JP6620301B1 - Microbial fermentation system with solid-liquid separation function - Google Patents

Abstract

A microbial fermentation system having a solid-liquid separation function is disclosed. A fermentation chamber is provided in the can, a power chamber is provided below the fermentation chamber, and a solid-liquid fermentation product is provided between the power chamber and the fermentation chamber. A sieving mechanism capable of separation is installed, a sieving plate and a sieving mechanism are installed in the fermentation chamber in the can, and the sieving mechanism lifts the sieving plate to form a sieving plate. A solid fermentation product and a liquid fermentation product can be separated, and the separated liquid can flow and return to the fermentation chamber through an external hole in the sieving plate. Then, the transposition mechanism can send the solid fermented product on the sieving plate into the solid chamber, and separate and store the solid fermented product and the liquid fermented product. [Selection diagram] Fig. 1

Description

The present invention relates to the field of fermenters, specifically a microbial fermentation system with a solid-liquid separation function.

In recent years, Japan's aquaculture and livestock have been developing rapidly, but the environmental problems created by pastoral and aquaculture have also become severe, and large amounts of sharks and livestock excrement have a serious impact on the ecological environment. Currently, existing technology uses methane gas produced by fermenting microorganisms as raw materials from livestock excreta and plant straw, but at the time of fermentation, solid fermented products are used for fermentation. Not only does it remain in the can but it is difficult to organize, and the separation liquid cannot be used, resulting in high maintenance costs.
A general microbial fermentation system cannot stir the fermented product during the fermentation process, and a microbial fermentation system having a stirring function cannot stir the culture solution slowly into the fermentation chamber at the same time as stirring. Fermentation efficiency of waste is low, and ordinary microbial fermentation systems cannot separate and store solid and liquid fermentations in the fermentation chamber, and the solid fermentation is left in the fermentation chamber In addition to continuing to ferment, the cost of cleaning the equipment is greatly increased.

Chinese Patent Application No. 108251272

An object of the present invention is to provide a microorganism fermentation system with a solid-liquid separation function, and to solve the above-described drawbacks in the existing technology.

A microorganism fermentation system with a solid-liquid separation function according to an embodiment of the present invention includes a can, a fermentation chamber is installed in the can, a power chamber is installed below the fermentation chamber, and the power chamber Between the fermentation chamber, a sieving mechanism capable of solid-liquid separation of the fermented product is installed, and the sieving mechanism includes a sieve tray that is slidably mounted in the fermentation chamber. External holes are installed symmetrically, a motor is installed in the rear inner wall of the power chamber, and a power rod is fixedly attached to the front side of the front output shaft of the motor. A first bevel gear is fixedly attached to the front side surface of the rod, and a meshing chamber is installed symmetrically in the power chamber in the front-rear direction. A transmission rod is rotatably mounted between the two, and a second bevel gear is fixedly attached to the transmission rod positioned in the power chamber, and the second bevel gear is fixed to the first bevel gear. Engage with the bevel gear, and when the motor rotates, the power rod rotates and interlocks. The solid fermented product is lifted, and the separated liquid flows from the outside hole, realizing the sieving function of solid-liquid separation.

A rotation mechanism having a stirring function is also installed on the front side of the fermentation chamber, a solid chamber is installed on the rear side of the fermentation chamber, and there is a rearrangement mechanism for rearranging the solid fermentation product above the solid chamber, The transposition mechanism can translocate the solid fermentation product separated by the sieving mechanism into the solid chamber, and a culture bottle is fixedly attached to the top surface of the can. Is equipped with a liquid dispensing mechanism that can slowly dispense the culture solution.

