CN216947014U - In-situ ecological fermentation system - Google Patents

Abstract

The utility model discloses an in-situ ecological fermentation system, which comprises a body, wherein the body also comprises a crushing bin, a first stirring bin, a storage bin, a domestic sewage recovery tank, an intelligent control bin, an aeration system, a waste liquid recovery chamber, a UM bacteria liquid chamber, an overhauling machine position, a second stirring bin, a liquid collecting tank, a liquid bin, a catch basin, a conveying belt, a liquid collecting recovery pipeline, a high-pressure aeration pipeline, a UM bacteria liquid spraying pipeline and a cable bridge frame, wherein auxiliary conveying belts are respectively arranged among the first stirring bin, the crushing bin and the storage bin, and the aeration system, the waste liquid recovery chamber and the UM bacteria liquid chamber are all arranged in the intelligent control bin. The problem of difficult recovery and centralized treatment of the highly dispersed tail end is solved, and the method has certain use value and popularization value.

Description

In-situ ecological fermentation system

Technical Field

The utility model relates to the technical field of ecological fermentation, in particular to an in-situ ecological fermentation system.

Background

At present, organic wastes such as straws, garden trimming materials and the like in non-flaky large-scale agricultural production areas of Jianghu, Zhejiang Shanghai and the like are diversified, the highly dispersed tail end is difficult to recover and concentrate, and the traditional treatment mode has the defects of large floor area, trouble in transportation, incapability of in-situ treatment and the like.

In view of the above, there is a need for an in situ ecological fermentation system that addresses the deficiencies of the prior art.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects of the prior art, the utility model provides an in-situ ecological fermentation system, which aims to solve the problems.

In order to achieve the purpose, the utility model provides the following technical scheme: an in-situ ecological fermentation system comprises a body, wherein the body further comprises a crushing bin, a first stirring bin, a storage bin, a domestic sewage recovery tank, a smart control bin, an aeration system, a waste liquid recovery chamber, a UM bacteria liquid chamber, an overhauling machine position, a second stirring bin, a liquid collecting tank, a liquid bin, a catch water ditch, a conveying belt, a liquid collecting recovery pipeline, a high-pressure aeration pipeline, a UM bacteria liquid spraying pipeline and a cable bridge frame, auxiliary conveying belts are further arranged between the first stirring bin and the crushing bin as well as between the first stirring bin and the storage bin, the aeration system, the waste liquid recovery chamber and the UM bacteria liquid chamber are all arranged in the smart control bin, and the conveying belt is arranged between the first stirring bin and the second stirring bin;

the aeration system is communicated with the liquid collecting tank through a high-pressure aeration pipeline, the waste liquid recovery chamber is communicated with the second stirring bin through a liquid collecting recovery pipeline, the UM bacteria liquid chamber is communicated with the second stirring bin through an UM bacteria liquid spraying pipeline, and one end, close to the second stirring bin, of the UM bacteria liquid spraying pipeline is connected with a plurality of spraying branch pipes.

Preferably, one side of the first stirring bin is connected to the liquid bin through a conduit.

Preferably, the overhaul machine position and the second stirring bin form an aerobic fermentation bin of the system.

Preferably, the discharge gate of smashing the storehouse and passing through auxiliary conveyor and connect in the feed inlet of first stirring storehouse, the clout export of first stirring storehouse passes through auxiliary conveyor and connects in the feed inlet of storage silo, and the main discharge gate of first stirring storehouse passes through the conveyer belt and connects in second stirring storehouse.

Preferably, the aerobic fermentation bin consisting of the maintenance machine position and the second stirring bin is connected to the intelligent control bin through a water intercepting ditch and a cable bridge.

Preferably, the liquid collecting tank is designed for solid-liquid separation, and is further provided with a built-in pump body, the liquid collecting tank is supplied and communicated with the second stirring bin in a single direction through a guide pipe, the seepage in the second stirring bin is further recovered to the liquid collecting tank through a bottom pipeline system, and when the liquid level of the liquid collecting tank is higher than a certain threshold value, the built-in pump body conveys the recovered UM bacterial liquid back to the waste liquid recovery chamber.

The utility model has the beneficial effects that: and has certain use value and popularization value.

