CN113481084A - Organic matter fermentation tank based on aerobic fermentation technology - Google Patents

Abstract

The invention discloses an organic matter fermentation tank based on aerobic fermentation technology, which comprises: the tank body is arranged vertically, and an oxygen content detector is arranged on the surface of the tank body; the feed inlet is arranged at the top end of the tank body, and the discharge outlet is arranged at the position, close to the bottom end, of the side end of the tank body; the stirring unit is arranged in the tank body and is used for stirring organic matters in the tank body; the high-temperature air inlet unit is arranged at the bottom end of the tank body. The invention discloses an organic matter fermentation tank based on aerobic fermentation technology, wherein organic fermentation products are fed into a tank body from a feeding hole for fermentation, a stirring unit stirs the organic fermentation products in the tank body, an oxygen content detector is used for monitoring the oxygen content in a pipe body, when the oxygen content is insufficient, a high-temperature air inlet unit sends oxygen-enriched high-temperature air into the tank body, and the organic fermentation products are fully contacted with the oxygen-enriched high-temperature air under the stirring of the stirring unit by utilizing the aerobic fermentation technology, so that the fermentation efficiency is improved.

Description

Organic matter fermentation tank based on aerobic fermentation technology

Technical Field

The invention relates to the technical field of fermentation tanks, in particular to an organic matter fermentation tank based on an aerobic fermentation technology.

Background

Need carry out aerobic fermentation to organic fermentation thing in the course of working of organic matter, make things convenient for the better fermentation of organic matter ability, satisfy the demand of using, but current fermentation cylinder sealed setting, oxygen content and temperature regulation nature are poor in the fermentation cylinder, the unable abundant demand that satisfies organic fermentation thing aerobic fermentation.

Disclosure of Invention

In order to achieve the above object, the present invention discloses an organic matter fermentation tank based on aerobic fermentation technology, comprising:

the tank body is arranged vertically, and an oxygen content detector is arranged on the surface of the tank body;

the feed inlet is arranged at the top end of the tank body, and the discharge outlet is arranged at the position, close to the bottom end, of the side end of the tank body;

the stirring unit is arranged in the tank body and is used for stirring organic matters in the tank body;

the high-temperature air inlet unit is arranged at the bottom end of the tank body.

Preferably, the outer surface of the tank body is wrapped with a heat insulation layer.

Preferably, a shielding shed is installed at the top end of the tank body.

Preferably, the method further comprises the following steps:

the ladder of ascending a height, the ladder of ascending a height is installed in jar body side.

Preferably, the stirring unit includes:

the sleeve extends into the tank body from the top end of the tank body;

the central shaft penetrates through the sleeve, the top end of the central shaft extends out of the top end of the sleeve, the bottom end of the central shaft extends out of the bottom end of the pipe body, and the bottom end of the central shaft extends into the high-temperature air inlet unit;

a plurality of stirring rods circumferentially mounted on the central shaft;

and the two stirring rod units are symmetrically arranged on the sleeve by taking the central shaft as a center.

Preferably, the agitating bar unit includes:

the upper mounting ring seat is sleeved on the sleeve;

the lower mounting ring seat is mounted on the sleeve through a fixed bearing and is positioned below the upper mounting ring seat;

the stirring rods are circumferentially hinged on the upper mounting ring seat by taking the central shaft as a center;

the connecting rods are arranged in equal number with the stirring rods, one end of each connecting rod is hinged with the lower mounting ring seat, and the other end of each connecting rod is hinged with the inner end of each stirring rod;

the two first connecting arms are symmetrically hinged on the sleeve by taking a central shaft as a center, and the first connecting arms are positioned between the upper mounting ring seat and the lower mounting ring seat;

and the first steel ball is fixedly connected to the first connecting arm far away from the end of the sleeve.

