CN215559935U - Self-heating circulation quick aerobic composting system based on heat storage - Google Patents

Abstract

An autothermal cycle rapid aerobic composting system based on heat storage comprises a compost container and a heat accumulator; storing the kitchen waste in a stack container and carrying out aerobic fermentation; storing a heat storage material in the heat storage body and performing high-temperature aerobic fermentation; the stack container is connected with an air outlet pipeline and an air inlet pipeline; a first heat release pipeline and a second heat release pipeline are connected in parallel between the air outlet pipeline and the air inlet pipeline; a first heat storage pipeline communicated with the heat accumulator is connected on the first heat release pipeline and between the first valve bank and the second valve bank, and a second heat storage pipeline communicated with the heat accumulator is connected on the second heat release pipeline and between the first valve bank and the second valve bank; a first crossover valve is arranged on the air outlet pipeline between the first heat release pipeline and the second heat release pipeline, a second crossover valve is arranged on the air inlet pipeline, and a second temperature sensor is arranged on the stack container; the heat accumulator is provided with a first temperature sensor. The utility model comprises three flow structures of a conventional flow, a heat storage flow and a heat release flow, and stores the heat energy generated by the compost to realize the recycling of energy.

Description

Self-heating circulation quick aerobic composting system based on heat storage

Technical Field

The utility model belongs to the technical field of comprehensive treatment of solid wastes, and particularly relates to a self-heating circulation rapid aerobic composting system based on heat storage.

Background

Aerobic composting is one of important treatment means of solid waste garbage, sludge and the like, and the initial temperature of a pile body influences the reaction rate and the decomposition time of the aerobic composting. If the temperature is too low, the reaction rate is too low and the decomposition time increases. It is generally necessary to control the stack temperature above 15 ℃.

In fact, most of the time, especially in cold and severe cold regions, the ambient temperature in winter is lower than 15 ℃, during ventilation and oxygen supply, especially forced ventilation and oxygen supply, the compost is continuously cooled, the moderate-temperature aerobic microorganisms are inhibited, the temperature of the compost cannot be normally raised, and the aerobic composting fails.

In order to solve such problems, the aerobic composting in the prior art mostly adopts a method of reducing ventilation, prolonging composting time or setting a separate preheating system to increase the initial temperature of a heap. The first method is long in composting time and also risks composting failure; the second method requires a separate heat source and consumes energy.

In the composting process, various strains are vigorously propagated by utilizing soluble monosaccharide, fat and carbohydrate. In the process of converting and utilizing chemical energy, a part of the chemical energy is converted into heat energy, 1m³The heat production of the stack is about 5-10 kw. Usually, this part of the heat is directly removed with the exhaust gas and does not go back toAnd (4) recycling.

Therefore, a self-heating circulation rapid aerobic composting process based on heat storage is urgently needed to be designed by fully utilizing waste heat generated by aerobic composting and combining the characteristics of intermittence of composting and asynchronism of heat utilization and heat release. The process stores heat energy generated in the aerobic composting process by arranging the heat accumulator, and is used for preheating the compost at the initial composting stage or when the environmental temperature is lower, so that the temperature of the compost is effectively increased, the aerobic composting reaction rate is increased, and the decomposition time is shortened.

SUMMERY OF THE UTILITY MODEL

Aiming at the problems, the utility model provides a self-heating circulation rapid aerobic composting system based on heat storage, and aims to solve the problem of fully utilizing the self heat productivity of aerobic composting and realize an aerobic composting system which has the advantages of low energy consumption, simple structure, easy implementation, convenient operation and maintenance and meets the requirement of environmental protection.

The technical scheme of the utility model is realized as follows:

a self-heating circulation rapid aerobic composting system based on heat storage comprises a composting container, a heat storage body, an air outlet pipeline, an air inlet pipeline, a first valve bank, a second valve bank, a first crossover valve, a second crossover valve, a first temperature sensor and a second temperature sensor;