Based on the above technical plan, the sieving mechanism is composed of a lifting groove, a lifting rod, a third bevel gear, a fourth bevel gear, a thread block, and a sandwiching plate, and above the meshing chamber. The lifting groove is installed, the lifting groove communicates with the fermentation chamber, and the lifting rod is attached to the top wall of the fermentation chamber so as to be able to rotate symmetrically in the front-rear direction. The third bevel gear is fixedly attached to the bottom surface of the lifting rod, and the fourth bevel gear is fixedly attached to the left and right side surfaces of the transmission rod. The fourth bevel gear meshes with the third bevel gear, and the thread block is connected to the lifting rod. Attached by mountains, the pinching plates in the front and rear sides of said sieve tray is symmetrically fixedly mounted, said pinching plate is mounted for the threaded block and the slide.

Based on the above technical plan, a restriction groove that opens to the right is formed in the sheave tray, and a restriction plate is slidably mounted in the restriction groove, and a left side surface of the restriction plate. A first spring is fixedly attached between the restriction groove and the left inner wall of the restriction groove, an internal hole is installed in the restriction plate, and the external hole communicates with the internal hole. A catching groove is formed in the right inner wall of the chamber.

Based on the above technical plan, the rotation mechanism is configured by a storage chamber, a thrust chamber, a rotation shaft, a knob, and a stirrer, and the storage chamber communicates with the right side of the fermentation chamber. The thrust chamber is installed on the right side of the storage chamber, and the rotary shaft is rotatably mounted between the storage chamber and the right side of the can. The knob is fixedly attached, and the stirrer is fixedly attached to the left side surface of the rotating shaft.

Based on the above technical plan, the liquid discharge mechanism includes a first gear, a transmission chamber, a transmission rod, a second gear, a third gear, a driven chamber, a rotation chamber, an auxiliary rod, and a fourth rod. Consists of gear, chain, auxiliary shaft, rotating wheel, fifth bevel gear, rotating groove, push-up block, rotating block, tensile force groove, second spring, liquid chamber, and liquid dripping pipe The first gear is fixedly attached to the rotation shaft located in the thrust chamber, and the transmission chamber is installed on the left side of the thrust chamber. The transmission rod is rotatably mounted between the driving rod and the thrust chamber, and the portion of the transmission rod located in the thrust chamber is located at the position of the rod. Two gears are fixedly attached, the second gear meshes with the first gear, the third gear is fixedly attached to the left side surface of the transmission rod, and the upper side of the transmission chamber The driven chamber is installed so as to communicate with the place located in the culture bottle, the rotating chamber is installed on the right side of the driven chamber, and the rotating chamber is located between the rotating chamber and the driven chamber. An auxiliary rod is attached to be rotatable, the fourth gear is fixedly attached to the left side surface of the auxiliary rod, and the chain can be transmitted between the fourth gear and the third gear. The auxiliary shaft is fixedly attached between the front and rear inner walls of the turning chamber, and the turning wheel is fixedly attached to the auxiliary shaft. The fifth bevel gear is fixedly attached to an end surface, the fifth bevel gear meshes with the rotating ring, the liquid chamber is installed in the culture bottle, and the rotating chamber and the liquid chamber The turning groove is formed so as to communicate therewith, and the push-up block is slidably mounted in the turning groove, and the tensile force groove opened upward in the bottom wall of the liquid chamber The rotary block is hinged to the rear inner wall of the liquid chamber, and the second spring is fixed between the bottom surface of the rotary block and the bottom wall of the tensile force groove. The liquid dropping tube is installed between the liquid chamber and the fermentation chamber so as to communicate with each other, and the top surface of the liquid dropping tube is blocked by the rotating block. be able to.

Based on the above technical plan, a lid is attached to the inner wall of the liquid chamber by a screw thread.

Based on the above technical plan, the shift mechanism includes a slide groove, a scraper blade, a tooth block, a rotation groove, a positioning shaft, a fifth gear, a storage groove, a force transmission rod, a lathe, The slide plate is formed so as to communicate with the solid chamber and the fermentation chamber, and the scraper blade is slidably mounted in the slide groove, and the scraper The tooth block, which is a block resembling a rack, is fixedly attached to the top surface of the blade, and the turning groove is formed above the solid chamber. Between the front and rear inner walls of the turning groove, The stereotaxic shaft is attached so as to rotate, and the fifth gear is fixedly attached to the stereotaxic shaft, and the fifth gear meshes with the tooth block. The storage groove is formed in the rear inner wall of the solid chamber, and the force transmission rod is rotatably mounted in the right inner wall of the turning groove. It extends to the left and penetrates the left side surface of the can, and the lathe is fixedly attached to the left side surface of the force transmission rod, and the push plate is attached to the force transmission rod by a screw thread. The push plate meshes with the fifth gear.