Preferably, the high temperature air inlet unit includes:

the air inlet box is connected to the bottom end of the tank body, and the bottom end of the central shaft extends into the air inlet box;

the limiting box is arranged in the air inlet box and close to the top, and the bottom end of the central shaft penetrates through the limiting box;

the supporting plate is arranged in the tank body, the supporting plate is sleeved on the central shaft, and the supporting plate is positioned below the stirring rod;

the lifting plate is positioned in the air inlet box, the lifting plate is sleeved on the central shaft, and the lifting plate is positioned below the limiting box;

the two vertical rods are symmetrically connected between the supporting plate and the lifting plate by taking the central shaft as a center, and the vertical rods penetrate through the limiting box;

the two limiting blocks are symmetrically connected in the limiting box by taking the central shaft as a center;

the limiting claws are connected to the inner end of the limiting block, and the two limiting claws are spliced into a circle and hooped with the central shaft;

the air inlet pipe is connected to the outer end of the limiting block, and the end, far away from the limiting block, of the air inlet pipe extends out of the limiting box;

the air inlet holes are uniformly formed in the air inlet pipe;

the reset spring is positioned in the limit box, the reset spring is sleeved on the air inlet pipe, one end of the reset spring is connected with the inner wall of the limit box, and the other end of the reset spring is connected with the limit block;

the chute is arranged on the limiting block, and the lower end of the chute is far away from the limiting claw;

the sliding block is connected in the chute in a sliding manner and is arranged on the vertical rod;

the air inlet channels are axially distributed by taking the central shaft as a center and communicated between the limiting box and the tank body;

the high-temperature air pipe is communicated with the air inlet box;

the two second connecting arms are symmetrically hinged to the bottom end of the central shaft by taking the central shaft as a center, and the second connecting arms are positioned below the lifting plate;

the second steel ball is fixedly connected to the second connecting arm and far away from the central shaft end;

the reset torsion spring is sleeved at the hinged end, close to the central shaft, of the second connecting arm, one torsion arm end of the reset torsion spring is fixedly connected with the second connecting arm, and the other torsion arm end of the reset torsion spring is fixedly connected with the side end of the central shaft.

Preferably, the method further comprises the following steps:

the first channel is arranged at the central end of the central shaft and extends out of the bottom end of the central shaft;

the second channel is arranged in the stirring rod and communicated with the first channel;

and the air outlet holes are respectively formed in the central shaft and the stirring rod and communicated with the first channel and the second channel.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of a stirring unit according to the present invention;

FIG. 3 is an enlarged view of reference character A in FIG. 2;

fig. 4 is an enlarged view of reference symbol B in fig. 2.

In the figure: 1. a tank body; 2. a stirring unit; 3. a high-temperature air inlet unit; 11. a feed inlet; 12. a discharge port; 21. a sleeve; 22. a central shaft; 23. a stirring rod; 24. a stirring rod unit; 25. an upper mounting ring seat; 26. a lower mounting ring seat; 27. a stirring rod; 28. a connecting rod; 29. a first connecting arm; 20. a first steel ball; 31. an air inlet box; 32. a limiting box; 33. a support plate; 34. a lifting plate; 35. a vertical rod; 36. a limiting block; 37. a limiting claw; 38. an air inlet pipe; 39. a return spring; 30. a chute; 41. a slider; 42. an air intake passage; 43. a high temperature air duct; 44. a first channel; 45. a second channel; 46. a second connecting arm; 47. and a second steel ball.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Examples

The invention will be further described with reference to the accompanying drawings.

As shown in fig. 1, the present embodiment provides an organic fermentation tank based on aerobic fermentation technology, comprising:

the tank body 1 is vertically arranged, and an oxygen content detector is arranged on the surface of the tank body 1;

the feeding port 11 is arranged at the top end of the tank body 1, and the discharging port 12 is arranged at the position, close to the bottom end, of the side end of the tank body 1;

the stirring unit 2 is arranged in the tank body 1, and is used for stirring the organic matters in the tank body 1;

high temperature air inlet unit 3, high temperature air inlet unit 3 install in 1 bottom of the jar body.

