CN212669681U - Fermentation equipment of organic matter - Google Patents

Abstract

The utility model provides a fermentation equipment of organic matter. The equipment comprises a first fermentation tank, a conveying system and a semi-permeable area which are connected in sequence; the conveying system is used for conveying the materials in the first fermentation tank to the semi-permeable area; the semi-permeable area is provided with a material with pores, the size of the pores is 200 mu m-5 mm, and the material is used for separating the material in the first fermentation tank; the semi-permeable area is also provided with a loop connected with the first fermentation tank, and the loop is used for conveying the separated material with high solid content to the first fermentation tank. The fermentation equipment of the utility model can effectively control the solid content in the organic fermentation equipment, thereby creating the best condition for the reproduction of anaerobic bacteria, the organic fermentation time is short, the biogas yield is high, the instrument operation is simple and convenient, and the process is stable.

Description

Fermentation equipment of organic matter

Technical Field

The utility model relates to a fermentation equipment of organic matter.

Background

Anaerobic fermentation of organic matter is an important solution for treating solid or liquid organic waste, and can convert organic matter into renewable energy gas and organic fertilizer. Anaerobic fermentation techniques for organic matter are generally divided into three categories: when the solid content of the material to be treated is less than 5%, anaerobic fermentation is carried out on the wastewater; when the solid content is between 5% and 20%, performing wet anaerobic fermentation; and when the solid content of the organic matters is more than 20%, dry anaerobic fermentation is carried out.

The main process of wet anaerobic fermentation is a complete mixing process: for example using a fully stirred tank reactor (CSTR). In this type of reactor, the mixing of the medium is ensured by a mechanical stirrer immersed in the reactor, which serves to stir the entire reactor interior. Alternatively, the mixing may be performed by injecting biogas into the reactor, the biogas being injected centrally from the reactor and causing intensive mixing within the reactor. In addition, the mixing of the reactor is achieved by external circulation (circulation of the material from one end of the fermenter to the other by means of a pump).

In continuous dry anaerobic fermentation, organic matter is introduced at one end of the fermentation tank and then proceeds to the other end of the fermentation tank in a plug flow fashion. These fermenters may be horizontal or vertical. Agitation in these fermenters is either ensured by gradually pushing the material towards the outlet of the fermenter by means of a slow agitator, or by circulating the material from one end of the fermenter to the other by means of a pump or by injecting biogas into the fermenter.

None of these techniques allow precise control of the solids content of the material in the fermentor. Therefore, these techniques do not provide optimal conditions for the propagation of anaerobic bacteria. The residence time of the organic matter is at least 30 days for the fully mixed technique and at least 20 days for the continuous dry fermentation technique. These techniques are also very sensitive to fluctuations in the organic load (amount of organic matter digested per day) fed to the fermenter, and therefore the organic load fed to the fermenter must be precisely controlled to ensure proper operation of the plant, which requires a lot of expertise on the part of the operator and makes the operation very inflexible. Furthermore, without control of the solids content, these techniques suffer from a number of problems in forming a suspension layer and a sediment layer, which are detrimental to the operation of the fermentor. Meanwhile, the maintenance of mechanical stirring parts in the fermentation tank is complex and expensive.

In the batch dry fermentation technique, the solid organic matter remains static in the fermentor. The organic matter is poured into the reaction device in batches and then is poured by liquid, and the liquid is circularly poured after sinking. In this type of technique, the organic solids are not stirred, and therefore the fermentation of the organic solids is very slow and difficult to control, with a residence time of about 60 days per batch. In addition, such techniques are operated batch-wise. The discontinuous nature of this fermentation makes the operation of this technique particularly complex.

For wider application, anaerobic fermentation technology must reduce investment and operating costs, reduce the volume of the reactor for use in locations with site restrictions. Anaerobic fermentation technology must also improve fermentation efficiency to increase energy production, reduce pollution, and improve process stability to ensure production stability.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome prior art's defect, provide a fermentation equipment of organic matter. The fermentation equipment of the utility model can effectively control the solid content in the organic fermentation equipment, thereby creating the best condition for the reproduction of anaerobic bacteria, the organic fermentation time is short, the biogas yield is high, the instrument operation is simple and convenient, and the process is stable.

