CN217809216U - Continuous high-temperature aerobic organic matter fermentation, drying and recycling system - Google Patents

Abstract

The utility model discloses a continuous high temperature good oxygen organic matter fermentation mummification resourceful system, which comprises a tank body, the internal division board that is fixed with six layers of equidistance and distributes of jar, the fixed embedding has the axle sleeve on the division board, the axle sleeve internal rotation is provided with the (mixing) shaft, be fixed with the stirring leaf that corresponds every layer on the (mixing) shaft, be fixed with the closing cap on the jar body, the fixed embedding on the closing cap has first bearing, (mixing) shaft and first bearing interference fit, be fixed with first motor on the closing cap, the pivot of first motor passes through the shaft coupling with the (mixing) shaft and fixes, be fixed with the feed inlet on the closing cap. The utility model discloses a six layers of layered design and set up between six layers and add the fungus mouth, can improve the quality of organic matter mummification resourceization, can carry out the even stirring to the organic material of each layer through the stirring leaf, be provided with the discharge gate on the division board of each layer and can carry out opening of baffle according to the actual number of days and use.

Description

Continuous high-temperature aerobic organic matter fermentation, drying and recycling system

Technical Field

The utility model relates to an good oxygen organic matter mummification technical field specifically is a continuous high temperature good oxygen organic matter fermentation mummification resourceful system.

Background

The aerobic organic matters reduce the oxygen content in the space, so that aquatic animals and plants die to cause water body odor, and the anaerobic microorganisms propagate in a large quantity and are subjected to putrefactive fermentation, so that bacteria grow, the water quality is deteriorated, and the water body is damaged.

According to an authorized bulletin number CN202010797456 with fungus device for bio-organic fertilizer production, including running gear, scatter the mechanism, weighing machine constructs and material storage mechanism, can drive the device through running gear and move in fermentation vat one side, material in the material storage tank can fall to weighing machine structure after the solenoid valve is opened, thereby weigh predetermined bacterial weight, can empty the second transmission path with the bacterial of weighing in the frame through electronic telescoping cylinder in, later the bacterial gets into in scattering the case of mechanism, start the fan and blow off the bacterial from the defeated material passageway to the fermentation vat in. The invention has the advantages of weighing the bacteria adding amount, realizing uniform dispersion and scattering, having high automation degree and being capable of remotely controlling the bacteria adding work, and is mainly used for adding bacteria during the production of organic fertilizers.

CN201920202134 the present disclosure relates to the treatment of food and feed production sidestreams, and more particularly to an apparatus for producing bioactive organic products from food and/or feed production sidestreams, comprising: a container (3); an inlet (4); an outlet (5); a buffer tank (33); a support device (7); a mobile device (10); a supply device (11); a gas discharge device (16); a gas recirculation device (43); and a recovery device (13).

The above all are devices for producing organic matters, but in order to ensure the drying and recycling quality of the aerobic organic matters in the production process, the devices need to be improved in a layered manner so as to meet the production requirements.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a continuous high temperature good oxygen organic matter fermentation mummification resourceful system to solve the problem to organic matter apparatus for producing layering improvement.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a continuous high temperature good oxygen organic matter fermentation mummification resourceful system, which comprises a tank body, the internal division board that has six layers of equidistance and distributes that is fixed with of jar, the fixed embedding has the axle sleeve on the division board, the axle sleeve internal rotation is provided with the (mixing) shaft, be fixed with the stirring leaf that corresponds every layer on the (mixing) shaft, be fixed with the closing cap on the jar body, fixed embedding has first bearing on the closing cap, (mixing) shaft and first bearing interference fit, be fixed with first motor on the closing cap, the pivot of first motor passes through the shaft coupling with the (mixing) shaft and fixes, be fixed with the feed inlet on the closing cap.

Preferably, the closing cap is fixedly embedded with a first bacterium adding port, the tank body is fixedly embedded with a second bacterium adding port, bacterium can be added in a segmented manner, and the quality of dried resources is improved.