The working principle and the beneficial effects of the technical scheme are as follows:

the invention discloses an organic matter fermentation tank based on aerobic fermentation technology, organic fermentation products are fed into a tank body 1 from a feeding hole 11 for fermentation, a stirring unit 2 stirs the organic fermentation products in the tank body 1, an oxygen content detector is used for monitoring the oxygen content in a pipe body 1, when the oxygen content is insufficient, a high-temperature air inlet unit 4 sends oxygen-enriched high-temperature air into the tank body 1, and the organic fermentation products are fully contacted with the oxygen-enriched high-temperature air by using the aerobic fermentation technology under the stirring of the stirring unit 2, so that the fermentation efficiency of the organic fermentation products is improved.

In one embodiment, the outer surface of the tank body 1 is wrapped with a thermal insulation layer.

The beneficial effects of the above technical scheme are:

plays a role in preserving heat of the organic fermentation product in the tank body 1.

In one embodiment, a shielding shed is arranged at the top end of the tank body 1.

In one embodiment, further comprising:

the ladder of ascending a height, the ladder of ascending a height is installed in 1 side of jar body.

As shown in fig. 2, in one embodiment, the stirring unit 2 includes:

the sleeve 21 extends into the tank body 1 from the top end of the tank body 1;

the central shaft 22 penetrates through the sleeve 21, the top end of the central shaft 22 extends out of the top end of the sleeve 21, the bottom end of the central shaft 22 extends out of the bottom end of the pipe body 1, and the bottom end of the central shaft 22 extends into the high-temperature air inlet unit 3;

a plurality of stirring rods 23 circumferentially attached to the center shaft 22;

and two stirring rod units 24, wherein the two stirring rod units 24 are symmetrically arranged on the sleeve 21 by taking the central shaft 22 as a center.

The working principle and the beneficial effects of the technical scheme are as follows:

a stirring motor drives the sleeve 21 to rotate positively, a stirring motor drives the central shaft 22 to turn over, the sleeve 21 rotating positively drives the stirring rod unit 24 to rotate positively in the tank body 1, and the central shaft 22 turning over drives the stirring rod 23 to rotate reversely in the tank body 1, so that the stirring efficiency of the organic fermentation product in the tank body 1 is improved.

As shown in fig. 3, in one embodiment, the stirring rod unit 24 includes:

the upper mounting ring seat 25 is sleeved on the sleeve 21;

a lower mounting ring seat 26, wherein the lower mounting ring seat 26 is mounted on the sleeve 21 through a fixed bearing, and the lower mounting ring seat 26 is located below the upper mounting ring seat 25;

a plurality of stirring rods 27, wherein the stirring rods 27 are circumferentially hinged on the upper mounting ring seat 25 by taking the central shaft 22 as a center;

the connecting rods 28 are arranged in equal number with the stirring rods 27, one end of each connecting rod 28 is hinged with the lower mounting ring seat 26, and the other end of each connecting rod 28 is hinged with the inner end of each stirring rod 27;

two first connecting arms 29, wherein the two first connecting arms 29 are symmetrically hinged on the sleeve 21 by taking the central shaft 22 as a center, and the first connecting arms 29 are positioned between the upper mounting ring seat 25 and the lower mounting ring seat 26;

and the first steel ball 20 is fixedly connected to the end, far away from the sleeve 21, of the first connecting arm 29.

The working principle and the beneficial effects of the technical scheme are as follows:

when sleeve pipe 21 forward rotation, the drive is located the lower collar extension 26 rotation on the sleeve pipe 21 through the fixing bearing cover, and then drive puddler 27 forward rotation, at this moment, first steel ball 20 is under the centrifugal force effect, it opens to drive first connecting arm 29, first steel ball 20 supports connecting rod 28, thereby make the contained angle between connecting rod 28 and the puddler 27 diminish, and then make and go up collar extension 25 along sleeve pipe 21 to being close to down collar extension 26 direction motion, puddler 27 opens, thereby accomplish the internal forward stirring of organic fermented product of jar.

