JP2020195360A - Microbe fermentation system with solid liquid separation function - Google Patents

Abstract

To disclose a microbe fermentation system with a solid liquid separation function.SOLUTION: A microbe fermentation system comprises a can; in the can, a fermentation chamber is installed; a power chamber is installed below the fermentation chamber; a screening mechanism for performing solid liquid separation to a fermentation product is installed between the power chamber and the fermentation chamber. In the fermentation chamber in the can, a screening plate and a screening mechanism are installed. The screening mechanism lifts up the screening plate for separating a solid fermentation product and a liquid fermentation product on the screening plate, and the separated liquid flows and returns into the fermentation chamber from an external hole provided on the screening plate. The device comprises therein a transition mechanism; the transition mechanism feeds the solid fermentation product on the screening plate into a solid chamber, and the solid fermentation product and the liquid fermentation product can be stored in a separated manner.SELECTED DRAWING: Figure 1

Description

The present invention is involved in the field of fermenters, and specifically is a microbial fermentation system with a solid-liquid separation function.

In recent years, Japan's aquaculture industry and livestock have developed rapidly, but the environmental problems created by livestock and aquaculture have become severe, and a large amount of straw and livestock excrement have a serious impact on the ecological environment. Currently, existing technology uses livestock excrement and plant straw as raw materials and profits from methane gas produced by fermenting microorganisms, but at the time of fermentation, solid fermented products are for fermentation. Not only is it difficult to organize because it remains in the can, but also the separation liquid cannot be used, and the maintenance cost is high.
A general microbial fermentation system cannot stir the fermented product during the fermentation process, and a microbial fermentation system with a stirring function cannot slowly drop the culture solution into the fermentation chamber at the same time as stirring. , Waste fermentation efficiency is low, and ordinary microbial fermentation systems cannot separate and store solid and liquid fermentation products in the fermentation chamber, leaving the solid fermentation products in the fermentation chamber. Not only does it not continue to ferment, but it also greatly increases the cost of cleaning the equipment.

Publication No. 108251272 of Chinese Patent Application

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

The microbial fermentation system with a solid-liquid separation function of the 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 and the power chamber are installed. A sieving mechanism capable of solid-liquid separation of the fermented product is installed between the fermentation chamber and the sieving chamber, and the sieving mechanism includes a sheave tray mounted so as to be slidable in the fermentation chamber, and is contained in the sheave tray. The 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 surface of the forward-facing output shaft of the motor. A first bevel gear is fixedly attached to the front surface of the rod, a meshing chamber is installed symmetrically in the front and rear of the power chamber, and a transmission rod is attached between the front and rear meshing chambers so that the transmission rod can rotate. A second bevel gear is fixedly attached to a portion of the transmission rod located in the power chamber, the second bevel gear meshes with the first bevel gear, and the power rod rotates when the motor rotates. Interlocking, the power rod rotates and interlocks the transmission rod with the first bevel gear and the second bevel gear, and the transmission rod rotates to move the sheave tray upward and interlock, lift the solid fermented product, and the separation liquid is inside the outer hole. It flows from and realizes 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 a transfer mechanism for rearranging the solid fermented product is provided above the solid chamber. The transfer mechanism can transfer the solid fermented product separated by the sieving mechanism into the solid chamber, and a culture bottle is fixedly attached to the top surface of the can and into the culture bottle. Is equipped with a liquid discharge mechanism that can slowly discharge 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 screw thread block, and a sandwich plate, and above the meshing chamber. The lifting groove is installed, the lifting groove communicates with the fermentation chamber, and the lifting rod is installed in the top wall of the fermentation chamber so as to rotate symmetrically in the front-rear direction, and the lifting rod is lowered. 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 so as to extend to and penetrate the top wall of the meshing chamber. The fourth bevel gear is meshed with the third bevel gear, the thread block is attached to the lifting rod by a screw thread, and the sandwich plate is symmetrically and fixedly attached to the front and rear side surfaces of the sheave tray. The sandwich plate is attached so that it can slide with the screw thread block.

Based on the above technical plan, a limiting groove opened to the right is formed in the sheave tray, and the limiting plate is mounted in the limiting groove so as to be slidable, and the left side surface of the limiting plate is installed. A first spring is fixedly attached between the surface and the inner wall on the left side of the limiting groove, an internal hole is installed in the limiting plate, the external hole communicates with the internal hole, and the fermentation A hook groove is formed on the inner wall on the right side of the chamber.