Preferably, the partition plate is provided with a discharge port, built-in grooves are formed in two sides of the inner wall of the discharge port, baffles are arranged in the built-in grooves in a sliding mode, a cylinder body is fixed on the inner wall of each built-in groove, and a piston rod of the cylinder body is fixedly connected with the baffles, so that materials can be transferred when the materials need to be discharged.

Preferably, the lower extreme of the jar body is fixed with the base, and fixed embedding has the second bearing on the base, and interference fit has the drive shaft in the second bearing, and the winding has first flight in the drive shaft, is fixed with the second motor on the outer wall of the jar body, and the pivot of second motor passes through the shaft coupling with the drive shaft to be fixed, guarantees the rotational stability of drive shaft.

Preferably, the fixed embedding in one side of base has the passageway, and the one end of passageway is fixed with the backup pad, and the fixed embedding in backup pad has the third bearing, and the fixed embedding in the passageway has the feed opening, guarantees the rotational stability of back shaft.

Preferably, a supporting shaft is arranged on the third bearing in an interference fit mode, and a second spiral sheet is wound on the supporting shaft, so that spiral feeding in the obliquely upward direction can be achieved.

Preferably, be fixed with the third motor in the backup pad, the pivot of third motor passes through the shaft coupling with the back shaft to be fixed, and first motor, second motor and third motor are step reduction machine type, and pass through wire plug and the circular telegram of indoor 220V power strip grafting.

Preferably, the fixed branch pipe that corresponds each layer on the jar body, the fixed embedding has the solenoid valve on the branch pipe, and the other end of branch pipe is fixed to be communicated with has the blast pipe, and the winding has the electrothermal tube on the blast pipe, and the electrothermal tube is electric heating pipe, can carry out high temperature heating to the blast pipe, reduces the emission of steam.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses a six layers of layered design and set up between six layers and add the fungus mouth, can improve the quality of organic matter mummification resourceization.

2. The utility model discloses a stirring leaf can evenly stir the organic material of each layer, is provided with the discharge gate on the division board of each layer and can carries out opening of baffle according to the actual number of days and use.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is an enlarged schematic view of the utility model at a;

fig. 3 is a schematic view of a third motor part according to the present invention.

In the figure: 1. a tank body; 11. a partition plate; 12. a shaft sleeve; 13. a stirring shaft; 14. stirring blades; 15. sealing the cover; 16. a first bearing; 17. a first motor; 18. a feed inlet; 2. a first bacterium adding port; 21. a second bacterium adding port; 22. a discharge port; 23. a built-in groove; 24. a cylinder body; 25. a baffle plate; 3. a base; 31. a second bearing; 32. a drive shaft; 33. a second motor; 34. a first helical flight; 4. a channel; 41. a support plate; 42. a third bearing; 43. a support shaft; 44. a second flight; 45. a third motor; 46. a feeding port; 5. pipe distribution; 51. an exhaust pipe; 52. an electric heating tube; 53. an electromagnetic valve.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example I

Referring to fig. 1, a continuous high-temperature aerobic organic matter fermentation, drying and recycling system includes a tank body 1, six layers of partition plates 11 are fixed in the tank body 1 and are distributed equidistantly, shaft sleeves 12 are fixed on the partition plates 11, stirring shafts 13 are rotatably arranged in the shaft sleeves 12, stirring blades 14 corresponding to each layer are fixed on the stirring shafts 13, a sealing cover 15 is fixed on the tank body 1, first bearings 16 are fixed on the sealing cover 15, the stirring shafts 13 are in interference fit with the first bearings 16, first motors 17 are fixed on the sealing covers 15, rotating shafts of the first motors 17 are fixed with the stirring shafts 13 through shaft couplings, and feed inlets 18 are fixed on the sealing cover 15.