The utility model discloses a solve above-mentioned technical problem through following technical scheme.

The utility model provides a fermentation device for organic matters, which comprises a first fermentation tank, a conveying system and a semi-permeable area which are connected in sequence; the conveying system is used for conveying the materials in the first fermentation tank to the semi-permeable area; the semi-permeable area is provided with a material with pores, the size of the pores is 200 mu m-5 mm, and the material is used for separating the material in the first fermentation tank; the semi-permeable area is also provided with a loop connected with the first fermentation tank, and the loop is used for conveying the separated material with high solid content to the first fermentation tank.

In the present invention, the first fermenter may be a conventional fermenter in the art.

Preferably, the first fermenter comprises a first inlet, a fifth inlet, a first outlet, a second outlet, a ninth outlet and a first fermenter material output pipe; the first inlet is a feeding channel of the separated material with high solid content; the fifth inlet is a feeding channel of the first fermentation tank and is used for conveying the fresh organic matters to be fermented into the first fermentation tank; one end of the first fermenter material output pipeline is connected with the first outlet and is used for conveying the material of the first fermenter to the semi-permeable area through the conveying system; the second outlet is a gas collecting channel of the first fermentation tank; the ninth outlet is a fermentation product discharge channel of the first fermentation tank and is used for discharging the fermentation product out of the first fermentation tank. In the utility model, the fresh organic matter to be fermented is the raw material to be treated which never enters the fermentation equipment.

Wherein, preferably, the first inlet is positioned at the upper part of the first fermenter.

Wherein, preferably, the fifth inlet is positioned at the upper part of the first fermenter.

In a preferred embodiment, the first inlet and the fifth inlet of the first fermenter can be the same inlet, i.e. the first inlet can be the feed channel of the first fermenter as well as the feed channel of the high solid content material.

Wherein, preferably, the first outlet is positioned at the lower part of the first fermenter.

Wherein, preferably, the second outlet is positioned at the upper part of the first fermenter.

Wherein, preferably, the ninth outlet is positioned at the lower part of the first fermenter.

Preferably, the first fermenter is not provided with a stirring member therein.

The utility model discloses in, conveying system can be the conventional conveying system in this field, conveying system can adjust the conveying speed of material.

The utility model discloses in, use during fermentation equipment, the material of the high solid content rate that the semi-permeable district separation obtained is carried back first fermentor, preferably, the semi-permeable district still be equipped with the low solid content rate's after the separation material discharge the pipeline in semi-permeable district. Wherein the low solid content rate means that the solid content rate is less than that of the material in the first fermentation tank, and the high solid content rate means that the solid content rate is greater than that of the material in the first fermentation tank.

Wherein, preferably, the semi-permeable area comprises a second inlet, a third outlet, a fourth outlet and a high solid content material output pipeline; the second inlet is connected with the other end of the first fermentation tank material output pipeline to form a feeding channel of the semi-permeable area; the third outlet is a discharge channel of the material with low solid content; the fourth outlet is a discharge channel of the material with high solid content; and one end of the high solid content material output pipeline is connected with the fourth outlet, and the other end of the high solid content material output pipeline is connected with the first fermentation tank and used for conveying the separated high solid content material to the first fermentation tank.

Wherein, preferably, the semi-permeable area is an inclined, serpentine, vertical or horizontal device.

More preferably, when the semi-permeable zone is a horizontal apparatus, the horizontal apparatus is a serpentine. More preferably, when the semi-permeable zone is a vertical apparatus, the second inlet is located at the lower part of the semi-permeable zone; the third outlet is positioned at the lower part of the semi-permeable zone and is higher than the second inlet; more preferably, the height of the third outlet from the bottom of the semi-permeable zone is within 15% of the height of the semi-permeable zone; the fourth outlet is located in an upper portion of the semi-permeable zone.

Preferably, the semi-permeable material in the semi-permeable zone is cloth, stainless steel, plastic or ceramic.