Based on the above technical plan, a switch is fixedly attached to the bottom surface of the slide groove, an electric wire is fixedly attached to the bottom surface of the switch, and the electric wire is connected so as to be able to energize the motor. Yes.

The beneficial effect of the present invention is: a sieving plate and a sieving mechanism are installed in the fermentation chamber in the can of the present invention, and the sieving mechanism lifts the sieving plate and sifts the plate. The solid fermented product and the liquid fermented product can be separated, and the separated liquid can flow and return to the fermentation chamber from the external hole in the sieving plate. Installed, the transposition mechanism can send the solid fermented material on the sieving plate into the solid chamber, separate the solid fermented product from the liquid fermented product and store it, and the front side of the fermentation chamber also has a rotating mechanism And the liquid discharge mechanism are installed, the rotation mechanism can stir the fermented material that has entered the fermentation chamber, the speed of the fermentation can be increased, and the liquid discharge mechanism agitates the fermented product in conjunction with the rotation mechanism and at the same time the fermentation chamber Slowly drop the culture medium into The speed of fermentation of wastes such as excrement and rice cake can be increased, and a restriction plate is installed in the restriction groove of the sieving plate. It can slide to the right and seals the outer hole in the sieving plate to prevent pressure on the solids and return them into the fermentation chamber.

In order to be able to explain in more detail the technical solutions in the embodiments of the invention or in the existing technology, the following is a brief introduction to the accompanying drawings necessary to explain the embodiments or the existing technology, and as will be clear, The following attached drawings are only some embodiments of the invention, and those skilled in the art can acquire other attached drawings based on these attached drawings without paying creative labor. In order to explain the present invention in detail with reference to FIGS. 1 to 4 below, and to provide a convenient explanation, the following directions are defined as follows: FIG. 1 is a front view of the apparatus of the present invention. The front-rear direction and the front-rear direction in FIG.

FIG. 1 is an overall schematic diagram of a microbial fermentation system with a solid-liquid separation function of the present invention. FIG. 2 is a schematic sectional view taken along the line AA in FIG. 1 of the present invention. 3 is an enlarged schematic diagram of the present invention at B in FIG. FIG. 4 is a schematic plan view of the sheave tray in the present invention.

1 to 4, the microbial fermentation system with a solid-liquid separation function according to the embodiment of the present invention includes a can 88, a fermentation chamber 15 is installed in the can 88, and the bottom of the fermentation chamber 15. Is provided with a power chamber 37, and between the power chamber 37 and the fermentation chamber 15, a sieving mechanism 103 capable of solid-liquid separation of the fermented material is installed. Including a sheave tray 31 mounted so as to be slidable therein, an outer hole 38 is installed symmetrically in the sheave tray 31, and a motor 32 is installed in the rear inner wall of the power chamber 37, A power rod 33 is fixedly attached to the front side surface of the forward output shaft of the motor 32, and a first bevel gear 34 is fixedly attached to the front side surface of the power rod 33. The engagement chamber 53 is symmetrically installed in the power chamber 37 in the front-rear direction, and a transmission rod 56 is rotatably attached between the front and rear engagement chambers 53. A second bevel gear 35 is fixedly mounted at a position located in the chamber 37, the second bevel gear 35 meshes with the first bevel gear 34, and when the motor 32 rotates, the power rod 33 rotates. The power rod 33 rotates and interlocks the transmission rod 56 with the first bevel gear 34 and the second bevel gear 35, and the transmission rod 56 rotates to move and move the sheave tray 31 upward to lift the solid fermented product. Flows out of the outer hole 38 and realizes a sieving function for solid-liquid separation. A rotating mechanism 102 having a stirring function is also installed on the front side of the chamber 15, a solid chamber 24 is installed on the rear side of the fermentation chamber 15, and a rearrangement mechanism for rearranging the solid fermentation product above the solid chamber 24. 104, the shift mechanism 104 can transfer the solid fermentation product separated by the sieving mechanism 103 into the solid chamber 24, and a culture bottle 99 is fixedly attached to the top surface of the can 88. A liquid dispensing mechanism 101 is installed in the culture bottle 99. The liquid dispensing mechanism 101 can slowly remove the culture solution.