Based on the above technical plan, the rotation mechanism is composed of a containment chamber, a pushing chamber, a rotation shaft, a knob, and a stirrer so that the containment chamber communicates with the right side of the fermentation chamber. The thrusting chamber is installed on the right side of the accommodating chamber, and is attached between the accommodating chamber and the right side surface of the can so that the rotating shaft can rotate, and on the right side surface of the rotating shaft. 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 turning chamber, an auxiliary rod, and a fourth gear. It consists of a gear, a chain, an auxiliary shaft, a turning wheel, a fifth bevel gear, a turning groove, a push-up block, a rotating block, a tensile force groove, a second spring, a liquid chamber, and a liquid dropping tube. The first gear is fixedly attached to the rotating shaft located in the thrusting chamber, and the transmission chamber is installed on the left side of the thrusting chamber. The transmission rod is rotatably attached between the and the thrusting chamber, and the second gear is fixedly attached to the transmission rod located in the thrusting chamber. , The second gear is meshed 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. The driven chamber is installed where there is communication, the rotating chamber is installed on the right side of the driven chamber, and the auxiliary rod is installed between the rotating chamber and the driven chamber so as to be rotatable. The fourth gear is fixedly attached to the left side surface of the auxiliary rod, and the chain is attached between the fourth gear and the third gear so that the chain can be transmitted to the front and rear of the turning chamber. The auxiliary shaft is fixedly attached between the inner walls, the turning wheel is fixedly attached to the auxiliary shaft, and the fifth bevel gear is fixedly attached to the right end surface of the auxiliary rod. The fifth bevel gear meshes with the turning wheel, the liquid chamber is installed in the culture bottle, and the turning groove is formed so as to communicate between the turning chamber and the liquid chamber. The push-up block is slidably installed in the turning groove, the tensile force groove opened upward is formed on the bottom wall of the liquid chamber, and the rear inner wall of the liquid chamber is formed. The rotating block is connected by a hinge, the second spring is fixedly attached between the bottom surface of the rotating block and the bottom wall of the tensile force groove, and between the liquid chamber and the fermentation chamber. The liquid dropping tube is installed so as to communicate with each other, and the top surface of the liquid dropping tube is closed by the rotating block. be able to.

Based on the above technical plan, a lid is screwed to the inner wall of the liquid chamber.

Based on the above technical plan, the transfer mechanism includes a slide groove, a scraper blade, a tooth block, a turning groove, a localization shaft, a fifth gear, a storage groove, a force transmission rod, a turning machine, and the like. It is composed of a push plate, the slide groove is formed so as to communicate between the solid chamber and the fermentation chamber, and the scraper blade is mounted in the slide groove so as to be slidable. The gear block, which is a rack-like block, is fixedly attached to the top surface of the blade, and the rotation groove is formed above the solid chamber, and between the front and rear inner walls of the rotation groove. The localization shaft is rotatably attached, the fifth gear is fixedly attached to the localization shaft, the fifth gear can mesh with the tooth block, and is attached to the rear inner wall of the solid chamber. The storage groove is formed, and the force transmission rod is mounted in the right inner wall of the rotation groove so as to be rotatable, and the force transmission rod extends to the left and penetrates the left side surface of the can. The turning disk 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 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 energized with the motor. There is.

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 the sieving plate. The solid and liquid fermented products can be separated from each other, and the separated liquid can flow and return to the fermentation chamber through the outer hole in the sieving plate, and there is also a transfer mechanism in the device. Installed, the transfer mechanism can send the solid fermented product on the sieving plate into the solid chamber, separate and store the solid and liquid fermented products, and also on the front side of the fermentation chamber a rotating mechanism. And a liquid brewing mechanism are installed, the rotation mechanism can stir the fermented product that has entered the fermentation chamber, the fermentation speed can be increased, and the liquid brewing mechanism stirs the fermented product by interlocking with the rotation mechanism and at the same time the fermentation chamber The culture solution can be slowly dropped into the inside to accelerate the fermentation rate of waste such as excrement and straw, and a restriction plate is installed in the restriction groove of the sieving plate. The transposition mechanism transports the solid fermented product and at the same time slides it to the right, sealing the outer holes in the sieving plate to prevent the solid material from being pressured back into the fermentation chamber.

In order to be able to explain in more detail the examples of the invention or the technical ideas in the existing technology, the following is a brief introduction to the illustrations necessary to explain the examples or the existing technology, and as is clear, The following illustrations are only examples of some of the inventions, and those skilled in the art can obtain other illustrations based on these illustrations without having to pay creative labor. In order to explain the present invention in detail with reference to FIGS. 1 to 4 below and to explain the present invention in a convenient manner, the following directions are defined as follows: FIG. 1 is a front view of the apparatus of the present invention, and is described above and below. The left-right front-back direction and the up-down, left-right front-back direction of the self-projection relationship in FIG. 1 are the same.