storing the kitchen waste in the stack container and carrying out aerobic fermentation; a heat storage material is stored in the heat storage body and high-temperature aerobic fermentation is carried out; the air outlet of the stack container is connected with one end of the air outlet pipeline, the air inlet of the stack container is connected with one end of the air inlet pipeline, the other end of the air outlet pipeline is communicated with the purifying device, and the other end of the air inlet pipeline is communicated with the outside; the air outlet pipeline and the air inlet pipeline are connected in parallel with a first heat release pipeline and a second heat release pipeline, and two ends of the second heat release pipeline are respectively connected between the tail end of the air outlet pipeline and the purification device and the initial end of the air inlet pipeline; the first heat release pipeline and the second heat release pipeline are respectively connected with the first valve bank and the second valve bank in series at corresponding positions; a first heat storage pipeline communicated with the first heat storage body inlet/outlet port is connected to the first heat release pipeline and between the first valve group and the second valve group, and a second heat storage pipeline communicated with the second heat storage body inlet/outlet port is connected to the second heat release pipeline and between the first valve group and the second valve group; the crossing valve I is arranged on the air outlet pipeline between the heat release pipeline I and the heat release pipeline II, the crossing valve II is arranged on the air inlet pipeline, and the temperature sensor II is arranged on the stack container; the heat accumulator is provided with the first temperature sensor.

The self-heating circulation rapid aerobic composting system based on heat storage is characterized in that a waste gas heat exchange pipeline penetrating through a heat storage material is arranged in the heat storage body, the arrangement form of the heat exchange pipeline is a serpentine pipeline, and the first heat storage pipeline and the second heat storage pipeline are communicated with pipe orifices at two ends of the waste gas heat exchange pipeline; the heat storage material in the heat storage body is liquid, solid or PCM material, and the heat release characteristic is that the high-temperature aerobic fermentation temperature is at least not lower than 60 ℃.

The self-heating circulation rapid aerobic composting system based on heat storage is characterized in that the heat storage material is water, heat conduction oil, heat storage bricks or octadecane.

When the temperature sensor monitors the temperature of the heap body container, the temperature is lower than the temperature of heat storage materials in the heap body monitored by the temperature sensor and is higher than 20 ℃, the first crossover valve is opened, the first valve group is closed, the second crossover valve is opened, and inlet air directly enters the heap body container through the air inlet pipe and the second crossover valve; and the waste gas in the stack container enters the air outlet pipeline through the air outlet and directly enters the purifying device through the first crossover valve.

When the temperature sensor monitors that the temperature of the heap in the heap container is higher than the temperature of heat storage materials in the heap container monitored by the temperature sensor, the second valve group is closed, the second crossover valve is opened, and inlet air directly enters the heap container through the air inlet by passing through the second crossover valve through the air inlet pipeline; and meanwhile, the first crossing valve is closed, the first valve group is opened, high-temperature waste gas in the stack container enters the first heat release pipeline through the gas outlet, the first heat storage pipeline enters the heat accumulator, heat energy is transferred to a heat storage material in the heat accumulator through the action of temperature difference, the heat accumulator enters a heat storage state, and the waste gas cooled in the heat accumulator is discharged to the air outlet pipeline through the second heat storage pipeline and the second heat release pipeline and enters a purification device.

When the temperature sensor monitors that the temperature of the heap in the heap container is lower than the temperature of heat storage materials in the heap container and lower than 20 ℃, the first crossover valve is opened, the first valve bank is closed, and high-temperature waste gas in the heap container directly enters a purification device through the first crossover valve through the air outlet pipeline; and meanwhile, the second valve group is opened, the second crossing valve is closed, inlet air enters the heat storage body through the air inlet pipeline through the second heat release pipeline and the second heat storage pipeline, is subjected to heat exchange with a heat storage material and then is heated, and enters the stack container through the first heat storage pipeline and the second heat release pipeline through the air inlet.

According to the self-heating circulation rapid aerobic composting system based on heat storage, high-temperature waste gas in the compost container enters a waste gas heat exchange pipeline arranged in the heat storage body to exchange heat and cool, and then is discharged.

According to the self-heating circulation rapid aerobic composting system based on heat storage, air enters a waste gas heat exchange pipeline in the heat storage body to exchange heat and raise the temperature, and then is discharged into the compost container.

The utility model has the following effects:

(1) aerobic composting is different in stages and different in heat demand, and heating is needed in the initial stage and cooling is needed in the later stage. The system makes full use of the characteristics, stores the heat energy generated in the aerobic composting process by arranging the heat accumulator, gives full play to the characteristics of the heat accumulator, reduces energy waste and realizes energy recycling.

(2) The process fully utilizes self-heating without additional energy.

(3) The process can store the cooling heat of the compost when the ambient temperature is high, and the cooling heat can be used in the compost start period of the compost when the ambient temperature is low.