In one embodiment, the sieving mechanism 103 also includes a lifting groove 52 installed above the meshing chamber 53, and the lifting groove 52 communicates with the fermentation chamber 15. A lifting rod 14 is mounted in the top wall of the chamber 15 so as to be able to rotate symmetrically in the longitudinal direction. The lifting rod 14 extends downward and penetrates the top wall of the meshing chamber 53. A third bevel gear 54 is fixedly attached to the bottom surface of the transmission rod, a fourth bevel gear 55 is fixedly attached to the left and right side surfaces of the transmission rod 56, and the fourth bevel gear 55 meshes with the third bevel gear 54. A thread block 50 is attached to the lifting rod 14 by a thread, and the front and rear side surfaces of the sheave tray 31 are The pinching plate 51 is symmetrically fixedly mounted, said pinching plate 51 is mounted for sliding said thread block 50,
When the motor 32 rotates, the power rod 33 is rotationally interlocked, the power rod 33 is rotationally interlocked with the first bevel gear 34 and the second bevel gear 35, and the transmission rod 56 is connected with the fourth bevel gear 55 and the third bevel gear 14. The lifting rod 14 is rotated and interlocked, the lifting rod 14 is rotated and the thread block 50 is moved and moved upward, and the thread block 50 pulls and moves the sandwich plate 51 to move the sheave tray 31 upward and solid fermentation. The product is separated from the liquid fermented product.

In one embodiment, the sheave tray 31 is formed with a restriction groove 30 that opens to the right, and the restriction plate 40 is slidably attached to the restriction groove 30. A first spring 29 is fixedly attached between the left side surface of the limiting plate 40 and the left inner wall of the limiting groove 30, an internal hole 39 is installed in the limiting plate 40, and the external hole 38. Is communicated with the inner hole 39, and a catching groove 13 is formed on the right inner wall of the fermentation chamber 15,
After the sheave tray 31 slides upward, the restricting groove 30 is engaged with the catching groove 13, the first spring 29 releases the elasticity, and the restricting plate 40 is pushed to slide to the right, and the outer hole 38 is moved to the inner hole 39. And the solid fermentation product is prevented from being pressured back into the fermentation chamber 15 when the translocation mechanism 104 is activated.

Further, in one embodiment, the rotating mechanism 102 also includes a storage chamber 41 installed to communicate with the right side of the fermentation chamber 15, and a thrust chamber 49 is installed on the right side of the storage chamber 41. A rotary shaft 46 is rotatably attached between the storage chamber 41 and the right side surface of the can 88, and a knob 47 is fixedly attached to the right side surface of the rotary shaft 46. A stirrer 42 is fixedly attached to the left side surface of 46,
When the fermented product is agitated, the knob 47 is manually pushed forward to move the agitator 42 forward by the rotating shaft 46, and the knob 47 is moved after the agitator 42 enters the fermentation chamber 15. The knob 47 is rotated and the stirrer 42 is rotationally interlocked by the rotating shaft 46 to realize a stirring function.

