CN114149898B - Compound engineering bacteria fermentation enzyme preparation extraction system - Google Patents

Abstract

The invention discloses a composite engineering bacteria fermentation enzyme preparation extraction system, which comprises a machine shell, wherein a placing cavity is arranged in the machine shell, and a lifting device, a rotating device, a pushing device, a first scraping device, a second scraping device and a moving device are arranged in the placing cavity; the invention can complete the work of preparing enzyme and extracting enzyme by engineering bacteria, improves the enzyme preparation efficiency, simultaneously fully ferments the engineering bacteria by stirring the engineering bacteria by the stirring rod, avoids the problem that part of the engineering bacteria can not complete the fermentation due to the accumulation of the engineering bacteria on the filter plate, avoids the resource waste, improves the production efficiency of a factory, can automatically push the engineering bacteria residue after the fermentation is finished out of the filter plate by the push plate, avoids the need of stretching hands into the machine for cleaning, and finally can scrape off the enzyme powder attached to the filter plate by the scraper blade, and avoids the resource waste caused by the residual enzyme powder on the filter plate.

Description

Compound engineering bacteria fermentation enzyme preparation extraction system

Technical Field

The invention relates to the technical field of enzyme extraction, in particular to an extraction system for preparing enzyme by fermenting composite engineering bacteria.

Background

The biological enzyme is an organic matter with a catalytic action and generated by living cells, the manufacturing and application fields of the biological enzyme are gradually expanded, but the preparation equipment of the biological enzyme has more defects:

firstly, in the current biological enzyme preparation equipment, enzyme preparation organisms cannot be stirred, so that when the organisms prepare enzymes, the sufficient fermentation cannot be carried out, and the resource waste is caused;

secondly, in the process of biologically preparing the enzyme, part of the enzyme remains in the equipment, and the enzyme can not be taken out from the equipment, thereby causing resource waste and increasing the production cost of a factory;

thirdly, in the enzyme preparation process, when the temperature inside the device is too high, the activity of the enzyme is permanently lost, thus greatly reducing the enzyme preparation effect.

Disclosure of Invention

The invention aims to provide an extraction system for preparing enzyme by fermenting composite engineering bacteria, which is used for overcoming the defects in the prior art.

The composite engineering bacteria fermentation enzyme preparation extraction system comprises a machine shell, wherein a placing cavity is arranged in the machine shell, first pipelines extending out of the machine shell are fixedly arranged on the left side wall and the right side wall of the left side and the right side of the placing cavity, a first electric control ball valve is arranged in each first pipeline, a first filter plate is fixedly arranged on the side wall of the placing cavity, and a lifting device is arranged in the rear side wall of the placing cavity;

a first heating pipe is fixedly arranged in the side walls of the left side and the right side of the placing cavity, and a pushing device for pushing engineering bacteria residues is arranged in the rear side wall of the placing cavity below the lifting device;

a first rotating door is rotatably connected to the front side wall of the placing cavity, a funnel is fixedly arranged at the lower end of the first filter plate, a second electric control ball valve is installed in the funnel, an enzyme outlet pipe is communicated with the bottom wall of the funnel below the second electric control ball valve, an enzyme preparation shell is fixedly arranged on the side wall of the placing cavity below the enzyme outlet pipe, an enzyme preparation cavity is arranged in the enzyme preparation shell and is communicated with the enzyme outlet pipe, a fan is installed in the left side wall of the enzyme preparation cavity, three enzyme powder rods are fixedly arranged on the rear side wall of the enzyme preparation cavity at equal intervals, and a first scraping device for scraping enzyme powder is arranged on each enzyme powder rod;

a second pipeline extending out of the shell is communicated with the right side wall of the enzyme preparation cavity, a filter cavity is arranged in the second pipeline, two second filter plates are installed in the filter cavity, a second heating pipe is fixedly arranged in the bottom wall of the enzyme preparation cavity, and a second scraping device for scraping enzyme powder on the second filter plates is arranged on the top wall of the enzyme preparation cavity;

the enzyme preparation chamber is characterized in that an enzyme outlet groove is fixedly formed in the bottom wall of the front side of the enzyme preparation chamber, a third electric control ball valve is installed in the enzyme outlet groove, a collection shell is connected to the bottom wall of the placing chamber below the third electric control ball valve in a sliding mode, a collection chamber with an upward opening is arranged in the collection shell, the front side of the collection shell is rotatably connected to the side wall of the placing chamber in the front mode and is provided with a second rotating door, and four movable devices are arranged on the bottom wall of the machine shell.