Preferably, the semi-permeable zone comprises a blow-back system, which can be conventional in the art, for cleaning the pores in the semi-permeable zone. Preferably, when the semi-permeable zone is a vertical device, the back-blowing system is located at the upper part of the semi-permeable zone.

In the utility model, preferably, the fermentation equipment includes a flow rate adjusting device, the flow rate adjusting device is located the fourth export with between the first import. The flow rate regulating device may be conventional in the art and may regulate the flow rate of the high solids content material in the semi-permeable zone.

In the utility model, preferably, the fermentation equipment includes a fifth export, the fifth export is located the fourth export with between the first import, do the discharge channel of the low reaches fermentation result in semi-permeable zone.

In the present invention, preferably, the fermentation apparatus includes a heating system, and the heating system is located between the fourth outlet and the first inlet.

In a preferred embodiment, the fourth outlet connects the semi-permeable zone to the flow rate regulating device, the fifth outlet and the heating system in this order.

The utility model discloses in, preferably, fermentation equipment includes a material introducing system, material introducing system with first import or fifth access connection for with the fresh introduction of treating fermented organic matter fermentation equipment.

In the present invention, preferably, the fermentation apparatus includes a second fermentation tank; the second fermentation tank comprises a third inlet, a sixth outlet, a seventh outlet, an eighth outlet, a low solid content material input pipeline and a second fermentation tank material output pipeline; one end of the low-solid-content material input pipeline is connected with the semi-permeable area (which can be the third outlet of the semi-permeable area), and the other end of the low-solid-content material input pipeline is connected with the third inlet, and is used for conveying the low-solid-content material to the second fermentation tank; the first fermenter comprises a fourth inlet; one end of the second fermentation tank material output pipeline is connected with the sixth outlet, and the other end of the second fermentation tank material output pipeline is connected with the fourth inlet, and is used for conveying part of the second fermentation tank material back to the first fermentation tank; the seventh outlet is used for discharging the residual materials of the second fermentation tank out of the second fermentation tank; the eighth outlet is a gas collection channel of the second fermentor.

Wherein, preferably, the third inlet is located at the lower part of the second fermenter.

Wherein, preferably, the fourth inlet is positioned at the upper part of the first fermenter.

Wherein, preferably, the sixth outlet is positioned at the upper part of the second fermenter.

Wherein, preferably, the seventh outlet is located at the upper part of the second fermenter.

Wherein, preferably, the eighth outlet is located at the upper part of the second fermenter.

When the fermentation equipment of the organic matters is adopted, the fermentation method of the organic matters can be adopted, and the steps comprise that the organic matters are fermented in the first fermentation tank; the conveying system conveys the materials in the first fermentation tank to the semi-permeable area for solid-liquid separation, the materials with low solid content obtained by the separation in the semi-permeable area are discharged from the semi-permeable area, and the materials with high solid content obtained by the separation in the semi-permeable area are conveyed back to the first fermentation tank;

wherein the low solid content is that the solid content is less than that of the material in the first fermenter; the high solid content is that the solid content is larger than that of the material in the first fermentation tank.

The utility model discloses can be in ensureing control when the solid rate that contains of organic matter in the first fermentor, mix the organic matter effectively. The conveying system pumps out the materials (the partially fermented solid and liquid) in the first fermentation tank, discharges partial materials (low solid content rate) after solid-liquid separation is carried out in the semi-permeable zone, and conveys the separated materials (high solid content rate) back to the first fermentation tank, so that the materials in the first fermentation tank can be fully mixed; and the solid content in the fermentation tank can be adjusted by adjusting the circulating speed and the circulating material amount of the conveying system. Therefore, the utility model discloses can contain solid rate in the accurate control fermentation cylinder, the whole fermentation materials of mixed fermentation jar simultaneously effectively. The use of a single system to achieve both mixing and control of the solid content rate enables fine control of both parameters, which is not possible with the prior art.