In one embodiment, the liquid dispensing mechanism 101 also includes a first gear 48 fixedly attached to the rotating shaft 46 at a position in the thrusting chamber 49. A transmission chamber 98 is installed on the left side of the thrusting chamber 49, and a transmission rod 45 is rotatably mounted between the transmission chamber 98 and the thrusting chamber 49. A second gear 44 is fixedly attached at a position located in the moving chamber 49, the second gear 44 meshes with the first gear 48, and a left side surface of the transmission rod 45 Three gears 43 are fixedly attached, and a driven chamber 59 communicates with the upper side of the transmission chamber 98 in the culture bottle 99. A rotation chamber 65 is installed on the right side of the driven chamber 59, and an auxiliary rod 61 is rotatably mounted between the rotation chamber 65 and the driven chamber 59. A fourth gear 60 is fixedly attached to the left side surface, and a chain 58 is attached between the fourth gear 60 and the third gear 43 so as to be able to transmit between the front and rear inner walls of the turning chamber 65. An auxiliary shaft 64 is fixedly attached to the auxiliary shaft 64, and a rotating wheel 63 is fixedly attached to the auxiliary shaft 64. A fifth bevel gear 62 is fixedly attached to the right end surface of the auxiliary rod 61, and Five bevel gears 62 are engaged with the rotating ring 63, the liquid chamber 12 is installed in the culture bottle 99, and the rotating chamber 65 and the liquid cha A rotation groove 69 is formed so as to communicate with the bar 12, and a push-up block 70 is slidably mounted in the rotation groove 69, and the bottom wall of the liquid chamber 12 is positioned upward. An opening tensile force groove 66 is formed, and a rotary block 68 is connected to the rear inner wall of the liquid chamber 12 by a hinge, and between the bottom surface of the rotary block 68 and the bottom wall of the tensile force groove 66. The second spring 67 is fixedly attached, and a liquid dropping pipe 57 is installed between the liquid chamber 12 and the fermentation chamber 15, and the top surface of the liquid dropping pipe 57 is the rotating block. 68 can be blocked,
When the stirring mechanism 102 starts to operate, the rotation shaft 46 rotates and interlocks the second gear 44 by the first gear 48, the second gear 44 rotates and interlocks the third gear 43 by the transmission rod 45, and the third gear 43 rotates. The auxiliary rod 61 is rotationally interlocked by the chain 58 and the fourth gear 60, the auxiliary rod 61 is rotationally interlocked by the fifth bevel gear 62, and the rotating wheel 63 periodically pushes the rotary block 68 by the push-up block 70. The second spring 67 releases the elasticity, pulls back the rotary block 68, and realizes a function of slowly dropping the liquid.

In one embodiment, a lid 11 is attached to the inner wall of the liquid chamber 12 by a screw thread.
The lid 11 can be turned and removed from the culture bottle 99, and the culture medium is added into the liquid chamber 12 to support the liquid dispensing mechanism 101 for dispensing the liquid.

In one embodiment, the displacement mechanism 104 also includes a slide groove 23 formed to communicate between the solid chamber 24 and the fermentation chamber 15. A scraper blade 26 is slidably mounted. A tooth block 25, which is a rack-like block, is fixedly attached to the top surface of the scraper blade 26. A rotating groove 18 is provided above the solid chamber 24. The positioning shaft 20 is rotatably mounted between the front and rear inner walls of the turning groove 18, and a fifth gear 22 is fixedly attached to the positioning shaft 20, and the fifth gear 22 is A storage groove 21 is formed on the rear inner wall of the solid chamber 24, and can be engaged with the tooth block 25. The force transmission rod 17 is rotatably mounted in the inside, and the force transmission rod 17 extends leftward and penetrates the left side surface of the can 88, and the left side surface of the force transmission rod 17 rotates. A board 19 is fixedly attached, a push plate 16 is attached to the force transmission rod 17 by a screw thread, and the push plate 16 meshes with the fifth gear 22;
After the motor 32 stops rotating, the tooth block 25 is driven by the scraper blade 26 and the sheave tray 31 to mesh with the fifth gear 22, and the person manually rotates the lathe 19, and the lathe 19 rotates the force transmission rod 17. To move the push plate 16 to the right, the push plate 16 causes the fifth gear 22 to slide the tooth block 25 and the scraper blade 26 backward, and the scraper blade 26 slides backward to move the solid in the sheave tray 31. The fermented material is turned into the solid chamber 24 to realize the function of dislocation.