Referring to fig. 1, a first bacteria adding port 2 is fixedly embedded in the sealing cover 15, and a second bacteria adding port 21 is fixedly embedded in the tank body 1, so that bacteria can be added in a segmented manner, and the drying and recycling quality can be improved.

The two second bacterium adding openings 21 correspond to the third layer and the fifth layer respectively.

Referring to fig. 1 and 2, a discharge port 22 is arranged on the partition plate 11, built-in grooves 23 are arranged on both sides of the inner wall of the discharge port 22, baffles 25 are slidably arranged in the built-in grooves 23, a cylinder body 24 is fixed on the inner wall of the built-in grooves 23, and a piston rod of the cylinder body 24 is fixedly connected with the baffles 25, so that materials can be discharged when the materials need to be discharged.

This embodiment is used: division board 11 separates the jar body 1 for six layers of compounding layers, corresponds six days, after finishing every day, carries out the material through discharge gate 22 and transfers, can realize continuous processing.

Organic fertilizer fermentation technology: the livestock and poultry manure, the biological fermentation bed padding and the like are decomposed and matured in a short time by biological aerobic fermentation to achieve harmless treatment.

After being crushed into fine powder by a crusher of organic fertilizer production equipment, the prepared materials enter a stirrer to be mixed, and finally are conveyed to a granulator for granulation through conveying equipment.

The powdery material is added into a disc granulator for granulation by a conveyer, the granulation is completed by a granulation process by a granulation method, and the material discharged from the disc granulator is sent into an organic fertilizer dryer by the conveyer for drying.

The dust-containing and moisture-containing waste gas is extracted from the discharge port by an exhaust fan, is dedusted by a deduster, is discharged into the atmosphere through a chimney, and is cooled after being collected by the dried material.

The granule after fertilizer equipment technology cooling directly gets into drum screening machine, and fertilizer production line finished product flows from lower floor's sieve discharge gate, and fertilizer granulation equipment gets into one production process down, and fertilizer production line large granule flows out from the upper strata, smashes the back and granulate, screens again, and fertilizer equipment tiny particle spills from lower floor's screen cloth and returns and granulate again.

Example II

Referring to fig. 1, in this embodiment, as further described in example 1, a continuous high-temperature aerobic organic matter fermentation, drying and recycling system includes a tank 1, six layers of partition plates 11 are fixed in the tank 1, which are equidistantly distributed, a shaft sleeve 12 is fixed on the partition plates 11, a stirring shaft 13 is rotatably disposed in the shaft sleeve 12, stirring blades 14 corresponding to each layer are fixed on the stirring shaft 13, a sealing cover 15 is fixed on the tank 1, a first bearing 16 is fixed on the sealing cover 15, the stirring shaft 13 is in interference fit with the first bearing 16, a first motor 17 is fixed on the sealing cover 15, a rotating shaft of the first motor 17 is fixed to the stirring shaft 13 through a coupling, and a feed port 18 is fixed on the sealing cover 15.

Referring to fig. 1 and 3, a channel 4 is fixedly embedded in one side of the base 3, a support plate 41 is fixed at one end of the channel 4, a third bearing 42 is fixedly embedded in the support plate 41, and a feed opening 46 is fixedly embedded in the channel 4 to ensure the stable rotation of the support shaft 43.

Referring to fig. 1 and 3, a supporting shaft 43 is in interference fit with the third bearing 42, and a second spiral sheet 44 is wound on the supporting shaft 43, so that spiral feeding in an obliquely upward direction can be realized.

Referring to fig. 1 and 3, a third motor 45 is fixed on the support plate 41, a rotating shaft of the third motor 45 is fixed with the support shaft 43 through a coupling, and the first motor 17, the second motor 33 and the third motor 45 are all of a step-down gear type and are connected with an indoor 220V power strip through a wire plug.

This embodiment is used: through spiral feeding at two ends, the materials can be stably conveyed during discharging.