Optionally, elevating gear including set firmly in placing the chamber back lateral wall in with place the lift groove of chamber intercommunication, first motor has set firmly on the lift groove roof, first motor is installed and is extended to the screw spindle in the lift groove, threaded connection has the elevator on the screw spindle, articulated on the lateral wall before the elevator have the extending of bilateral symmetry to place two first axes of rotation of intracavity, place the intracavity first sleeve has set firmly in the first axis of rotation, equidistant six puddlers that have set firmly in the first sleeve, the puddler front side place and be equipped with the drive before the chamber on the lateral wall first axis of rotation pivoted rotating device.

Therefore, the upper position and the lower position of the stirring rod can be controlled according to the quantity of engineering bacteria, and the situation that the stirring rod cannot rotate due to the fact that the engineering bacteria are too much is avoided.

Optionally, the rotating device including set firmly in place before the chamber on the lateral wall and with place the rotation groove of chamber intercommunication, first axis of rotation extends to rotate before the groove lateral wall and with place before the chamber lateral wall and rotate and be connected, rotate the inslot first gear has set firmly in the first axis of rotation, first gear below rotate before the groove on the lateral wall and rotate and be connected with two second axis of rotation, two the second axis of rotation is located two respectively under the first axis of rotation, install the drive left side in the rotation groove before the lateral wall the second motor of second axis of rotation, second axis of rotation rear end is equipped with the second gear admittedly, the second gear with first gear engagement, set firmly the third gear in the second axis of rotation, two it is connected with the chain to rotate on the third gear.

Therefore, the engineering bacteria can be stirred, so that the engineering bacteria are fully fermented, and the condition of resource waste is avoided.

Optionally, the pushing device comprises a pushing groove fixedly arranged in the rear side wall of the placing cavity and communicated with the placing cavity, a first hydraulic cylinder is fixedly arranged on the rear side wall of the pushing groove, a first telescopic rod is arranged towards the placing cavity and provided with a pushing plate, and the bottom wall of the pushing plate is connected with the top wall of the first filter plate in a sliding mode.

Therefore, the engineering bacteria residues after fermentation can be automatically pushed out, and the need of manual taking out is avoided.

Optionally, the first scraping device comprises a rack fixedly arranged on the enzyme powder rod, the enzyme powder rod is connected with a second sleeve in a sliding manner, a third motor is fixedly arranged in the second sleeve wall above the rack, a third rotating shaft is installed on the third motor, a fourth gear is fixedly arranged on the third rotating shaft and meshed with the rack, a push block is fixedly arranged on the front side wall of the second sleeve, and the bottom wall of the push block is connected with the bottom wall of the enzyme preparation cavity in a sliding manner.

In this way, the enzyme powder attached to the enzyme powder rod can be pushed into the collection chamber.

Optionally, the second scraping device comprises a second hydraulic cylinder fixedly arranged on the top wall of the right side of the enzyme preparation cavity, the second hydraulic cylinder is provided with a second telescopic rod extending into the enzyme preparation cavity, the lower end of the second telescopic rod is fixedly provided with a scraper, and the right end of the scraper is connected with the second filter plate in a sliding manner.

Thus, the enzyme powder attached to the filter plate can be scraped, and the waste of resources is avoided.

Optionally, the moving device includes a bottom plate fixedly arranged on the bottom wall of the casing, shock-absorbing rods with symmetrical front and back positions are fixedly arranged on the bottom plate, and wheels with brake pads are mounted at the lower ends of the two shock-absorbing rods.

Therefore, the equipment can be conveniently moved, and the requirement of a large amount of labor for moving the equipment is avoided.