In one embodiment, a switch 27 is fixedly attached to the bottom surface of the slide groove 23, an electric wire 28 is fixedly attached to the bottom surface of the switch 27, and the electric wire 28 is connected to the motor 32. And connected so that it can be energized
After the sieving mechanism 103 thrusts and moves the sheave tray 31 to move upward, the sheave tray 31 pulls and moves the switch 27 to move upward, the switch 27 leaves the contact with the energizing block 26, and the motor 32 After obtaining the electrical signal from 28, the rotation is stopped.

In use, the motor 32 rotates to interlock the power rod 33, the power rod 33 rotationally interlocks the transmission rod 56 by the first bevel gear 34 and the second bevel gear 35, and the transmission rod 56 contacts the fourth bevel gear 55. The lifting rod 14 is rotationally interlocked with the third bevel gear 54, and the lifting rod 14 rotates to interlock the movement of the thread block 50. The thread block 50 pulls and moves the sandwich plate 51 to move the sheave tray 31 upward. After moving the solid fermented product from the liquid fermented product and sliding the sieve tray 31 upward, the limiting groove 30 communicates with the catching groove 13, and the first spring 29 releases the elasticity and drives the limiting plate 40. When the dislocation mechanism 104 is activated when the outer hole 38 is not in communication with the inner hole 39, the solid fermented product is When the fermented product is agitated by preventing pressure from being returned into the fermentation chamber 15, the knob 47 is manually pushed forward, and the knob 47 moves the agitator 42 forward by the rotating shaft 46. After the stirrer 42 enters the fermentation chamber 15, the knob 47 is rotated, and the knob 47 rotates the stirrer 42 by the rotation shaft 46 to realize the stirring function, and the stirring mechanism 102 starts to operate. The rotation shaft 46 rotates and interlocks the second gear 44 with the first gear 48, the second gear 44 rotates and interlocks the third gear 43 with the transmission rod 45, and the third gear 43 includes the chain 58 and the fourth gear 60. The auxiliary rod 61 is rotationally interlocked by the rotation, the auxiliary rod 61 is rotationally interlocked by the fifth bevel gear 62, and the rotating wheel 63 rotates to rotate the rotating block 68 periodically. The second spring 67 releases the elasticity and pulls back the rotary block 68 to realize the function of slowly dropping the liquid, and the lid 11 can be rotated and removed from the culture bottle 99, into the liquid chamber 12. After adding the culture solution and supporting the liquid discharging mechanism 101 to discharge the liquid, the sieving mechanism 103 pushes and moves the sieve tray 31 upward, and then the sieve tray 31 pulls and moves the switch 27 to move upward. The switch 27 is removed from contact with the energizing block 26, the motor 32 stops rotating after obtaining an electrical signal from the electric wire 28, and after the motor 32 stops rotating, the tooth block 25 is moved to the scraper blade 26, the sheave tray 31, Is engaged with the fifth gear 22 and the person manually rotates the lathe 19 so that the lathe 19 is turned to the force transmission rod 1. 7, the push plate 16 is moved and interlocked to the right, and the push plate 16 is slidably interlocked with the tooth block 25 and the scraper blade 26 by the fifth gear 22. The solid fermented product is rotated into the solid chamber 24 to realize the function of dislocation.