The utility model discloses can be used to organic matter fermentation technical field, its specially adapted contains the solid rate relatively higher (generally contain the solid rate and be greater than 5%, be greater than 10% better, be greater than 15% and be less than 35%) organic matter anaerobic fermentation. The organic matter is preferably one or more of solid organic waste or energy crops, such as agricultural waste, industrial waste, waste produced on the food processing industry chain, kitchen waste and municipal organic waste; and further for example industrial and municipal wastewater treatment sludges.

Wherein, the agricultural waste contains various crop straws, livestock and poultry manure produced by livestock and poultry cultivation, and the like; the waste produced in the industrial chain of the food processing industry or the kitchen waste contains a mixture of various substances such as oil, water, fruit peels, vegetables, rice flour, fish, meat, bones and the like; municipal organic waste contains domestic waste and the like.

In the present invention, the solid content in the first fermenter is preferably 10% to 40%, more preferably 15% to 25%.

The inventors have noted that controlling the solids content and the intensity of agitation in the fermentor is a key parameter for culturing the fermenting flora for fermenting the organic material. Through the control of the parameters, the utility model creates the optimal conditions for the culture of the fermentation flora. Furthermore, it may ensure an efficient discharge system of the soluble fermentation product. Therefore, compared with other anaerobic fermentation technologies, the utility model greatly reduces the retention time of the organic matters. Therefore, compared to the prior art, the volume of the fermentation tank using the technology of the present invention is smaller (compared to the prior art, the volume of the first fermentation tank or the second fermentation tank is only 30% of that of the dry fermentation apparatus, or only 15% of that of the wet fermentation apparatus, wherein the volume of the apparatus is calculated according to the volume of the daily treatment amount ×. the residence time), thereby reducing the investment cost and the floor space. This also makes the fermentation of organic matter more abundant in the utility model to ensure the degradation of organic matter bigger degree, and make the output of marsh gas than the traditional technology and go up by 25%.

The utility model discloses in, preferably, the organic matter is in average dwell time in the first fermenter is 1 ~ 15 days.

In the present invention, preferably, the reaction in the first fermenter is anaerobic fermentation.

The utility model discloses in, preferably, after the steady operation to a day calculates for the time cycle, through the material volume that conveying system carried does 0.3 ~ 3 times of the volume of first fermentor.

The utility model discloses in, preferably, when including the second fermentation cylinder in the fermentation equipment, after the steady operation to one day calculates as time cycle, follows the second fermentation cylinder mesocycle extremely the material volume of first fermentation cylinder does 0.2 ~ 3 times of the volume of first fermentation cylinder.

In the present invention, preferably, the reaction in the second fermentation tank is anaerobic fermentation/aerobic fermentation, more preferably anaerobic fermentation.

The utility model discloses in, preferably, the temperature of first fermentor is 20 ~ 60 ℃.

The utility model discloses in, preferably, the organic matter throws the material once more at least every day and gets into in the first fermenter.

The utility model discloses an actively advance the effect and lie in:

the utility model discloses a fermentation equipment can effective control organic matter fermentation equipment in contain solid rate to for the reproduction of anaerobe creates the optimal condition, organic matter fermentation time is short, and biogas output is high, and the fermentation cylinder is small, thereby has reduced investment cost and area.

The utility model discloses can prevent the formation of suspension layer or sedimentation layer, and suspension layer or sedimentation layer are the common operating problem of current anaerobic fermentation technique. The process is also particularly stable to fluctuations in the organic load of the organic material fed into the fermenter, thus making the apparatus easier to operate.

The utility model discloses do not need at main fermentation cylinder internally mounted moving part to the maintenance operation has been reduced and simplified.

Drawings

FIG. 1 is a schematic view of the apparatus in example 1.

FIG. 2 is a schematic view of the apparatus in example 2.

Description of the reference numerals

First fermenter 1

Conveying system 2

Semi-permeable zone 3

First outlet 4

A third outlet 5

First inlet 6

Flow rate regulating device 7

Fifth outlet 8

Heating system 9

Material introduction system 10

Second fermenter 11

Fourth inlet 12

Blowback system 13

Second outlet 14

An eighth outlet 15

Ninth outlet 16

Fifth inlet 17

Second inlet 18

Fourth outlet 19

Sixth outlet 20

Seventh outlet 21

Third inlet 22

Detailed Description

The present invention will be more clearly and completely described below with reference to the accompanying drawings.