Drawings

Fig. 1 is a schematic block diagram of a system plane structure of the present invention.

In the figure: 100-body, 1-crushing bin, 2-first stirring bin, 3-storage bin, 4-domestic sewage recovery tank, 5-intelligent control bin, 6-aeration system, 7-waste liquid recovery chamber, 8-UM bacteria liquid chamber, 9-maintenance machine position, 10-second stirring bin, 11-liquid collecting tank, 12-liquid bin, 13-intercepting ditch, 14-conveying belt, 15-liquid collecting recovery pipeline, 16-high pressure aeration pipeline, 17-UM bacteria liquid spraying pipeline and 18-cable bridge.

Detailed Description

As shown in fig. 1, an in-situ ecological fermentation system comprises a body 100, wherein the body 100 further comprises a crushing bin 1, a first stirring bin 2, a storage bin 3, a domestic sewage recovery tank 4, a smart control bin 5, an aeration system 6, a waste liquid recovery chamber 7, an UM bacteria liquid chamber 8, an overhaul stand 9, a second stirring bin 10, a liquid collecting tank 11, a liquid bin 12, a catch basin 13, a conveyor belt 14, a liquid collecting recovery pipeline 15, a high-pressure aeration pipeline 16, an UM bacteria liquid spraying pipeline 17 and a cable bridge 18, wherein auxiliary conveyor belts are respectively arranged between the first stirring bin 2 and the crushing bin 1 as well as between the storage bin 3, the aeration system 6, the waste liquid recovery chamber 7 and the UM bacteria liquid chamber 8 are respectively arranged in the control bin 5, and the conveyor belt 14 is arranged between the first stirring bin 2 and the second stirring bin 10;

the aeration system 6 is communicated with the liquid collecting tank 11 through a high-pressure aeration pipeline 16, the waste liquid recovery chamber 7 is communicated with the second stirring bin 10 through a liquid collecting recovery pipeline 15, the UM bacteria liquid chamber 8 is communicated with the second stirring bin 10 through an UM bacteria liquid spraying pipeline 17, and one end, close to the second stirring bin 10, of the UM bacteria liquid spraying pipeline 17 is connected with a plurality of spraying branch pipes.

Further, one side of the first stirring chamber 2 is connected to the liquid chamber 12 through a conduit.

Furthermore, the maintenance machine station 9 and the second stirring bin 10 form an aerobic fermentation bin of the system.

Further, the discharge gate of smashing storehouse 1 is connected in the feed inlet of first stirring storehouse 2 through supplementary conveyer belt, and the clout export of first stirring storehouse 2 is connected in the feed inlet of storage silo 3 through supplementary conveyer belt, and the main discharge gate of first stirring storehouse 2 passes through conveyer belt 14 and connects in second stirring storehouse 10.

Furthermore, an aerobic fermentation bin consisting of the maintenance machine position 9 and the second stirring bin 10 is connected with the intelligent control bin 5 through a water intercepting ditch 13 and a cable bridge 18.

Further, liquid collecting tank 11 is designed for solid-liquid separation, and liquid collecting tank 11 still is equipped with the built-in pump body, and liquid collecting tank 11 feeds through in second stirring storehouse 10 through the pipe unilateral supply, and the inside sepage of second stirring storehouse 10 still retrieves to liquid collecting tank 11 through bottom pipe-line system, and when liquid level of liquid collecting tank 11 was higher than certain threshold value, the built-in pump body carried the UM fungus liquid after retrieving back to waste liquid recovery room 7.