(4) The recycled heat energy is used for preheating the compost at the initial composting stage or when the environmental temperature is lower, so that the temperature of the compost can be effectively increased, the aerobic composting reaction rate is increased, and the decomposition time is shortened.

(5) The method can select proper heat storage materials and capacity according to different garbage components and composting requirements, and can recover heat energy to the maximum extent.

Drawings

FIG. 1 is a schematic diagram of the system connection of the present invention,

FIG. 2 is a schematic diagram of a conventional flow chart of the system of the present invention,

FIG. 3 is a schematic diagram of the heat storage process of the system of the present invention,

FIG. 4 is a schematic diagram of the heat release process of the system of the present invention;

description of the figures

1-a stack container, 2-a heat accumulator, 3-an air outlet pipeline, 4-an air inlet pipeline, 5-a first valve bank, 6-a second valve bank, 7-a first crossover valve, 8-a second crossover valve, 9-a first temperature sensor, 10-a second temperature sensor, a first heat release pipeline 31, a second heat release pipeline 32, a first heat storage pipeline 41 and a second heat storage pipeline 42;

Detailed Description

The following embodiments are given for the purpose of illustrating the present invention clearly and not for the purpose of limiting the same, and it will be apparent to those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the present invention.

Referring to fig. 1, the self-heating circulation rapid aerobic composting system based on heat storage of the utility model comprises a composting container 1, a heat accumulator 2, an air outlet pipeline 3, an air inlet pipeline 4, a first valve bank 5, a second valve bank 6, a first crossover valve 7, a second crossover valve 8, a first temperature sensor 9 and a second temperature sensor 10;

the kitchen waste is stored in the heap body container 1 and is subjected to aerobic fermentation; a heat storage material is stored in the heat accumulator 2 and high-temperature aerobic fermentation is carried out; the air outlet of the stack container 1 is connected with one end of the air outlet pipeline 3, the air inlet of the stack container is connected with one end of the air inlet pipeline 4, the other end of the air outlet pipeline 3 is communicated with a purification device, and the other end of the air inlet pipeline 4 is communicated with the outside; a first heat release pipeline 31 and a second heat release pipeline 32 are connected in parallel between the air outlet pipeline 3 and the air inlet pipeline 4, and two ends of the second heat release pipeline 32 are respectively connected between the tail end of the air outlet pipeline 3 and the purification device and the beginning end of the air inlet pipeline 4; the first heat release pipeline 31 and the second heat release pipeline 32 are respectively connected with the first valve bank 5 and the second valve bank 6 in series at corresponding positions; a first heat storage pipeline 41 communicated with the first inlet/outlet port of the heat accumulator 2 is connected on the first heat release pipeline 31 and between the first valve group 5 and the second valve group 6, and a second heat storage pipeline 42 communicated with the second inlet/outlet port of the heat accumulator 2 is connected on the second heat release pipeline 32 and between the first valve group 5 and the second valve group 6; the first crossover valve 7 is arranged on the air outlet pipeline 3 between the first heat release pipeline 31 and the second heat release pipeline 32, the second crossover valve 8 is arranged on the air inlet pipeline 4, and the second temperature sensor 10 is arranged on the stack container 1; the first temperature sensor 9 is arranged on the heat accumulator 2.

The self-heating circulation rapid aerobic composting system based on heat storage is characterized in that a waste gas heat exchange pipeline penetrating through a heat storage material is arranged in a heat storage body, the heat exchange pipeline is arranged in a serpentine pipeline, a first heat storage pipeline 41 and a second heat storage pipeline 42 are communicated with pipe orifices at two ends of the waste gas heat exchange pipeline, namely a first air inlet/outlet and a second air inlet/outlet, and the pipe orifices at the two ends can be used for air inlet or air outlet according to the trend of gas; the heat storage material in the heat storage body is liquid, solid or PCM material, and the heat release characteristic is that the high-temperature aerobic fermentation temperature is at least not lower than 60 ℃.

The self-heating circulation rapid aerobic composting system based on heat storage is characterized in that the heat storage material is water, heat conduction oil, heat storage bricks or octadecane.

In the self-heating circulation rapid aerobic composting system based on heat accumulation, referring to fig. 2, when the second temperature sensor 10 monitors the temperature of the pile body in the pile body container 1, and the temperature is lower than the temperature of the heat accumulation material in the heat accumulation body monitored by the first temperature sensor 9 and higher than 20 ℃, the first crossover valve 7 is opened, the first valve group 5 is closed, the second valve group 6 is closed, the second crossover valve 8 is opened, and the inlet air enters the pile body container 1 through the inlet port directly through the second crossover valve 8 through the inlet air pipe 4; and the waste gas in the stack container 1 enters the air outlet pipeline 3 through the air outlet and directly enters the purification device through the first crossover valve 7.