As shown in fig. 4, in one embodiment, the high temperature air intake unit 3 includes:

the air inlet box 31 is connected to the bottom end of the tank body 1, and the bottom end of the central shaft 22 extends into the air inlet box 31;

the limiting box 32 is arranged in the air inlet box 31 and close to the top, and the bottom end of the central shaft 22 penetrates through the limiting box 32;

the supporting plate 33 is arranged in the tank body 1, the supporting plate 33 is sleeved on the central shaft 22, and the supporting plate 33 is positioned below the stirring rod 23;

the lifting plate 34 is positioned in the air inlet box 31, the lifting plate 34 is sleeved on the central shaft 22, and the lifting plate 34 is positioned below the limit box 32;

the two vertical rods 35 are symmetrically connected between the supporting plate 33 and the lifting plate 34 by taking the central shaft 22 as a center, and the vertical rods 35 penetrate through the limiting box 32;

the two limiting blocks 36 are symmetrically connected in the limiting box 32 by taking the central shaft 22 as a center;

the limiting claws 37 are connected to the inner end of the limiting block 36, and the two limiting claws 37 are spliced into a circle and hooped on the central shaft 22;

the air inlet pipe 38 is connected to the outer end of the limiting block 36, and the air inlet pipe 38 is arranged far away from the end of the limiting block 36 and extends out of the limiting box 32;

the air inlet holes are uniformly formed in the air inlet pipe 38;

the return spring 39 is positioned in the limit box 32, the return spring 39 is sleeved on the air inlet pipe 38, one end of the return spring 39 is connected with the inner wall of the limit box 32, and the other end of the return spring 39 is connected with the limit block 36;

the chute 30 is arranged on the limiting block 36, and the low-position end of the chute 30 is far away from the limiting claw 37;

the sliding block 41 is connected in the inclined groove 30 in a sliding mode, and the sliding block 41 is installed on the vertical rod 35;

a plurality of air inlet channels 42, wherein the air inlet channels 42 are axially distributed by taking the central shaft 22 as a center and are communicated between the limiting box 32 and the tank body 1;

the high-temperature air pipe 43 is communicated with the air inlet box 31;

two second connecting arms 46, wherein the two second connecting arms 29 are symmetrically hinged to the bottom end of the central shaft 22 by taking the central shaft 22 as a center, and the second connecting arms 29 are positioned below the lifting plate 34;

the second steel ball 47 is fixedly connected to the end, far away from the central shaft 22, of the second connecting arm 46;

the second connecting arm 46 is sleeved with the reset torsion spring, the hinged end of the second connecting arm 46 is close to the central shaft 22, one torsion arm end of the reset torsion spring is fixedly connected with the second connecting arm 46, and the other torsion arm end of the reset torsion spring is fixedly connected with the side end of the central shaft 22.

The working principle and the beneficial effects of the technical scheme are as follows:

organic fermentation products are fed into the tank body 1 from the feed inlet 11, the support plate 33 is pressed by the self weight of the organic fermentation products, so that the support plate 33 moves downwards, the vertical rod 35 connected with the support plate 33 is further driven, the lifting plate 34 connected with the end, far away from the support plate 33, of the vertical rod 35 moves downwards, when the vertical rod 35 moves vertically downwards, the sliding block 41 is driven to move downwards, the limiting block 36 connected with the sliding block 41 through the chute 30 is driven to move towards the direction close to the central shaft 22, the reset spring 39 is stretched, the air inlet pipe 38 extends into the limiting box 32, the amount of high-temperature hot air fed into the limiting box 32 by the air inlet pipe 38 is increased along with the increase of the air inlet holes entering the limiting box 32, so that the amount of high-temperature hot air fed into the tank body 1 through the air inlet channel 42 is increased, the organic fermentation products which are adapted to be increased are fed, and the central shaft 22 drives the second steel ball 47 to rotate around the central shaft 22 through the second connecting arm 46, along with the rotational speed of center pin 22 accelerates, the centrifugal force of second steel ball 47 increases, the torsional spring atress distortion that resets, the contained angle grow of second linking arm 46 and center pin 22 that is connected with second steel ball 47, lifter plate 34 downstream, and then drive backup pad 33 through montant 35 along center pin 22 downstream, 41 progressively to being close to 30 low-order end motion in 30, and then drive 36, the 37 of being connected with 36 the inner is to being close to 22 direction motion, two 37 concatenations form cyclic annularly, thereby it is spacing 22 the bottom prevents rocking of 22 bottoms, improves the life of fermentation cylinder.

