation of the stacking groove 214.
An overturning device 2 for overturning feces in the stacking groove 214 of the stacking device 21.
143 is provided.
The aerobic fermentation tank 2 further includes an internal heat exchanger 23, and a heat radiating end of the heat exchanger 23 communicates with an inside of the biogas collection tank 32 to bioheat the heat generated in the aerobic fermentation tank 2. After being transferred to the gas collection tank 32 and heating the biogas slurry, it is sprayed into the anaerobic reaction chamber 3 through the spray device 34, and is used to increase the number and growth rate of methanogens in the fermented product. ..
The exhaust ports of the fecal collection tank 1 and the aerobic fermentation tank 2 are connected to the biogas treatment device 41, respectively.
The operation method of the seventh embodiment is as follows.
The livestock and poultry feces on the farm remove large debris by the sieve plate 11, and then send them to the fecal collection tank 1, and the moisture meter 12 monitors the water content of the livestock and poultry feces, and the moisture content of the livestock and poultry feces. In order to adjust the amount, control box 6 controls feed tank 13 to add dry material to faecal collection tank 1 to adjust the water content of livestock and poultry faeces, and during the addition process, agitator 14 After continuous stirring and adjustment, the feeder feeds livestock and poultry faeces to the storage hopper 211 of the aerobic fermentation tank 2, and the stacking groove 214 is moved to an appropriate position on the track 213 by the load-bearing arm 2141. After being moved, the hydraulic telescopic rod 214
2 arranges the stacking groove 214 on the bottom surface of the aerobic fermentation tank 2, the quantitative conveyor 212 opens, transports the livestock and poultry feces in the storage hopper 211 to the stacking groove 214, and the capsize device 2143 capsizes during the transportation process. Subsequently, livestock and poultry feces are piled up on the bottom surface of the aerobic fermentation tank 2 to grow into a longitudinal compost for aerobic fermentation, and a ventilation device is provided to supply oxygen required for aerobic fermentation during the fermentation process. After being continuously ventilated by 22 and the aerobic fermentation is completed, livestock and poultry feces are pulled up to the anaerobic reaction chamber 3 by the feeder, and the differential motor 312 of the solid-liquid separation device 31 is periodically periodically moved. Inverting and driving the conveyor belt 311 for reciprocating motion, livestock and poultry feces are inverted on the conveyor belt 311 by the action of gravity, and the biogas slurry contained in the livestock and poultry feces is biogas from the sieve holes. A large amount of heat is generated by livestock and poultry feces during the aerobic fermentation process, which is flowed to the slurry collection tank 32, and the heat is collected from the endothermic end of the heat exchange device 23 arranged on the inner wall of the aerobic fermentation tank 3. Next, the heat radiating end of the heat exchange device 23 heats the biogas slurry in the biogas collection tank 32, and the heated biogas slurry is lifted to the spray device 34 by the lift pump 33, and the biogas slurry in the anaerobic reaction chamber 3 is heated. After spraying livestock and poultry faeces to increase the number and breeding rate of methanogens in fermented livestock and poultry faeces and after completing the anaerobic reaction, the biogas residue enters the fertilizer production unit 5 for drying and The biogas produced by granulation to produce organic fertilizer is dehydrated, dust-removed, and desulfurized by the biogas treatment device 41, and then enters the biogas collection device 4 for power generation and gas supply.

Exam 6
The equipment provided in Examples 1 and 7, respectively, is used to treat feces and the treatment effects are comprehensively analyzed.
Results: Provided in Example 7 when the equipment provided in Example 1 processed feces, foreign matter adhered to the equipment, the stacking shape was irregular, and the exhaust gas polluted the air. The above situation does not appear during the processing of feces by the provided equipment.
And, the operating time of the equipment provided in Example 7 is shorter than the operating time of the equipment provided in Example 1, a specific difference is the operation of the stacking device, and in Example 7. The equipment provided does not require additional heating equipment, has low cost and low energy consumption.
Conclusion: The cost and energy consumption of the equipment provided in Example 7 is low, operating time is short, labor is saved, treatment efficiency is high, and environmentally friendly.