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

With reference to FIGS. 1 to 4, the microbial fermentation system with a solid-liquid separation function of the embodiment of the present invention includes a can 88, in which the fermentation chamber 15 is installed and below the fermentation chamber 15. A power chamber 37 is installed in the power chamber 37, and a sieving mechanism 103 capable of solid-liquid separation of fermented products is installed between the power chamber 37 and the fermentation chamber 15, and the sieving mechanism 103 is the fermentation chamber 15. A sheave tray 31 mounted so as to slide inside is included, 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, a first bevel gear 34 is fixedly attached to the front side surface of the power rod 33, and meshes with the power chamber 37. The chamber 53 is installed symmetrically in the front-rear direction, and the transmission rod 56 is rotatably attached between the front and rear meshing chambers 53, and is located in the power chamber 37 of the transmission rod 56. The second bevel gear 35 is fixedly attached, the second bevel gear 35 meshes with the first bevel gear 34, and when the motor 32 rotates, the power rod 33 is rotationally interlocked, and the power rod 33 and the first bevel gear 34 The transmission rod 56 is rotationally interlocked with the second bevel gear 35, the sheave tray 31 is moved and interlocked upward by the rotation of the transmission rod 56, the solid fermented product is lifted, and the separation liquid flows from the outer hole 38. A rotary mechanism 102 that realizes a solid-liquid separation sieving function and also has a stirring function is installed on the front side of the fermentation chamber 15, and a solid chamber 24 is installed on the rear side of the fermentation chamber 15. Above 24, there is a transposition mechanism 104 that translocates the solid fermented product, and the translocation mechanism 104 can displace the solid fermented product separated by the sieving mechanism 103 into the solid chamber 24, and the can. A culture bottle 99 is fixedly attached to the top surface of the 88, and a liquid discharge mechanism 101 capable of slowly discharging the culture liquid is installed in the culture bottle 99.

Further, 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 to perform the fermentation. A lifting rod 14 is installed in the top wall of the chamber 15 so as to be able to rotate symmetrically in the front-rear direction, and 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 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 screw thread block 50 is attached to the lifting rod 14 by a screw thread, a sandwich plate 51 is symmetrically and fixedly attached to the front and rear side surfaces of the sieve tray 31, and the sandwich plate 51 is attached to the thread block 50. Attached so that it can slide
When the motor 32 rotates, the power rod 33 is rotationally interlocked, the power rod 33 is rotationally interlocked with the transmission rod 56 by the first bevel gear 34 and the second bevel gear 35, and the transmission rod 56 is associated 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 screw thread block 50 is moved and interlocked upward, and the screw thread block 50 is moved by pulling the sandwich plate 51 to move the sheave tray 31 upward and solid fermentation. Separate the product from the liquid fermented product.

Further, in one embodiment, a limiting groove 30 opened to the right is formed in the sheave tray 31, and a limiting plate 40 is installed in the limiting groove 30 so as to be slidable. 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 outer hole 38 is provided. Is communicated with the internal hole 39, and a hooking groove 13 is formed on the inner wall on the right side of the fermentation chamber 15.
After the sheave tray 31 slides upward, the limiting groove 30 communicates with the catching groove 13, the first spring 29 releases the elasticity and pushes the limiting plate 40 to slide it to the right, and the outer hole 38 is the inner hole 39. It prevents the solid fermented product from being returned into the fermentation chamber 15 by applying pressure when the dislocation mechanism 104 operates.

Further, in one embodiment, the rotation mechanism 102 also includes a storage chamber 41 installed so as to communicate with the right side of the fermentation chamber 15, and a push chamber 49 is installed on the right side of the storage chamber 41. A rotating shaft 46 is rotatably attached between the accommodating 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 rotating shaft 46. A stirrer 42 is fixedly attached to the left side surface of the 46.
When stirring the fermented product, the knob 47 is manually pushed forward, the knob 47 moves the stirrer 42 forward by the rotating shaft 46, and the knob 47 is moved after the stirrer 42 enters the fermentation chamber 15. It is rotated, and the knob 47 rotates and interlocks the stirrer 42 with the rotating shaft 46 to realize the function of stirring.