The beneficial effects of the invention are:

according to the invention, the lifting device, the rotating device, the pushing device, the first scraping device, the second scraping device and the moving device are arranged, so that the work of producing enzyme and extracting enzyme by engineering bacteria can be completed, the automation degree of enzyme production equipment is improved, and the enzyme production efficiency is improved;

meanwhile, the stirring rod is used for stirring the engineering bacteria, so that the engineering bacteria are fully fermented, the problem that part of the engineering bacteria cannot be fermented due to the fact that the engineering bacteria are accumulated on the filter plate is avoided, resource waste is avoided, and the production efficiency of a factory is improved;

the push plate can automatically push the engineering bacteria residues after fermentation out of the filter plate, so that the situation that hands are scratched by a stirring rod in the placing cavity due to the fact that the hands need to be inserted into the machine for cleaning is avoided;

finally, the scraper blade provided by the invention can scrape off the enzyme powder attached to the filter plate, so that the problem of resource waste caused by the fact that part of the enzyme powder remains on the filter plate is avoided, the production efficiency of a factory is improved, and the production cost of the factory is reduced.

Drawings

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

FIG. 2 is a schematic diagram of the overall structure of a composite engineering bacteria fermentation enzyme preparation extraction system of the present invention;

FIG. 3 is a schematic view of A-A of FIG. 2 in accordance with the present invention;

FIG. 4 is a schematic view of the first scraping apparatus of FIG. 3 in accordance with the present invention;

FIG. 5 is a schematic view of the turning gear of FIG. 3 according to the present invention;

FIG. 6 is a schematic view of the second scraping apparatus of FIG. 2 according to the invention;

FIG. 7 is a schematic view of the mobile device of FIG. 3 according to the present invention;

as shown in the figure:

10. a housing; 11. a placement chamber; 12. a first filter plate; 13. a first conduit; 14. a first electrically controlled ball valve; 15. a lifting groove; 16. a first motor; 17. a threaded shaft; 18. a lifting block; 19. a first rotating shaft; 20. a rotating groove; 21. a first gear; 22. a second motor; 23. a second rotating shaft; 24. a third gear; 25. a chain; 26. a second gear; 27. a first sleeve; 28. a stirring rod; 29. a first heating pipe; 30. a first hydraulic cylinder; 31. a first telescopic rod; 32. pushing the plate; 33. a first swing door; 34. a funnel; 35. a second electrically controlled ball valve; 36. discharging an enzyme tube; 37. preparing an enzyme shell; 38. an enzyme preparation cavity; 39. a fan; 40. an enzyme powder rod; 41. a second sleeve; 42. a third motor; 43. a third rotating shaft; 44. a fourth gear; 45. a second hydraulic cylinder; 46. a second telescopic rod; 47. a squeegee; 48. a second pipe; 49. a filter chamber; 50. a second filter plate; 51. discharging the enzyme from the enzyme tank; 52. a third electrically controlled ball valve; 53. collecting the shells; 54. a collection chamber; 55. a second swing door; 56. a rack; 57. a base plate; 58. a shock-absorbing rod; 59. a wheel; 60. a second heating pipe; 61. a push groove; 62. a push block; 63. a lifting device; 64. a rotating device; 65. a pushing device; 66. a first scraping device; 67. a second scraping device; 68. and (4) moving the device.

Detailed Description

The invention is further illustrated by the following examples:

referring to fig. 1-7, the composite engineering bacteria fermentation enzyme preparation extraction system includes a housing 10, a placing cavity 11 is provided in the housing 10, a first pipeline 13 extending to the outside of the housing 10 is fixedly provided on the left and right side walls of the left and right sides of the placing cavity 11, a first electric control ball valve 14 is provided in the first pipeline 13, a first filter plate 12 is fixedly provided on the side wall of the placing cavity 11, and a lifting device 63 is provided in the rear side wall of the placing cavity 11;

first heating pipes 29 are fixedly arranged in the side walls of the left side and the right side of the placing cavity 11, and a pushing device 65 for pushing engineering bacteria residues is arranged in the rear side wall of the placing cavity 11 below the lifting device 63;