In the self-heating circulation rapid aerobic composting system based on heat accumulation, referring to fig. 3, when the second temperature sensor 10 detects that the temperature of the pile in the pile container 1 is higher than the temperature of the heat accumulation material in the pile detected by the first temperature sensor 9, the second valve group 6 is closed, the second crossover valve 8 is opened, and the inlet air enters the pile container 1 through the inlet port directly through the second crossover valve 8 through the inlet air pipe 4; meanwhile, the first crossover valve 7 is closed, the first valve group 5 is opened, high-temperature waste gas in the stack container 1 enters the first heat release pipeline 31 through the air outlet, the first heat storage pipeline 41 enters the heat accumulator 2, heat energy is transferred to heat storage materials in the heat accumulator 2 through the temperature difference effect, the heat accumulator 2 enters a heat storage state, and waste gas cooled in the heat accumulator 2 is discharged to the air outlet pipeline 3 through the second heat storage pipeline 42 and the second heat release pipeline 32 and enters a purification device.

In the self-heating circulation rapid aerobic composting system based on heat accumulation, referring to fig. 4, when the temperature sensor II 10 detects that the temperature of the heap in the heap container 1 is lower than the temperature of heat accumulation materials in the heap, which is detected by the temperature sensor I9, and is lower than 20 ℃, the crossover valve I (7) is opened, the valve group I (5) is closed, and high-temperature waste gas in the heap container 1 directly enters a purification device through the air outlet pipeline 3 via the crossover valve I (7); meanwhile, the second valve group 6 is opened, the second crossover valve 8 is closed, intake air enters the heat accumulator 2 through the second heat release pipeline 32 and the second heat accumulation pipeline 42 through the air inlet pipeline 4, is heated after exchanging heat with a heat accumulation material, and enters the reactor container 1 through the first heat accumulation pipeline 41 and the first heat release pipeline 31 through the air inlet.

According to the self-heating circulation rapid aerobic composting system based on heat storage, high-temperature waste gas in the compost container 1 enters a waste gas heat exchange pipeline arranged in the heat storage body to exchange heat and cool, and then is discharged.

According to the self-heating circulation rapid aerobic composting system based on heat storage, air enters the waste gas heat exchange pipeline in the heat accumulator 2 for heat exchange and temperature rise, and is discharged into the compost container 1.

The working principle of the utility model is as follows:

the utility model designs an autothermal cycle rapid aerobic composting process based on heat storage by utilizing waste heat generated by aerobic composting and combining the characteristics of composting intermittence and asynchronism of heat consumption and heat release. The system mainly comprises a stack container, a heat accumulator, an air outlet pipeline, an air inlet pipeline, a first heat accumulation valve group, a second heat release valve group, a first crossover valve, a second crossover valve, a first temperature sensor, a second temperature sensor and the like.

The heap body container 1 is used for storing kitchen waste and performing aerobic fermentation; the heat accumulator 2 is used for storing high-temperature aerobic heat release and supplementing aerobic heat demand at low temperature, the heat storage materials can be water, heat conduction oil (liquid), magnesium oxide heat storage bricks (solid), octadecane (PCM, the phase change temperature is 28 ℃) and the like, and the high-temperature aerobic temperature is generally not lower than 60 ℃; the air outlet pipeline 3 is used for conveying waste gas generated by aerobic composting to a purification device for treatment; the air inlet pipeline 4 is used for supplementing oxygen and cooling air quantity required by aerobic composting, and fans can be arranged on the air outlet pipeline 3 and the air inlet pipeline 4 according to the conventional technology; the first valve group 5 is used for controlling a heat storage process of aerobic composting waste gas; the second valve group 6 is used for controlling an air inlet flow of aerobic composting; the first crossover valve 7 and the second crossover valve 8 are respectively used for switching an air inlet and outlet heat storage and release pipeline; the first temperature sensor 9 is used for monitoring the temperature of the heat accumulator; the second temperature sensor 10 is used for monitoring the temperature of the stack body.