Claims (1)

A facility for producing organic fertilizer by energy chemical engineering cogeneration for livestock and poultry feces,
A faecal collection tank (1),
Aerobic fermentation tank connected to a faecal collection tank for sterilization of livestock and poultry feces (2)
When,
An aerobic fermentation tank (2) for decomposing livestock and poultry feces to prepare biogas and organic fertilizer.
) An anaerobic reaction chamber (3) connected to
A biogas slurry collection tank (32) below the solid-liquid separator for collecting biogas slurry,
A lift pump (for spraying the separated biogas slurry onto livestock and poultry faeces
33) a spray device (34) connected to the biogas slurry collection tank (32) by
)When,
A biogas collector (4) connected to the anaerobic reaction chamber (3),
A control box (6) for controlling the entire equipment,
Inside the aerobic fermentation tank (2), a stacking device (21) for making livestock and poultry feces into a longitudinal shape, and a ventilation device (22) for ventilation are provided.
Inside the anaerobic reaction chamber (3), a solid-liquid separator (31) for separating the biogas slurry by rotating livestock and poultry feces back and forth is provided,
A biogas treatment device (41) for dehydrating, removing dust and desulfurizing the biogas generated in the anaerobic reaction chamber (3) is provided inside the biogas collecting device (4) ,
In the fecal collection tank (1),
A sieve plate (11) at the inlet to sort out large pieces of livestock and poultry feces,
Moisture meter inside the fecal collection tank (1) to monitor the water content of livestock and poultry feces
(12) and
A feed tank located above the faeces collection tank (1) for adjusting the water content of livestock and poultry faeces.
Ku (13),
A stirrer (14) in the stool collection tank (1) for stirring the stool,
The stacking device (21) includes:
Storage hopper (above the aerobic fermentation tank (2) for feeding and monitoring the feed rate (
211),
A fixed quantity conveyor (212) connected to the lower end of the storage hopper (211),
A truck (213) on the upper inside of the aerobic fermentation tank (2),
Mounted slidably on the track (213) by a load bearing arm (2141)
And a stacking groove (214),
The stacking groove (214) communicates with the fixed quantity conveyor (212) and is connected to the storage hopper (211).
) Stacking livestock and poultry feces in the aerobic fermentation tank (2) into a longitudinal compost
Used for
The load-bearing arm (2141) is connected to the stacking groove via the hydraulic telescopic rod (2142).
(214) and is used to control the raising and lowering of the stacking groove (214),
An overturning device (2143) for overturning the compost is provided inside the stacking groove (214).
The
In the aerobic fermentation tank (2),
The heat exchanger (23) further includes an internal heat exchanger (23), and the heat radiating end of the heat exchanger (23) has the biogas
The heat generated in the aerobic fermentation tank (2) is communicated with the inside of the collection tank (32) and bioheated.
After transferring to the gas collection tank (32) and heating the biogas slurry, the spray device (3
4) to spray the anaerobic reaction chamber (3) to check the number and growth rate of methanogens in the fermented material.
Used to increase,
The solid-liquid separation device (31),
A conveyor belt (311) arranged in an inverted V shape,
A differential motor (312) for driving the conveyor belt (311),
A sieve hole for separating the biogas slurry is provided on the conveyor belt (311),
Biogas residue generated in the anaerobic reaction chamber (3) is present at the outlet of the anaerobic reaction chamber (3).
The fertilizer manufacturing device (5) for converting the material into organic fertilizer is connected, and the fertilizer manufacturing device (5) is
A drying device (51) for dehydrating the ogas residue and an organic matter for the dehydrated biogas residue.
A granulator (52) for granulating the fertilizer particles,
The exhaust ports of the fecal collection tank (1) and the aerobic fermentation tank (2) are respectively provided with the biogas.
Connected to the processing unit (41),
An organic fertilizer production facility by energy chemical engineering cogeneration for livestock and poultry faeces characterized by the above.