Example III

Referring to fig. 1, the present embodiment further illustrates another embodiment, a continuous high-temperature aerobic organic matter fermentation, drying and recycling system includes a tank 1, six layers of partition plates 11 are fixed in the tank 1, the partition plates 11 are equidistantly distributed, shaft sleeves 12 are fixed on the partition plates 11, stirring shafts 13 are rotatably arranged in the shaft sleeves 12, stirring blades 14 corresponding to each layer are fixed on the stirring shafts 13, a sealing cover 15 is fixed on the tank 1, a first bearing 16 is fixed on the sealing cover 15, the stirring shafts 13 are in interference fit with the first bearing 16, a first motor 17 is fixed on the sealing cover 15, a rotating shaft of the first motor 17 is fixed with the stirring shafts 13 through a coupling, and a feed inlet 18 is fixed on the sealing cover 15.

Referring to fig. 1, a first bacteria adding port 2 is fixedly embedded in the sealing cover 15, and a second bacteria adding port 21 is fixedly embedded in the tank body 1, so that bacteria can be added in a segmented manner, and the drying and recycling quality can be improved.

Referring to fig. 1 and 2, a discharge port 22 is arranged on the partition plate 11, built-in grooves 23 are arranged on both sides of the inner wall of the discharge port 22, baffles 25 are slidably arranged in the built-in grooves 23, a cylinder body 24 is fixed on the inner wall of the built-in grooves 23, and a piston rod of the cylinder body 24 is fixedly connected with the baffles 25, so that materials can be discharged when the materials need to be discharged.

Referring to fig. 1, a base 3 is fixed at the lower end of a tank body 1, a second bearing 31 is fixed on the base 3, a driving shaft 32 is arranged in the second bearing 31 in an interference fit manner, a first spiral sheet 34 is wound on the driving shaft 32, a second motor 33 is fixed on the outer wall of the tank body 1, and a rotating shaft of the second motor 33 is fixed with the driving shaft 32 through a coupling, so that the stable rotation of the driving shaft 32 is ensured.

Referring to fig. 1 and 3, a channel 4 is fixedly embedded in one side of the base 3, a support plate 41 is fixed at one end of the channel 4, a third bearing 42 is fixedly embedded in the support plate 41, and a feed opening 46 is fixedly embedded in the channel 4 to ensure the stable rotation of the support shaft 43.

Referring to fig. 1 and 3, a support shaft 43 is in interference fit with the third bearing 42, and a second spiral sheet 44 is wound on the support shaft 43, so that spiral feeding in an obliquely upward direction can be realized.

Referring to fig. 1 and 3, a third motor 45 is fixed on the supporting plate 41, a rotating shaft of the third motor 45 is fixed with the supporting shaft 43 through a coupler, and the first motor 17, the second motor 33 and the third motor 45 are all of a step-down gear type and are connected with an indoor 220V power strip through a wire plug in a plugging manner.

Referring to fig. 1, the branch pipes 5 corresponding to each layer are fixed on the tank body 1, the electromagnetic valves 53 are fixed on the branch pipes 5, the exhaust pipes 51 are fixedly communicated with the other ends of the branch pipes 5, the electric heating pipes 52 are wound on the exhaust pipes 51, and the electric heating pipes 52 are electric heating pipes and can heat the exhaust pipes 51 at high temperature to reduce the emission of water vapor.

In use, the present embodiment: carry out the raw materials through feed inlet 18 and carry, then start first motor 17, first motor 17 drives (mixing) shaft 13 and rotates for stirring leaf 14 stirs the raw materials, can add the fungus to the mixture of first layer through first fungus mouth 2 that adds.

When the material is required to be discharged, the piston rod of the cylinder body 24 retracts, the baffle 25 on the partition plate 11 of the first layer is opened, the material is discharged through the corresponding discharge hole 22, the second motor 33 and the third motor 45 are respectively started after the material is discharged from the discharge hole 22 of the partition plate 11 of the last layer, the spiral material feeding is realized through the rotation of the two spiral pieces, and the material is finally collected through the discharge hole 46.