The working process of the utility model is divided into 3 process systems of conventional heat release and heat storage,

first, conventional procedure

Referring to fig. 2, in the stack container 1, when the stack temperature monitored by the second temperature sensor 10 is higher than 20 ℃ and lower than the thermal mass temperature monitored by the first temperature sensor 9, the first crossover valve 7 is opened, the first valve bank 5 is closed, the second valve bank 6 is closed, the second crossover valve 8 is opened, and the inlet air directly enters the stack container 1 through the second crossover valve 8 through the inlet air duct 4; and waste gas directly enters the purification device through the air outlet pipeline 3 through the first crossover valve 7.

Second, heat storage process

Referring to fig. 3, in the stack container 1, the stack temperature monitored by the second temperature sensor 10 is higher than the heat storage temperature monitored by the first temperature sensor 9, the second valve group 6 is closed, the second crossover valve 8 is opened, and the inlet air directly enters the stack container 1 through the second crossover valve 8 through the inlet air pipe 4; meanwhile, the first crossover valve 7 is closed, the first valve group 5 is opened, high-temperature waste gas enters the first heat release pipeline 31 through the gas outlet, enters the first heat storage pipeline 41 through the first valve group 5, enters the heat accumulator 2, heat energy is transferred to a heat storage material in the heat accumulator 2 through the temperature difference effect, and the heat accumulator 2 enters a heat storage state. The cooled waste gas enters the purification device through the air outlet pipeline 3.

Third, heat release process

Referring to fig. 4, when the temperature of the stack monitored by the second temperature sensor 10 in the stack container 1 is lower than 20 ℃ and lower than the temperature of the heat accumulator monitored by the first temperature sensor 9, the first crossover valve 7 is opened, the first valve bank 5 is closed, and the high-temperature exhaust gas directly enters the purification device through the first crossover valve 7 through the air outlet pipe 3; meanwhile, the second valve group 6 is opened, the second crossover valve 8 is closed, intake air enters the heat accumulator 2 through the second heat release pipeline 32, the second valve group 6 and the second heat storage pipeline 42 through the air inlet pipeline 4, is subjected to heat exchange with a heat storage material and then is heated, and enters the reactor container 1 through the first heat storage pipeline 41, the first heat release pipeline 31 and the heat storage valve 6 through the air inlet;

the heat storage material in the heat storage body 2 may be a liquid, a solid, or a PCM or other different material. The specific material can be selected according to different heat accumulation and release characteristics of the reactor. The heat storage material can be water, heat conduction oil (liquid), magnesium oxide heat storage bricks (solid), octadecane PCM (phase change temperature is 28 ℃) and the like, and the high-temperature aerobic temperature is generally not lower than 60 ℃.

The process stores heat energy generated in the aerobic composting process by arranging the heat accumulator, is used for preheating the compost at the initial composting stage or when the environmental temperature is lower, can effectively improve the temperature of the compost, improves the reaction rate of the aerobic composting and shortens the decomposition time. Is a self-heating circulation rapid aerobic composting process based on heat storage,

the structures of the stack container 1 and the heat accumulator 2 are common structures, and are generally cylindrical or rectangular containers. The stack container 1 is generally made of glass fiber reinforced plastic, and the heat accumulator 2 may be made of steel or concrete. The whole heat accumulator is filled with the heat storage material, the waste gas passes through the heat accumulator through the heat exchange pipeline, the pipeline arrangement form is a coiled pipe, and the pipe diameter, the distance, the wall thickness, the material quality and the like can be adjusted according to actual requirements.

Claims (7)

1. An autothermal cycle rapid aerobic composting system based on heat storage is characterized by comprising a composting container (1), a heat accumulator (2), an air outlet pipeline (3), an air inlet pipeline (4), a first valve bank (5), a second valve bank (6), a first crossover valve (7), a second crossover valve (8), a first temperature sensor (9) and a second temperature sensor (10);