In one embodiment, further comprising:

a first channel 44, wherein the first channel 44 is opened at the central end of the central shaft 22, and the first channel 44 is extended from the bottom end of the central shaft 22;

the second channel 45 is arranged in the stirring rod 23, and the second channel 45 is communicated with the first channel 44;

and the air outlet holes are respectively formed in the central shaft 22 and the stirring rod 23 and are communicated with the first channel 44 and the second channel 45.

The beneficial effects of the above technical scheme are:

high-temperature hot air is fed into the second channel 45 from the first channel 44 and is fed into the tank body 1 through the air outlet hole, so that the high-temperature hot air is uniformly fed into the organic fermentation product, the contact area of the organic fermentation product and the high-temperature hot air is increased, and the fermentation efficiency is improved.

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications therefrom are within the scope of the invention.

Claims (8)

1. An organic matter fermentation tank based on aerobic fermentation technology is characterized by comprising:

the tank body (1) is arranged vertically, and an oxygen content detector is arranged on the surface of the tank body (1);

the feed inlet (11) is installed at the top end of the tank body (1), and the discharge outlet (12) is installed at the position, close to the bottom end, of the side end of the tank body (1);

the stirring unit (2) is arranged in the tank body (1) and is used for stirring the organic matters in the tank body (1);

the high-temperature air inlet unit (3), the high-temperature air inlet unit (3) install in jar body (1) bottom.

2. An organic matter fermentation tank based on aerobic fermentation technology according to claim 1, characterized in that the outer surface of the tank body (1) is wrapped with a thermal insulation layer.

3. A stacked organic aerobic fermentation tank according to the claim 1, wherein the top of the tank body (1) is provided with a shelter.

4. An overlapped organic aerobic fermentation tank according to claim 1, which is characterized by further comprising:

the ladder of ascending a height, the ladder of ascending a height is installed in jar body (1) side.

5. An organic matter fermenter based on aerobic fermentation technology according to claim 1, wherein the stirring unit (2) comprises:

the sleeve (21) extends into the tank body (1) from the top end of the tank body (1);

the central shaft (22), the central shaft (22) is arranged in the sleeve (21) in a penetrating manner, the top end of the central shaft (22) extends out of the top end of the sleeve (21), the bottom end of the central shaft (22) extends out of the bottom end of the pipe body (1), and the bottom end of the central shaft (22) extends into the high-temperature air inlet unit (3);

a plurality of stirring rods (23), wherein the plurality of stirring rods (23) are circumferentially arranged on the central shaft (22);

and the two stirring rod units (24) are symmetrically arranged on the sleeve (21) by taking the central shaft (22) as the center.