a first rotating door 33 is connected to the front side wall of the placing cavity 11 in a rotating manner, a funnel 34 is fixedly arranged at the lower end of the first filter plate 12, a second electric control ball valve 35 is installed in the funnel 34, an enzyme outlet pipe 36 is communicated with the bottom wall of the funnel 34 below the second electric control ball valve 35, an enzyme preparation shell 37 is fixedly arranged on the side wall of the placing cavity 11 below the enzyme outlet pipe 36, an enzyme preparation cavity 38 is formed in the enzyme preparation shell 37, the enzyme preparation cavity 38 is communicated with the enzyme outlet pipe 36, a fan 39 is installed in the left side wall of the enzyme preparation cavity 38, three enzyme powder rods 40 are fixedly arranged on the rear side wall of the enzyme preparation cavity 38 at equal intervals, and a first scraping device 66 for scraping enzyme powder is arranged on the enzyme powder rods 40;

a second pipeline 48 extending out of the casing 10 is communicated with the right side wall of the enzyme preparation chamber 38, a filter chamber 49 is arranged in the second pipeline 48, two second filter plates 50 are installed in the filter chamber 49, a second heating pipe 60 is fixedly arranged in the bottom wall of the enzyme preparation chamber 38, and a second scraping device 67 for scraping enzyme powder on the second filter plates 50 is arranged on the top wall of the enzyme preparation chamber 38;

enzyme preparation chamber 38 front side diapire has set firmly out enzyme groove 51, go out and install third automatically controlled ball valve 52 in the enzyme groove 51, third automatically controlled ball valve 52 below place sliding connection on the 11 diapalls of chamber and collect shell 53, be equipped with opening collection chamber 54 up in the collection shell 53, collect the shell 53 front side place rotate on the 11 preceding lateral walls in chamber and be connected with the second and rotate door 55, be equipped with four removals on the casing 10 diapalls the mobile device 68 of casing 10.

Beneficially, the lifting device 63 includes a lifting groove 15 fixedly disposed in a rear side wall of the placing cavity 11 and communicated with the placing cavity 11, a first motor 16 is fixedly disposed on a top wall of the lifting groove 15, the first motor 16 is provided with a threaded shaft 17 extending into the lifting groove 15, a lifting block 18 is screwed on the threaded shaft 17, two first rotating shafts 19 symmetrically extending into the placing cavity 11 are hinged on a front side wall of the lifting block 18, a first sleeve 27 is fixedly disposed on the first rotating shaft 19 in the placing cavity 11, six stirring rods 28 are fixedly disposed on the first sleeve 27 at equal intervals, a rotating device 64 for driving the first rotating shaft 19 to rotate is disposed on the front side wall of the placing cavity 11 on the front side of the stirring rods 28, and when the first motor 16 is started, the first motor 16 drives the lifting block 18 to move through the threaded shaft 17, the lifting block 18 drives the two first rotating shafts 19 to move.

Advantageously, the rotating device 64 includes a rotating groove 20 fixedly disposed on the front side wall of the placing cavity 11 and communicating with the placing cavity 11, the first rotating shaft 19 extends to the front side wall of the rotating groove 20 and is rotatably connected with the front side wall of the placing cavity 11, a first gear 21 is fixedly disposed on the first rotating shaft 19 in the rotating groove 20, two second rotating shafts 23 are rotatably connected to the front side wall of the rotating groove 20 below the first gear 21, the two second rotating shafts 23 are respectively located right below the two first rotating shafts 19, a second motor 22 for driving the left second rotating shaft 23 is mounted in the front side wall of the rotating groove 20, a second gear 26 is fixedly disposed at the rear end of the second rotating shaft 23, the second gear 26 is engaged with the first gear 21, a third gear 24 is fixedly disposed on the second rotating shaft 23, and a chain 25 is rotatably connected to the two third gears 24, when the second motor 22 is started, the second motor 22 drives the left third gear 24 to rotate through the left second rotating shaft 23, the left third gear 24 drives the right third gear 24 to rotate through the chain 25, the right third gear 24 drives the second gear 26 to rotate through the second rotating shaft 23, the second gear 26 drives the first rotating shaft 19 to rotate through meshing with the first gear 21, and the first rotating shaft 19 drives the stirring rod 28 to rotate through the first sleeve 27.