Further, in one embodiment, the liquid discharging mechanism 101 also includes a first gear 48 fixedly attached to the rotating shaft 46 located in the pushing chamber 49. A transmission chamber 98 is installed on the left side of the thrusting chamber 49, and a transmission rod 45 is attached between the transmission chamber 98 and the thrusting chamber 49 so as to be rotatable, and the thrust of the transmission rod 45. A second gear 44 is fixedly attached to a position located in the moving chamber 49, the second gear 44 meshes with the first gear 48, and a second gear 44 is on the left side surface of the transmission rod 45. The three gears 43 are fixedly attached, and the driven chamber 59 is installed so as to communicate with the upper side of the transmission chamber 98 located in the culture bottle 99, and is installed on the right side of the driven chamber 59. A turning chamber 65 is installed, an auxiliary rod 61 is attached between the turning chamber 65 and the driven chamber 59 so as to be rotatable, and a fourth gear 60 is fixedly attached to the left side surface of the auxiliary rod 61. It is attached so that the chain 58 can be transmitted between the fourth gear 60 and the third gear 43, and the auxiliary shaft 64 is fixedly attached between the front and rear inner walls of the turning chamber 65. A turning 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 the fifth bevel gear 62 meshes with the turning wheel 63. A liquid chamber 12 is installed in the culture bottle 99, and a rotating groove 69 is formed so as to communicate between the rotating chamber 65 and the liquid chamber 12, and the rotating groove 69 is formed in the rotating groove 69. Is attached so that the push-up block 70 can slide, a tensile force groove 66 opened upward is formed on the bottom wall of the liquid chamber 12, and a rotating block 68 is hinged on the rear inner wall of the liquid chamber 12. A second spring 67 is fixedly attached between the bottom surface of the rotary block 68 and the bottom wall of the tensile force groove 66, and a liquid is connected between the liquid chamber 12 and the fermentation chamber 15. The dropping tube 57 is installed so as to communicate with each other, and the top surface of the liquid dropping tube 57 can be closed by the rotating block 68.
When the stirring mechanism 102 starts to operate, the rotating shaft 46 rotates the second gear 44 by the first gear 48, the second gear 44 rotates the third gear 43 by the transmission rod 45, and the third gear 43 moves. The auxiliary rod 61 is rotationally interlocked by the chain 58 and the fourth gear 60, the auxiliary rod 61 is rotationally interlocked with the rotating wheel 63 by the fifth bevel gear 62, and the rotating wheel 63 periodically pushes up the rotating block 68 by the push-up block 70. , The second spring 67 releases the elasticity to pull back the rotating block 68, and realizes a function of slowly dropping the liquid.

Further, 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 to be removed from the culture bottle 99, and the culture solution is added into the liquid chamber 12 to support the liquid discharge mechanism 101 to discharge the liquid.

Further, in one embodiment, the transfer mechanism 104 also includes a slide groove 23 formed so as to communicate between the solid chamber 24 and the fermentation chamber 15, and the slide groove 23 includes a slide groove 23. The scraper blade 26 is slidably attached, a gear block 25 which is a rack-like block is fixedly attached to the top surface of the scraper blade 26, and a turning groove 18 is above the solid chamber 24. A fifth gear 22 is fixedly attached to the localization shaft 20 so that the localization shaft 20 can rotate between the front and rear inner walls of the rotation groove 18, and the fifth gear 22 is formed. A storage groove 21 is formed in the rear inner wall of the solid chamber 24 so that it can mesh with the tooth block 25, and a force transmission rod 17 is installed in the right inner wall of the turning groove 18 so as to be rotatable. The force transmission rod 17 extends to the left and penetrates the left side surface of the can 88, and a turning disk 19 is fixedly attached to the left side surface of the force transmission rod 17, and the force transmission rod 17 is attached. A push plate 16 is attached to the wheel 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 pushed by the scraper blade 26 and the sheave tray 31 to mesh with the fifth gear 22, and the person manually rotates the turning disk 19 so that the rotating disk 19 causes the force transmission rod 17 to rotate. The push plate 16 is moved to the right and interlocked, the push plate 16 slides the tooth block 25 and the scraper blade 26 rearward by the fifth gear 22, and the scraper blade 26 slides rearward and is a solid on the sheave tray 31. The fermented product is rotated into the solid chamber 24 to realize the function of rearrangement.

Further, in one embodiment, the switch 27 is fixedly attached to the bottom surface of the slide groove 23, the electric wire 28 is fixedly attached to the bottom surface of the switch 27, and the electric wire 28 is the motor 32. Connected so that it can be energized with
After the sieving mechanism 103 pushes and moves the sheave tray 31 upward, the sheave tray 31 pulls and moves the switch 27 to move it upward, the switch 27 is separated from the contact with the energizing block 26, and the motor 32 is an electric wire. The rotation is stopped after obtaining the electric signal from 28.