the kitchen waste is stored in the heap container (1) and is subjected to aerobic fermentation; a heat storage material is stored in the heat accumulator (2) and high-temperature aerobic fermentation is carried out; the air outlet of the stack container (1) is connected with one end of the air outlet pipeline (3), the air inlet of the stack container is connected with one end of the air inlet pipeline (4), the other end of the air outlet pipeline (3) is communicated with a purification device, and the other end of the air inlet pipeline (4) is communicated with the outside; a first heat release pipeline (31) and a second heat release pipeline (32) are connected in parallel between the air outlet pipeline (3) and the air inlet pipeline (4), and two ends of the second heat release pipeline (32) are respectively connected between the tail end of the air outlet pipeline (3) and the purification device and at the beginning end of the air inlet pipeline (4); the first heat release pipeline (31) and the second heat release pipeline (32) are respectively connected with the first valve bank (5) and the second valve bank (6) in series at corresponding positions; a first heat storage pipeline (41) communicated with a first inlet/outlet port of the heat storage body (2) is connected on the first heat release pipeline (31) and between the first valve group (5) and the second valve group (6), and a second heat storage pipeline (42) communicated with a second inlet/outlet port of the heat storage body (2) is connected on the second heat release pipeline (32) and between the first valve group (5) and the second valve group (6); the crossing valve I (7) is arranged on the air outlet pipeline (3) between the heat release pipeline I (31) and the heat release pipeline II (32), the crossing valve II (8) is arranged on the air inlet pipeline (4), and the temperature sensor II (10) is arranged on the stack container (1); the first temperature sensor (9) is arranged on the heat accumulator (2).

2. The self-heating circulation rapid aerobic composting system based on heat accumulation as claimed in claim 1, wherein an exhaust gas heat exchange pipeline passing through the heat accumulation material is arranged in the heat accumulator, the heat exchange pipeline is arranged in a serpentine pipeline, and the first heat accumulation pipeline (41) and the second heat accumulation pipeline (42) are communicated with pipe orifices at two ends of the exhaust gas heat exchange pipeline; the heat storage material in the heat storage body is liquid, solid or PCM material, and the heat release characteristic is that the high-temperature aerobic fermentation temperature is at least not lower than 60 ℃.

3. The self-heating circulation rapid aerobic composting system based on heat accumulation as claimed in claim 1, wherein the heat accumulation material is water, heat conduction oil, heat accumulation bricks or octadecane.

4. The thermal storage based autothermal cycle rapid aerobic composting system of claim 1 wherein when the second temperature sensor (10) monitors the temperature of the heap in the heap container (1) below the temperature of the thermal storage material in the heap monitored by the first temperature sensor (9) and above 20 ℃, the first crossover valve (7) is open, the first valve (5) is closed, the second valve (6) is closed, the second crossover valve (8) is open, and the inlet air enters the heap container (1) through the inlet duct (4) via the second crossover valve (8) directly via the inlet; and the waste gas in the stack container (1) enters the air outlet pipeline (3) through the air outlet and directly enters the purification device through the first crossover valve (7).

5. The thermal storage based autothermal cycle rapid aerobic composting system of claim 1 wherein when the second temperature sensor (10) detects that the temperature of the heap in the heap container (1) is higher than the temperature of the thermal storage material in the heap detected by the first temperature sensor (9), the second valve (6) is closed, the second crossover valve (8) is opened, and the inlet air enters the heap container (1) through the inlet port directly through the second crossover valve (8) through the inlet duct (4); meanwhile, the first crossover valve (7) is closed, the first valve group (5) is opened, high-temperature waste gas in the stack container (1) enters the first heat release pipeline (31) and the first heat storage pipeline (41) enters the heat accumulator (2) through the gas outlet, heat energy is transferred to a heat storage material in the heat accumulator (2) through the action of temperature difference, the heat accumulator (2) enters a heat storage state, and the waste gas cooled in the heat accumulator (2) is discharged to the air outlet pipeline (3) through the second heat storage pipeline (42) and the second heat release pipeline (32) and enters a purification device.

6. The autothermal cycle rapid aerobic composting system based on thermal storage according to claim 1 wherein when the temperature sensor two (10) detects that the temperature of the heap in the heap container (1) is lower than the temperature of the thermal storage material in the heap which is detected by the temperature sensor one (9) and lower than 20 ℃, the crossover valve one (7) is opened, the valve group one (5) is closed, and the high temperature waste gas in the heap container (1) directly enters the purification device through the air outlet pipe (3) via the crossover valve one (7); meanwhile, the second valve group (6) is opened, the second crossover valve (8) is closed, intake air enters the heat accumulator (2) through the air inlet pipeline (4) via the second heat release pipeline (32) and the second heat storage pipeline (42), is subjected to heat exchange with a heat storage material and then is heated, and enters the stack container (1) through the first heat storage pipeline (41) and the first heat release pipeline (31) via the air inlet.

7. The self-heating circulation rapid aerobic composting system based on heat accumulation as claimed in claim 5, wherein the heat accumulator is provided with an exhaust gas heat exchange pipeline.

Images