The working principle of the utility model is as follows: when the system is used, the wastes of corn stalks, straws and livestock breeding are collected, then the in-situ ecological fermentation system is used for processing, the solid-liquid state is separated, the solid wastes are crushed in the crushing bin 1, and the liquid directly exists in the liquid bin 12; after the solid liquid is collected and smashed according to types, the solid liquid can be stirred through the first stirring bin 2 according to different formulas, redundant liquid is stored in the storage bin 3, the first stirring bin 2 is stirred to form a semi-finished product, the semi-finished product enters an aerobic fermentation bin consisting of an overhauling machine position 9 and a second stirring bin 10 in the later processing process, and besides a mixed material obtained by smashing and stirring organic waste, other nutrition starters are added into the aerobic fermentation bin: organic matters with high nutrient nutrients such as bean paste and bean dregs are mixed, UM engineering bacteria in an UM bacteria liquid chamber 8 are sprayed into an aerobic fermentation chamber for stirring through an intelligent control chamber 5 and a UM bacteria liquid spraying pipeline 17 in the fermentation process in the aerobic fermentation chamber, and oxygen with proper concentration in the fermentation process is introduced while stirring and fermenting; on the basis of guaranteeing proper material feeding, oxygen proportioning and proper growth conditions of bacteria, the humiture and the oxygen concentration in the fermentation process are in the optimal proportion to specific engineering bacteria through a closed environment, namely the humiture adjustment of the closed environment of the fermentation chamber of the overhauling machine station 9 and the second stirring chamber 10, and almost no waste gas and waste water are discharged in the whole process, so that the produced engineering product is in a state which is very beneficial to the growth of the engineering product, and the whole fermentation process is accelerated.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents or improvements made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (6)

1. An in-situ ecological fermentation system comprises a body (100), and is characterized in that the body (100) further comprises a crushing bin (1), a first stirring bin (2), a storage bin (3), a domestic sewage recovery tank (4), a smart control bin (5), an aeration system (6), a waste liquid recovery chamber (7), a UM bacteria liquid chamber (8), an overhauling machine position (9), a second stirring bin (10), a liquid collecting tank (11), a liquid bin (12), a water intercepting ditch (13), a conveyor belt (14), a liquid collecting recovery pipeline (15), a high-pressure aeration pipeline (16), a UM bacteria liquid spraying pipeline (17) and a cable bridge (18), wherein auxiliary conveyor belts are respectively arranged between the first stirring bin (2) and the crushing bin (1) as well as between the first stirring bin (3) and the storage bin (3), and the aeration system (6), the waste liquid recovery chamber (7) and the UM bacteria liquid chamber (8) are arranged in the smart control bin (5), the conveying belt (14) is arranged between the first stirring bin (2) and the second stirring bin (10);

aeration system (6) communicate in collecting tank (11) through high-pressure aeration pipeline (16), waste liquid recovery room (7) communicate in second stirring storehouse (10) through collection liquid recovery pipeline (15), UM fungus liquid chamber (8) communicate in second stirring storehouse (10) through UM fungus liquid spray pipe (17), and the one end that UM fungus liquid spray pipe (17) is close to second stirring storehouse (10) is connected with a plurality of spray branch pipes.

2. The in-situ ecological fermentation system according to claim 1, wherein one side of the first stirring bin (2) is connected to the liquid bin (12) through a conduit.

3. The in-situ ecological fermentation system according to claim 1, wherein the maintenance machine (9) and the second stirring bin (10) constitute an aerobic fermentation bin of the system.

4. The in-situ ecological fermentation system according to claim 1, wherein the discharge port of the crushing bin (1) is connected to the feed port of the first stirring bin (2) through an auxiliary conveyor belt, the residue outlet of the first stirring bin (2) is connected to the feed port of the storage bin (3) through an auxiliary conveyor belt, and the main discharge port of the first stirring bin (2) is connected to the second stirring bin (10) through a conveyor belt (14).

5. An in-situ ecological fermentation system according to any one of claims 1 and 3, wherein the aerobic fermentation chamber formed by the maintenance machine (9) and the second stirring chamber (10) is connected to the intelligent control chamber (5) through a water cut-off ditch (13) and a cable bridge (18).

6. The in-situ ecological fermentation system according to claim 1, wherein the liquid collecting tank (11) is designed for solid-liquid separation, and the liquid collecting tank (11) is further provided with a built-in pump body, the liquid collecting tank (11) is communicated with the second stirring bin (10) through a conduit in a single direction, the seepage liquid in the second stirring bin (10) is further recovered to the liquid collecting tank (11) through a bottom pipeline system, and when the liquid level of the liquid collecting tank (11) is higher than a certain threshold value, the built-in pump body conveys the recovered UM bacterial liquid back to the waste liquid recovery chamber (7).

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