When each layer is stirred at high temperature, water vapor enters the exhaust pipe 51 through the branch pipes 5, the electromagnetic valve 53 can control the water vapor transmission of each branch pipe 5, and finally the water vapor is discharged through the exhaust pipe 51 and is locally heated by the electric heating pipe 52 with the spiral structure, so that the water vapor is evaporated, and the influence of the water vapor on the humidity of the surrounding environment is reduced.

It should be noted that, in this document, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a continuous high temperature is good for fermentation mummification resource system of organic matter, includes jar body (1), its characterized in that: the utility model discloses a stirring tank, including the jar body (1), division board (11) that the internal fixation has six layers of equidistance to distribute, fixed embedding has axle sleeve (12) on division board (11), axle sleeve (12) internal rotation is provided with (mixing) shaft (13), be fixed with stirring leaf (14) that correspond every layer on (mixing) shaft (13), be fixed with closing cap (15) on the jar body (1), fixed embedding has first bearing (16) on closing cap (15), (mixing) shaft (13) and first bearing (16) interference fit, be fixed with first motor (17) on closing cap (15), the pivot of first motor (17) is fixed through the shaft coupling with (mixing) shaft (13), be fixed with feed inlet (18) on closing cap (15).

2. The continuous high-temperature aerobic organic matter fermentation, drying and recycling system as claimed in claim 1, wherein: the first fungus mouth (2) that adds is fixed to be embedded into on closing cap (15), the jar body (1) is fixed to be embedded into has the second to add fungus mouth (21).

3. The continuous high-temperature aerobic organic matter fermentation, drying and recycling system as claimed in claim 1, wherein: the automatic discharging device is characterized in that a discharging port (22) is formed in the partition plate (11), built-in grooves (23) are formed in two sides of the inner wall of the discharging port (22), baffles (25) are arranged in the built-in grooves (23) in a sliding mode, a cylinder body (24) is fixed on the inner wall of each built-in groove (23), and a piston rod of each cylinder body (24) is fixedly connected with the corresponding baffle (25).

4. The continuous high-temperature aerobic organic matter fermentation, drying and recycling system as claimed in claim 1, wherein: the lower extreme of the jar body (1) is fixed with base (3), and it has second bearing (31) to fix the embedding on base (3), and interference fit has drive shaft (32) in second bearing (31), and the winding has first flight (34) on drive shaft (32), is fixed with second motor (33) on the outer wall of the jar body (1), and the pivot of second motor (33) is fixed through the shaft coupling with drive shaft (32).

5. The continuous high-temperature aerobic organic matter fermentation, drying and recycling system as claimed in claim 4, wherein: one side of base (3) is fixed to be embedded in has passageway (4), and the one end of passageway (4) is fixed with backup pad (41), and fixed embedding has third bearing (42) on backup pad (41), and fixed embedding has feed opening (46) on passageway (4).

6. The continuous high-temperature aerobic organic matter fermentation, drying and recycling system as claimed in claim 5, wherein: a supporting shaft (43) is arranged on the third bearing (42) in an interference fit mode, and a second spiral sheet (44) is wound on the supporting shaft (43).

7. The continuous high-temperature aerobic organic matter fermentation, drying and recycling system as claimed in claim 6, wherein: a third motor (45) is fixed on the supporting plate (41), and a rotating shaft of the third motor (45) is fixed with the supporting shaft (43) through a coupler.

8. The continuous high-temperature aerobic organic matter fermentation, drying and recycling system as claimed in claim 1, wherein: the tank is characterized in that branch pipes (5) corresponding to each layer are fixed on the tank body (1), electromagnetic valves (53) are fixedly embedded into the branch pipes (5), exhaust pipes (51) are fixedly communicated with the other ends of the branch pipes (5), and electric heating pipes (52) are wound on the exhaust pipes (51).

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