The beneficial effect of the present invention is: a sieving plate and a sieving mechanism are installed in the fermentation chamber in the can of the present invention, and the sieving mechanism lifts the sieving plate and sifts the plate. The solid fermented product and the liquid fermented product can be separated, and the separated liquid can flow and return to the fermentation chamber from the external hole in the sieving plate. Installed, the transposition mechanism can send the solid fermented material on the sieving plate into the solid chamber, separate the solid fermented product from the liquid fermented product and store it, and the front side of the fermentation chamber also has a rotating mechanism And the liquid discharge mechanism are installed, the rotation mechanism can stir the fermented material that has entered the fermentation chamber, and the speed of the fermentation can be increased. Slowly drop the culture medium into The speed of fermentation of wastes such as excrement and rice cake can be increased, and a restriction plate is installed in the restriction groove of the sieving plate. It can slide to the right and seals the outer hole in the sieving plate to prevent pressure on the solids and return them into the fermentation chamber.

The above are only preferred embodiments of the present invention, and are not intended to limit the present invention. Any modification, replacement of the same effect, improvement, etc., all within the spirit and principle of the present invention. Should be covered within the scope of protection.

Claims (8)

In front view, a can is included, a fermentation chamber is installed in the can, a power chamber is installed below the fermentation chamber, and a fermented product is liquid-solid between the power chamber and the fermentation chamber. A sieving mechanism capable of performing separation is installed, and the sieving mechanism includes a sieve tray that is slidably mounted in the fermentation chamber, and external holes are installed symmetrically in the sieve tray, and the power A motor is installed in the rear inner wall of the chamber, a power rod is fixedly attached to the front side surface of the front-facing output shaft of the motor, and a first bevel gear is fixedly attached to the front side surface of the power rod. A meshing chamber is installed in the power chamber symmetrically in the front-rear direction, and a transmission rod can be rotated between the front and rear meshing chambers. A second bevel gear is fixedly attached to the transmission rod located in the power chamber, the second bevel gear meshes with the first bevel gear, and when the motor rotates, the power rod The power rod is rotated and linked with the first bevel gear and the second bevel gear, the sheave tray is moved and linked with the rotation of the transmission rod, the solid fermented product is lifted, and the separated liquid is in the external hole. Flow from inside, realizing the sieving function of solid-liquid separation,
A rotation mechanism having a stirring function is also installed on the front side of the fermentation chamber, a solid chamber is installed on the rear side of the fermentation chamber, and there is a rearrangement mechanism for rearranging the solid fermentation product above the solid chamber, The transposition mechanism can translocate the solid fermentation product separated by the sieving mechanism into the solid chamber, and a culture bottle is fixedly attached to the top surface of the can. Is a microbial fermentation system with a solid-liquid separation function, which is equipped with a liquid discharge mechanism that can slowly discharge the culture solution. The sieving mechanism is composed of a lifting groove, a lifting rod, a third bevel gear, a fourth bevel gear, a thread block, and a sandwiching plate,
The lifting groove is installed above the meshing chamber, the lifting groove communicates with the fermentation chamber, and is attached to the top wall of the fermentation chamber so that the lifting rod can rotate symmetrically in the front-rear direction. The lifting rod extends downward and penetrates the top wall of the meshing chamber, the third bevel gear is fixedly attached to the bottom surface of the lifting rod, and the left and right side surfaces of the transmission rod are Four bevel gears are fixedly attached, the fourth bevel gear meshes with the third bevel gear, the thread block is attached to the lifting rod by a thread, and the sandwiching plates are disposed on the front and rear sides of the sheave tray. Mounted symmetrically and fixedly so that the clip plate can slide with the thread block Solid-liquid microbial fermentation system with isolation, as in claim 1, characterized in that are. The sheave tray is formed with a restriction groove that opens to the right, and a restriction plate is slidably mounted in the restriction groove, and a left side surface of the restriction plate and a left inner wall of the restriction groove A first spring is fixedly attached between the inner plate, an inner hole is installed in the restriction plate, the outer hole communicates with the inner hole, and a catching groove is formed on the right inner wall of the fermentation chamber. The microbial fermentation system with a solid-liquid separation function according to claim 1, wherein The rotation mechanism includes a storage chamber, a thrust chamber, a rotation shaft, a knob, and a stirrer.