Example 1

As shown in fig. 1, the fermentation apparatus of an organic matter in this embodiment includes a first fermenter 1, a delivery system 2, and a semi-permeable zone 3 connected in sequence; the conveying system 2 is used for conveying the materials in the first fermentation tank 1 to the semi-permeable area 3; the semi-permeable area 3 is provided with a material with pores, the size of the pores of the material is 200 mu m-5 mm, and the material is used for separating the material in the first fermentation tank 1; the semi-permeable zone 3 is also provided with a loop connected with the first fermentation tank 1, and the loop is used for conveying the separated material with high solid content to the first fermentation tank 1.

The first fermentation tank 1 comprises a first inlet 6, a fifth inlet 17, a first outlet 4, a second outlet 14, a ninth outlet 16 and a first fermentation tank material output pipeline; the first inlet 6 is a feeding channel of the separated material with high solid content; the fifth inlet 17 is a feeding channel of the first fermentation tank 1 and is used for conveying the organic matters to be fermented to the first fermentation tank 1; one end of the first fermenter material output pipeline is connected with the first outlet 4 and is used for conveying the material of the first fermenter 1 to the semi-permeable zone 3 through the conveying system 2; the second outlet 14 is a gas collecting channel of the first fermenter 1; the ninth outlet 16 is a fermentation product discharge channel of the first fermentation tank 1, and is used for discharging the fermentation product out of the first fermentation tank 1. Wherein, the fresh organic matter to be fermented refers to the raw material to be treated which never enters the fermentation equipment for treatment.

Wherein the first inlet 6 is located at the upper part of the first fermenter 1.

Wherein the fifth inlet 17 is located at the upper part of the first fermenter 1.

Wherein the first outlet 4 is located at the lower part of the first fermenter 1.

Wherein the second outlet 14 is located at the upper part of the first fermenter 1.

Wherein the ninth outlet 16 is located at the lower portion of the first fermenter 1.

The first fermenter 1 is not provided with a stirring member therein.

The conveying system 2 can adjust the conveying speed of the materials. When the fermentation equipment is used, the material with high solid content separated in the semi-permeable zone 3 is conveyed back to the first fermentation tank 1. The semi-permeable area 3 is also provided with a pipeline for discharging the separated material with low solid content out of the semi-permeable area 3. Wherein, the low solid content rate means that the solid content rate is less than that of the material in the first fermentation tank 1, and the high solid content rate means that the solid content rate is greater than that of the material in the first fermentation tank 1.

Wherein, the semi-permeable zone 3 comprises a second inlet 18, a third outlet 5, a fourth outlet 19 and a high solid content material output pipeline; the second inlet 18 is connected with the other end of the first fermenter material output pipeline to form a feed channel of the semi-permeable zone 3; the third outlet 5 is a discharge channel of the material with low solid content; the fourth outlet 19 is a discharge channel of the material with high solid content; one end of the high solid content material output pipeline is connected with the fourth outlet 19, and the other end of the high solid content material output pipeline is connected with the first fermentation tank 1, and is used for conveying the separated high solid content material to the first fermentation tank 1.

The semi-permeable area 3 is a vertical device, and the second inlet 18 is positioned at the lower part of the semi-permeable area 3; the third outlet 5 is located at the lower part of the semi-permeable zone 3 and is higher than the second inlet 18; the height of the third outlet 5 from the bottom of the semi-permeable zone 3 accounts for 15% of the height of the semi-permeable zone 3; the fourth outlet 19 is located in the upper part of the semi-permeable zone 3.

The semi-permeable material in the semi-permeable zone 3 is cloth.