Advantageously, the pushing device 65 comprises a pushing groove 61 fixedly arranged in the rear side wall of the placing cavity 11 and communicated with the placing cavity 11, a first hydraulic cylinder 30 is fixedly arranged on the rear side wall of the pushing groove 61, the first hydraulic cylinder 30 is provided with a first telescopic rod 31 facing the placing cavity 11, a pushing plate 32 is fixedly arranged on the first telescopic rod 31, the bottom wall of the pushing plate 32 is slidably connected with the top wall of the first filter plate 12, and when the first hydraulic cylinder 30 is started, the first telescopic rod 31 is extended, and the pushing plate 32 is driven by the first telescopic rod 31 to move.

Advantageously, the first scraping device 66 includes a rack 56 fixed on the enzyme powder rod 40, the enzyme powder rod 40 is slidably connected to a second sleeve 41, a third motor 42 is fixed in a wall of the second sleeve 41 above the rack 56, the third motor 42 is provided with a third rotating shaft 43, a fourth gear 44 is fixed on the third rotating shaft 43, the fourth gear 44 is engaged with the rack 56, a push block 62 is fixed on a front side wall of the second sleeve 41, a bottom wall of the push block 62 is slidably connected to a bottom wall of the enzyme preparation chamber 38, when the third motor 42 is started, the third motor 42 drives the fourth gear 44 to rotate through the third rotating shaft 43, the fourth gear 44 drives the second sleeve 41 to move through engagement with the rack 56, and the second sleeve 41 drives the push block 62 to move.

Beneficially, the second scraping device 67 includes a second hydraulic cylinder 45 fixedly arranged on the top wall of the right side of the enzyme preparation chamber 38, the second hydraulic cylinder 45 is provided with a second telescopic rod 46 extending into the enzyme preparation chamber 38, a scraping plate 47 is fixedly arranged at the lower end of the second telescopic rod 46, the right end of the scraping plate 47 is slidably connected with the second filter plate 50, and when the second hydraulic cylinder 45 is started, the second telescopic rod 46 is extended, and the second telescopic rod 46 drives the scraping plate 47 to move.

Advantageously, the moving device 68 comprises a bottom plate 57 fixed to the bottom wall of the casing 10, shock absorbing rods 58 are fixed to the bottom plate 57, and shock absorbing rods 58 are symmetrically arranged in the front-rear direction, and wheels 59 with brake pads are mounted at the lower ends of the shock absorbing rods 58.

The invention relates to a composite engineering bacteria fermentation enzyme preparation extraction system, which comprises the following working procedures:

initial state: the first electrically-controlled ball valve 14, the second electrically-controlled ball valve 35 and the third electrically-controlled ball valve 52 are all in a closed state;

when enzyme preparation needs to be started, the first electric control ball valve 14 on the left side is opened, the first pipeline 13 on the left side is connected with engineering bacteria, the engineering bacteria fall onto the first filter plate 12, the first heating pipe 29 is heated, the first motor 16 is started, the first motor 16 drives the lifting block 18 to descend through the threaded shaft 17, the lifting block 18 drives the two first rotating shafts 19 to move downwards, the second motor 22 is started, the second motor 22 drives the third gear 24 on the left side to rotate through the second rotating shaft 23 on the left side, the third gear 24 on the left side drives the third gear 24 on the right side to rotate through the chain 25, the third gear 24 on the right side drives the second gear 26 to rotate through the second rotating shaft 23, and the second gear 26 drives the first rotating shaft 19 to rotate through meshing with the first gear 21, the first rotating shaft 19 drives the stirring rod 28 to rotate through the first sleeve 27, the stirring rod 28 stirs the engineering bacteria on the first filter plate 12, so that the engineering bacteria are fully fermented, after the engineering bacteria are fermented for a period of time, the first electric control ball valve 14 and the second electric control ball valve 35 on the right side are opened, the first pipeline 13 on the right side is accessed with part of clear water, and the clear water flows the mixed liquid with the enzyme into the enzyme preparation cavity 38 along the enzyme outlet pipe 36 through the first filter plate 12;