The right side of the fermentation chamber is installed so that the storage chamber communicates, the right side of the storage chamber is provided with the thrusting chamber, and the rotating shaft is provided between the storage chamber and the right side of the can. The knob is fixedly attached to the right side surface of the rotating shaft, and the stirrer is fixedly attached to the left side surface of the rotating shaft. Item 2. A microorganism fermentation system with a solid-liquid separation function according to Item 1. The liquid discharge mechanism includes a first gear, a transmission chamber, a transmission rod, a second gear, a third gear, a driven chamber, a turning chamber, an auxiliary rod, a fourth gear, a chain, and an auxiliary shaft. And a rotating ring, a fifth bevel gear, a rotating groove, a push-up block, a rotating block, a tensile force groove, a second spring, a liquid chamber, and a liquid dropping pipe,
The first gear is fixedly attached to the rotation shaft located in the thrust chamber, the transmission chamber is installed on the left side of the thrust chamber, and the transmission chamber and the The transmission rod is attached so as to rotate between the thrusting chamber and the second gear is fixedly attached to a portion of the transmission rod located in the thrusting chamber, A second gear meshes with the first gear, the third gear is fixedly attached to the left side surface of the transmission rod, and is located in the culture bottle on the upper side of the transmission chamber Is installed so that the driven chamber communicates, and the rotating chamber is installed on the right side of the driven chamber, the rotating chamber and the driven chamber The auxiliary rod is rotatably mounted between the auxiliary rod, the fourth gear is fixedly attached to the left side surface of the auxiliary rod, and the chain is between the fourth gear and the third gear. The auxiliary shaft is fixedly attached between the front and rear inner walls of the turning chamber, the rotating wheel is fixedly attached to the auxiliary shaft, and is attached to the right end surface of the auxiliary rod. The fifth bevel gear is fixedly attached, the fifth bevel gear meshes with the rotating wheel, the liquid chamber is installed in the culture bottle, and between the rotating chamber and the liquid chamber Is formed so that the turning groove communicates, and the push-up block is slidably mounted in the turning groove, and the upper wall is placed on the bottom wall of the liquid chamber The tensile force groove that is open to the liquid chamber is formed, the rotary block is connected to the rear inner wall of the liquid chamber by a hinge, and the bottom surface of the rotary block and the bottom wall of the tensile force groove are connected to the rotary block. A second spring is fixedly installed, the liquid dropping pipe is installed between the liquid chamber and the fermentation chamber, and the top surface of the liquid dropping pipe is blocked by the rotating block. The microbial fermentation system with a solid-liquid separation function according to claim 1, wherein The microbial fermentation system with a solid-liquid separation function according to claim 1, wherein a lid is attached to an inner wall of the liquid chamber with a screw thread. The shift mechanism is composed of a slide groove, a scraper blade, a tooth block, a rotation groove, a positioning shaft, a fifth gear, a storage groove, a force transmission rod, a lathe, and a push plate.
The slide groove is formed to communicate between the solid chamber and the fermentation chamber, and the scraper blade is slidably mounted in the slide groove, and a rack is mounted on the top surface of the scraper blade. The tooth block, which is a block similar to the above, is fixedly attached, the turning groove is formed above the solid chamber, and the localization shaft can rotate between the front and rear inner walls of the turning groove. The fifth gear is fixedly attached to the stereotaxic shaft, the fifth gear can mesh with the tooth block, and the storage groove is formed on the rear inner wall of the solid chamber. The force transmission rod is rotatably mounted in the right inner wall of the turning groove, and the force transmission rod extends leftward to the left of the can. The lathe is fixedly attached to the left side surface of the force transmission rod, the push plate is attached to the force transmission rod by a screw thread, and the push plate is attached to the fifth gear. The microbial fermentation system with a solid-liquid separation function according to claim 1, wherein the microbial fermentation system has a solid-liquid separation function. The switch is fixedly attached to a bottom surface of the slide groove, an electric wire is fixedly attached to the bottom surface of the switch, and the electric wire is connected to the motor so as to be energized. 2. A microbial fermentation system with a solid-liquid separation function according to 1.

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