Example 2

As shown in fig. 2, the fermentation apparatus for an organic matter in this embodiment includes a first fermenter 1, a delivery system 2, and a semi-permeable zone 3 connected in sequence; the conveying system 2 is used for conveying the materials in the first fermentation tank 1 to the semi-permeable area 3; the semi-permeable area 3 is provided with a material with pores, the size of the pores of the material is 200 mu m-5 mm, and the material is used for separating the material in the first fermentation tank 1; the semi-permeable zone 3 is also provided with a loop connected with the first fermentation tank 1, and the loop is used for conveying the separated material with high solid content to the first fermentation tank 1.

The first fermentation tank 1 comprises a first inlet 6, a first outlet 4, a second outlet 14, a ninth outlet 16 and a first fermentation tank material output pipeline; the first inlet 6 is a feeding channel of the separated material with high solid content; one end of the first fermenter material output pipeline is connected with the first outlet 4 and is used for conveying the material of the first fermenter 1 to the semi-permeable zone 3 through the conveying system 2; the second outlet 14 is a gas collecting channel of the first fermenter 1; the ninth outlet 16 is a fermentation product discharge channel of the first fermentation tank 1, and is used for discharging the fermentation product out of the first fermentation tank 1. Wherein, the fresh organic matter to be fermented refers to the raw material to be treated which never enters the fermentation equipment for treatment.

Wherein the first inlet 6 is located at the upper part of the first fermenter 1.

Wherein the first outlet 4 is located at the lower part of the first fermenter 1.

Wherein the second outlet 14 is located at the upper part of the first fermenter 1.

Wherein the ninth outlet 16 is located at the lower portion of the first fermenter 1.

The first fermenter 1 is not provided with a stirring member therein.

The conveying system 2 can adjust the conveying speed of the materials. When the fermentation equipment is used, the material with high solid content separated in the semi-permeable zone 3 is conveyed back to the first fermentation tank 1. The semi-permeable area 3 is also provided with a pipeline for discharging the separated material with low solid content out of the semi-permeable area 3. Wherein, the low solid content rate means that the solid content rate is less than that of the material in the first fermentation tank 1, and the high solid content rate means that the solid content rate is greater than that of the material in the first fermentation tank 1.

Wherein, the semi-permeable zone 3 comprises a second inlet 18, a third outlet 5, a fourth outlet 19 and a high solid content material output pipeline; the second inlet 18 is connected with the other end of the first fermenter material output pipeline to form a feed channel of the semi-permeable zone 3; the third outlet 5 is a discharge channel of the material with low solid content; the fourth outlet 19 is a discharge channel of the material with high solid content; one end of the high solid content material output pipeline is connected with the fourth outlet 19. The fermentation device further comprises a flow rate regulating device 7, wherein the flow rate regulating device 7 is positioned between the fourth outlet 19 and the first inlet 6 and can regulate the flow rate of the material with high solid content in the semi-permeable zone 3. The other end of the high solid content material output pipeline is connected with the flow speed adjusting device 7, and the separated high solid content material is conveyed to the first fermentation tank 1.

The semi-permeable area 3 is a vertical device, and the second inlet 18 is positioned at the lower part of the semi-permeable area 3; the third outlet 5 is located at the lower part of the semi-permeable zone 3 and is higher than the second inlet 18; the height of the third outlet 5 from the bottom of the semi-permeable zone 3 accounts for 10% of the height of the semi-permeable zone 3; the fourth outlet 19 is located in the upper part of the semi-permeable zone 3.

The semi-permeable material in the semi-permeable zone 3 is stainless steel.

The semi-permeable zone 3 comprises a blow-back system 13, the blow-back system 13 being located in the upper part of the semi-permeable zone 3.

The fermentation device comprises a fifth outlet 8, the fifth outlet 8 is located between the fourth outlet 19 and the first inlet 6 and is a discharge channel for the fermentation product downstream of the semi-permeable zone 3.

The fermentation apparatus comprises a heating system 9, the heating system 9 being located between the fourth outlet 19 and the first inlet 6.

The fourth outlet 19 connects the semi-permeable zone 3 in turn with the flow rate regulating device 7, the fifth outlet 8 and the heating system 9.

The fermentation apparatus comprises a material introduction system 10, the material introduction system 10 being connected to the first inlet 6 for introducing fresh organic material to be fermented into the fermentation apparatus.