when the mixed liquid with enzyme flows into the enzyme making cavity 38, the fan 39 and the second heating pipe 60 are started, the second heating pipe 60 heats the enzyme making cavity 38, and controls the highest temperature in the enzyme making cavity 38 not to exceed sixty degrees centigrade, the fan 39 and the second heating pipe 60 evaporate water, enzyme powder separated from the water is attached to the enzyme powder rod 40, the third motor 42 is started, the third motor 42 drives the fourth gear 44 to rotate through the third rotating shaft 43, the fourth gear 44 drives the second sleeve 41 to move through being meshed with the rack 56, the second sleeve 41 scrapes the enzyme powder attached to the enzyme powder rod 40, the second hydraulic cylinder 45 is started, the second telescopic rod 46 extends, the second telescopic rod 46 drives the scraper 47 to scrape the second filter plate 50, scraping enzyme powder blocked on the second filter plate 50 onto the bottom wall of the enzyme preparation cavity 38, driving the push block 62 by the second sleeve 41 to push and collect the enzyme powder on the bottom wall of the enzyme preparation cavity 38 and push the enzyme powder into the enzyme outlet groove 51, enabling the enzyme powder to fall into the collection shell 53 through the enzyme outlet groove 51, opening the two second rotating doors 55 by an operator when the enzyme powder needs to be taken, pulling the collection shell 53 out of the placing cavity 11 by the operator, and extracting and collecting the enzyme powder in the collection shell 53 by the operator;

after the fermentation finishes, first pneumatic cylinder 30 starts, first telescopic link 31 extension, first telescopic link 31 drives push pedal 32 moves forward, push pedal 32 will engineering fungus residue after finishing fermenting on the first filter plate 12 is released, and the operator opens two first revolving door 33, the operator will be promoted extremely the residue of first filter plate 12 front side is collected and is handled.

The foregoing detailed description of the preferred embodiments of the invention has been presented. It will be appreciated by those skilled in the art that changes could be made to the embodiments described above without departing from the broad inventive concept thereof. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims (6)

1. The utility model provides a compound engineering bacteria fermentation system enzyme extraction system, includes casing (10), its characterized in that: a placing cavity (11) is arranged in the machine shell (10), a first pipeline (13) extending out of the machine shell (10) is fixedly arranged on the left side wall and the right side wall of the left side and the right side of the placing cavity (11), a first electric control ball valve (14) is arranged in the first pipeline (13), a first filter plate (12) is fixedly arranged on the side wall of the placing cavity (11), and a lifting device (63) is arranged in the rear side wall of the placing cavity (11);

a first heating pipe (29) is fixedly arranged in the side walls of the left side and the right side of the placing cavity (11), and a pushing device (65) for pushing engineering bacteria residues is arranged in the rear side wall of the placing cavity (11) below the lifting device (63);

the enzyme production device is characterized in that a first rotating door (33) is rotatably connected to the front side wall of the placing cavity (11), a funnel (34) is fixedly arranged at the lower end of the first filter plate (12), a second electric control ball valve (35) is installed in the funnel (34), an enzyme outlet pipe (36) is communicated with the bottom wall of the funnel (34) below the second electric control ball valve (35), an enzyme production shell (37) is fixedly arranged on the side wall of the placing cavity (11) below the enzyme outlet pipe (36), an enzyme production cavity (38) is formed in the enzyme production shell (37), the enzyme production cavity (38) is communicated with the enzyme outlet pipe (36), a fan (39) is installed in the left side wall of the enzyme production cavity (38), three enzyme powder rods (40) are fixedly arranged on the rear side wall of the enzyme production cavity (38) at equal intervals, and a first scraping device (66) for scraping enzyme powder is arranged on the enzyme powder rods (40);

a second pipeline (48) extending out of the machine shell (10) is communicated with the right side wall of the enzyme preparation cavity (38), a filter cavity (49) is arranged in the second pipeline (48), two second filter plates (50) are installed in the filter cavity (49), a second heating pipe (60) is fixedly arranged in the bottom wall of the enzyme preparation cavity (38), and a second scraping device (67) for scraping enzyme powder on the second filter plates (50) is arranged on the top wall of the enzyme preparation cavity (38);