6. An organic matter fermenter based on aerobic fermentation technology according to claim 5, wherein the stirring rod unit (24) comprises:

the upper mounting ring seat (25) is sleeved on the sleeve (21);

the lower mounting ring seat (26) is mounted on the sleeve (21) through a fixed bearing, and the lower mounting ring seat (26) is positioned below the upper mounting ring seat (25);

the stirring rods (27) are circumferentially hinged on the upper mounting ring seat (25) by taking a central shaft (22) as a center;

the connecting rods (28) are arranged in equal number with the stirring rods (27), one end of each connecting rod (28) is hinged with the lower mounting ring seat (26), and the other end of each connecting rod (28) is hinged with the inner end of each stirring rod (27);

the two first connecting arms (29) are symmetrically hinged on the sleeve (21) by taking a central shaft (22) as a center, and the first connecting arms (29) are positioned between the upper mounting ring seat (25) and the lower mounting ring seat (26);

the first steel ball (20), the first steel ball (20) is fixedly connected to the end of the first connecting arm (29) far away from the sleeve (21).

7. An organic matter fermenter based on aerobic fermentation technology according to claim 5, wherein the high temperature air intake unit (3) comprises:

the air inlet box (31), the air inlet box (31) is connected to the bottom end of the tank body (1), and the bottom end of the central shaft (22) extends into the air inlet box (31);

the limiting box (32) is mounted in the air inlet box (31) and close to the top, and the bottom end of the central shaft (22) penetrates through the limiting box (32);

the supporting plate (33), the supporting plate (33) is arranged in the tank body (1), the supporting plate (33) is sleeved on the central shaft (22), and the supporting plate (33) is positioned below the stirring rod (23);

the lifting plate (34) is positioned in the air inlet box (31), the lifting plate (34) is sleeved on the central shaft (22), and the lifting plate (34) is positioned below the limiting box (32);

the two vertical rods (35) are symmetrically connected between the supporting plate (33) and the lifting plate (34) by taking the central shaft (22) as a center, and the vertical rods (35) penetrate through the limiting box (32);

the two limiting blocks (36) are symmetrically connected in the limiting box (32) by taking the central shaft (22) as the center;

the limiting claws (37), the limiting claws (37) are connected to the inner end of the limiting block (36), the two limiting claws (37) are spliced into a circle and hoop the central shaft (22);

the air inlet pipe (38), the air inlet pipe (38) is connected to the outer end of the limiting block (36), and the end, far away from the limiting block (36), of the air inlet pipe (38) extends out of the limiting box (32);

the air inlet holes are uniformly formed in the air inlet pipe (38);

the return spring (39) is positioned in the limiting box (32), the return spring (39) is sleeved on the air inlet pipe (38), one end of the return spring (39) is connected with the inner wall of the limiting box (32), and the other end of the return spring (39) is connected with the limiting block (36);

the chute (30) is arranged on the limiting block (36), and the low end of the chute (30) is far away from the limiting claw (37);

the sliding block (41), the sliding block (41) is connected in the chute (30) in a sliding mode, and the sliding block (41) is installed on the vertical rod (35);

the air inlet channels (42) are axially distributed by taking the central shaft (22) as a center and are communicated between the limiting box (32) and the tank body (1);

the high-temperature air pipe (43), the said high-temperature air pipe (43) communicates in the air inlet box (31);

the two second connecting arms (46) are symmetrically hinged to the bottom end of the central shaft (22) by taking the central shaft (22) as a center, and the second connecting arms (29) are positioned below the lifting plate (34);

the second steel ball (47), the second steel ball (47) is fixedly connected to the end, far away from the central shaft (22), of the second connecting arm (46);

the reset torsion spring is sleeved at the hinged end, close to the central shaft (22), of the second connecting arm (46), one torsion arm end of the reset torsion spring is fixedly connected with the second connecting arm (46), and the other torsion arm end of the reset torsion spring is fixedly connected with the side end of the central shaft (22).

8. The organic matter fermentation tank based on aerobic fermentation technology as claimed in claim 7, further comprising:

the first channel (44) is arranged at the central end of the central shaft (22), and the first channel (44) extends from the bottom end of the central shaft (22);

the second channel (45) is arranged in the stirring rod (23), and the second channel (45) is communicated with the first channel (44);

and the air outlet holes are respectively formed in the central shaft (22) and the stirring rod (23) and are communicated with the first channel (44) and the second channel (45).

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