The fermentation equipment comprises a second fermentation tank 11; the second fermentation tank 11 comprises a third inlet 22, a sixth outlet 20, a seventh outlet 21, an eighth outlet 15, a low solid content material input pipeline and a second fermentation tank material output pipeline; one end of the low-solid-content material input pipeline is connected with the third outlet 5 of the semi-permeable zone 3, and the other end of the low-solid-content material input pipeline is connected with the third inlet 22, and is used for conveying the low-solid-content material to the second fermentation tank 11; the first fermenter 1 comprises a fourth inlet 12; one end of the second fermentation tank material output pipeline is connected with the sixth outlet 20, and the other end of the second fermentation tank material output pipeline is connected with the fourth inlet 12, and is used for conveying part of the material of the second fermentation tank 11 back to the first fermentation tank 1; the seventh outlet 21 is used for discharging the residual materials of the second fermentation tank 11 out of the second fermentation tank 11; the eighth outlet 15 is a gas collection channel of the second fermenter 11.

Wherein the third inlet 22 is located in the lower part of the second fermenter 11.

Wherein the fourth inlet 12 is located at the upper part of the first fermenter 1.

Wherein the sixth outlet 20 is located in the upper part of the second fermenter 11.

Wherein the seventh outlet 21 is located in the upper part of the second fermenter 11.

Wherein the eighth outlet 15 is located in the upper part of the second fermenter 11.

Application example 1

Using the apparatus of example 1, the volume of the first fermenter 1 was 60m³。

Can treat 10 tons of cow dung every day. Can generate 900m per day³Biogas, which contains 55% methane. 5.8 tons of liquid organic fertilizer can be discharged from the semi-permeable zone 3. 3 tons of solid organic fertilizer can be discharged from the first fermenter 1 every day.

The solid content in the first fermenter 1 was maintained at 22%. The material quantity circularly conveyed by the conveying system 2 every day is 90m³。

Application example 2

Using the apparatus of example 2, the volume of the first fermenter 1 was 20m³. The volume of the second fermenter 11(UASB type fermenter) was 10m³。

And 5 tons of sorted urban organic garbage (containing kitchen garbage) are treated.

Can generate 930m each day³The biogas of (2), wherein the biogas contains 58% of methane.

Discharging 0.22 tons of solid organic fertilizer from the first fermenter 1 every day; the flow rate of the liquid organic fertilizer discharged from the second fermentation tank 11 was 3.6 tons.

The solids content in the first fermenter 1 was maintained at 18%. The material quantity circularly conveyed by the conveying system 2 every day is 40m³. The flow rate of the feed from the second fermenter 11 to the first fermenter 1 is 10m per day³。

Claims (10)

1. The fermentation equipment of the organic matter is characterized by comprising a first fermentation tank, a conveying system and a semi-permeable area which are sequentially connected; the conveying system is used for conveying the materials in the first fermentation tank to the semi-permeable area; the semi-permeable area is provided with a material with pores, the size of the pores is 200 mu m-5 mm, and the material is used for separating the material in the first fermentation tank; the semi-permeable area is also provided with a loop connected with the first fermentation tank, and the loop is used for conveying the separated material with high solid content to the first fermentation tank.

2. The organic matter fermenting apparatus of claim 1, wherein the first fermenter is not provided with a stirring member therein.

3. The organic matter fermenting apparatus of claim 1, wherein the semi-permeable region is further provided with a pipeline for discharging the separated low solid content material out of the semi-permeable region;

the semi-permeable material in the semi-permeable area is cloth, stainless steel, plastic or ceramic.