the lifting device (63) comprises a lifting groove (15) fixedly arranged in the rear side wall of the placing cavity (11) and communicated with the placing cavity (11), a first motor (16) is fixedly arranged on the top wall of the lifting groove (15), a threaded shaft (17) extending into the lifting groove (15) is arranged on the first motor (16), the threaded shaft (17) is in threaded connection with a lifting block (18), the front side wall of the lifting block (18) is hinged with two first rotating shafts (19) which are symmetrically arranged at left and right and extend into the placing cavity (11), a first sleeve (27) is fixedly arranged on the first rotating shaft (19) in the placing cavity (11), six stirring rods (28) are fixedly arranged on the first sleeve (27) at equal intervals, a rotating device (64) for driving the first rotating shaft (19) to rotate is arranged on the front side wall of the placing cavity (11) on the front side of the stirring rod (28);

rotating device (64) including set firmly in place on the preceding lateral wall of chamber (11) and with place rotation groove (20) of chamber (11) intercommunication, first axis of rotation (19) extend to rotate groove (20) preceding lateral wall and with place chamber (11) preceding lateral wall and rotate and be connected, rotate in groove (20) first axis of rotation (19) on set firmly first gear (21), first gear (21) below rotate groove (20) preceding lateral wall on be connected with two second axis of rotation (23), two second axis of rotation (23) are located two respectively under first axis of rotation (19), install the drive left side in rotation groove (20) preceding lateral wall second motor (22) of second axis of rotation (23), second axis of rotation (23) rear end is equipped with second gear (26) admittedly, second gear (26) with first gear (21) meshing, and a third gear (24) is fixedly arranged on the second rotating shaft (23), a chain (25) is connected to the third gear (24) in a rotating manner, and a stirring rod (28) is used for stirring the engineering bacteria on the first filter plate (12) so as to fully ferment the engineering bacteria.

2. The system for extracting enzyme through fermentation of composite engineering bacteria according to claim 1, characterized in that: enzyme preparation chamber (38) front side diapire has set firmly out enzyme groove (51), go out and install third automatically controlled ball valve (52) in enzyme groove (51), third automatically controlled ball valve (52) below place sliding connection on chamber (11) diapire and collect shell (53), be equipped with opening collection chamber (54) up in collecting shell (53), collect shell (53) front side place rotate on placing chamber (11) preceding lateral wall and be connected with second and rotate door (55), be equipped with four removals on casing (10) diapire mobile device (68) of casing (10).

3. The extraction system for producing enzyme by fermentation of composite engineering bacteria according to claim 1, characterized in that: thrust unit (65) including set firmly in place in the chamber (11) rear side wall and with place promotion groove (61) of chamber (11) intercommunication, first pneumatic cylinder (30) have set firmly on promotion groove (61) rear side wall, first pneumatic cylinder (30) are installed the orientation place first telescopic link (31) of chamber (11), push pedal (32) have set firmly on first telescopic link (31), push pedal (32) diapire with first filter plate (12) roof sliding connection.

4. The system for extracting enzyme through fermentation of composite engineering bacteria according to claim 2, characterized in that: first scraping device (66) including set firmly in rack (56) on enzyme powder pole (40), sliding connection has second sleeve (41) on enzyme powder pole (40), rack (56) top second sleeve (41) wall internal fixation has third motor (42), third axis of rotation (43) is installed in third motor (42), fourth gear (44) have set firmly on third axis of rotation (43), fourth gear (44) with rack (56) meshing, set firmly ejector pad (62) on second sleeve (41) preceding lateral wall, ejector pad (62) diapire with system enzyme chamber (38) diapire sliding connection.

5. The system for extracting enzyme through fermentation of composite engineering bacteria according to claim 2, characterized in that: the second is scraped and is got device (67) including set firmly in second pneumatic cylinder (45) on system enzyme chamber (38) right side roof, second pneumatic cylinder (45) are installed and are extended to second telescopic link (46) in system enzyme chamber (38), second telescopic link (46) lower extreme has set firmly scraper blade (47), scraper blade (47) right-hand member with second filter plate (50) sliding connection.

6. The system for extracting enzyme through fermentation of composite engineering bacteria according to claim 2, characterized in that: the moving device (68) comprises a bottom plate (57) fixedly arranged on the bottom wall of the machine shell (10), shock absorption rods (58) which are symmetrical in front and back positions are fixedly arranged on the bottom plate (57), and wheels (59) with brake pads are mounted at the lower ends of the shock absorption rods (58).

Images