4. The organic matter fermenting apparatus of claim 1, wherein said first fermenter comprises a first inlet, a fifth inlet, a first outlet, a second outlet, a ninth outlet, and a first fermenter material output pipe; the first inlet is a feeding channel of the separated material with high solid content; the fifth inlet is a feeding channel of the first fermentation tank and is used for conveying the fresh organic matters to be fermented into the first fermentation tank; one end of the first fermenter material output pipeline is connected with the first outlet and is used for conveying the material of the first fermenter to the semi-permeable area through the conveying system; the second outlet is a gas collecting channel of the first fermentation tank; the ninth outlet is a fermentation product discharge channel of the first fermentation tank and is used for discharging a fermentation product out of the first fermentation tank;

the semi-permeable area comprises a second inlet, a third outlet, a fourth outlet and a high solid content material output pipeline; the second inlet is connected with the other end of the first fermentation tank material output pipeline to form a feeding channel of the semi-permeable area; the third outlet is a discharge channel of the material with low solid content; the fourth outlet is a discharge channel of the material with high solid content; one end of the high solid content material output pipeline is connected with the fourth outlet, and the other end of the high solid content material output pipeline is connected with the first fermentation tank and used for conveying the separated high solid content material to the first fermentation tank;

the semi-permeable zone is an inclined, snake-shaped, vertical or horizontal device.

5. The fermentation apparatus for organic matter of claim 4, wherein when the semi-permeable zone is a horizontal apparatus, the horizontal apparatus is a serpentine pipe;

when the semi-permeable zone is a vertical device, the second inlet is positioned at the lower part of the semi-permeable zone; the third outlet is positioned at the lower part of the semi-permeable zone and is higher than the second inlet; the fourth outlet is located at the upper part of the semi-permeable zone;

the semi-permeable zone includes a blow-back system.

6. The organic matter fermenting apparatus of claim 5, wherein said first inlet is located at an upper portion of said first fermenter;

the fifth inlet is positioned at the upper part of the first fermentation tank;

the first outlet is positioned at the lower part of the first fermentation tank;

the second outlet is positioned at the upper part of the first fermentation tank;

the ninth outlet is positioned at the lower part of the first fermentation tank;

the height of the third outlet from the bottom of the semi-permeable zone is within 15% of the height of the semi-permeable zone;

when the semi-permeable area is vertical equipment, the back blowing system is positioned at the upper part of the semi-permeable area.

7. The organic matter fermenting apparatus of claim 6, wherein the first inlet and the fifth inlet of the first fermenter are the same inlet;

the fermentation apparatus comprises a flow rate adjustment apparatus located between the fourth outlet and the first inlet;

the fermentation equipment comprises a fifth outlet, the fifth outlet is positioned between the fourth outlet and the first inlet and is a discharge channel of a downstream fermentation product of the semi-permeable zone;

the fermentation apparatus comprises a heating system located between the fourth outlet and the first inlet;

the fermentation equipment comprises a material introducing system, and the material introducing system is connected with the first inlet or the fifth inlet and is used for introducing fresh organic matters to be fermented into the fermentation equipment.

8. The organic matter fermenting apparatus of claim 7, wherein said fourth outlet connects said semi-permeable zone to said flow rate regulating apparatus, said fifth outlet and said heating system in that order.

9. The fermentation apparatus of an organic substance of claim 1, wherein the fermentation apparatus comprises a second fermentor; the second fermentation tank comprises a third inlet, a sixth outlet, a seventh outlet, an eighth outlet, a low solid content material input pipeline and a second fermentation tank material output pipeline; one end of the low-solid-content material input pipeline is connected with the semi-permeable area, and the other end of the low-solid-content material input pipeline is connected with the third inlet and is used for conveying the low-solid-content material to the second fermentation tank; the first fermenter comprises a fourth inlet; one end of the second fermentation tank material output pipeline is connected with the sixth outlet, and the other end of the second fermentation tank material output pipeline is connected with the fourth inlet, and is used for conveying part of the second fermentation tank material back to the first fermentation tank; the seventh outlet is used for discharging the residual materials of the second fermentation tank out of the second fermentation tank; the eighth outlet is a gas collection channel of the second fermentor.

10. The organic matter fermenting apparatus of claim 9, wherein said third inlet is located at a lower portion of said second fermenter;

the fourth inlet is positioned at the upper part of the first fermentation tank;

the sixth outlet is located at the upper part of the second fermenter;

the seventh outlet is located at the upper part of the second fermenter;

the eighth outlet is located at an upper portion of the second fermenter.

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