At the time of use, the motor 32 rotates to rotate and interlock the power rod 33, 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 with the fourth bevel gear 55. The lifting rod 14 is rotationally interlocked with the third bevel gear 54, the lifting rod 14 is rotated to move and interlock the thread block 50 upward, and the thread block 50 pulls and moves the sandwich plate 51 to move the sheave tray 31 upward. After moving to separate the solid fermented product from the liquid fermented product and sliding the sheave tray 31 upward, the limiting groove 30 communicates with the catching groove 13, and the first spring 29 releases the elasticity to push the limiting plate 40. Slide to the right to prevent the outer hole 38 from communicating with the inner hole 39 and pressure the solid fermented product to return to the fermentation chamber 15 when the transposition mechanism 104 operates, allowing the fermented product to return into the fermentation chamber 15. When stirring, the knob 47 is manually pushed forward, the knob 47 moves and interlocks the stirrer 42 forward by the rotating shaft 46, and the knob 47 is rotated after the stirrer 42 enters the fermentation chamber 15. The knob 47 rotates and interlocks the stirrer 42 by the rotating shaft 46 to realize the function of stirring, and when the stirring mechanism 102 starts to operate, the rotating shaft 46 rotates and interlocks the second gear 44 by the first gear 48, and the second gear 44 The second gear 44 rotates and interlocks the third gear 43 with the transmission rod 45, the third gear 43 rotates and interlocks the auxiliary rod 61 with the chain 58 and the fourth gear 60, and the auxiliary rod 61 rotates with the fifth bevel gear 62. The rotation of 63 is interlocked, the rotation wheel 63 rotates to rotate the rotation block 68 periodically, the second spring 67 releases the elasticity to pull back the rotation block 68, and the function of slowly dropping the liquid is realized. The lid 11 can be rotated and removed from the culture bottle 99, the culture solution is added into the liquid chamber 12 to support the liquid discharge mechanism 101 to discharge the liquid, and the sieving mechanism 103 pushes the sheave tray 31 upward. After moving, the sheave tray 31 pulls the switch 27 to move it upward, the switch 27 breaks out of contact with the energizing block 26, and the motor 32 stops rotating after receiving an electrical signal from the wire 28. After the motor 32 stops rotating, the tooth block 25 is pushed by the scraper blade 26 and the sheave tray 31 to mesh with the fifth gear 22, and the person manually rotates the rotating disk 19 so that the rotating disk 19 rotates the force transmission rod. 1 The push plate 16 is moved and interlocked to the right by 7, the push plate 16 slides the tooth block 25 and the scraper blade 26 rearward by the fifth gear 22, and the scraper blade 26 slides rearward and is on the sheave tray 31. The solid fermented product is spun 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 the sieving plate. The solid and liquid fermented products can be separated from each other, and the separated liquid can flow and return to the fermentation chamber through the outer hole in the sieving plate, and there is also a transfer mechanism in the device. Installed, the transfer mechanism can send the solid fermented product on the sieving plate into the solid chamber, separate and store the solid and liquid fermented products, and also on the front side of the fermentation chamber a rotating mechanism. And a liquid brewing mechanism are installed, the rotation mechanism can stir the fermented product that has entered the fermentation chamber, the fermentation speed can be increased, and the liquid brewing mechanism stirs the fermented product at the same time by interlocking with the rotation mechanism The culture solution can be slowly dropped into the inside to accelerate the fermentation rate of waste such as excrement and straw, and a restriction plate is installed in the restriction groove of the sieving plate. The transposition mechanism transports the solid fermented product and at the same time slides it to the right, sealing the outer holes in the sieving plate to prevent the solid material from being pressured back into the fermentation chamber.

The above is merely a preferred embodiment of the present invention, and does not limit the present invention, and all modifications made in the spirit and principles of the present invention, replacement of the same effect, improvement, etc. are all the present invention. Should be covered within the scope of protection.

Claims (8)

In front view, it contains a can, a fermentation chamber is installed in the can, a power chamber is installed below the fermentation chamber, and a solid liquid in a fermented product is installed between the power chamber and the fermentation chamber. A sieving mechanism capable of separation is installed, and the sieving mechanism includes a sheave tray mounted so as to be slidable in the fermentation chamber, and external holes are installed symmetrically in the sheave tray to provide 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 forward-facing output shaft of the motor, and a first bevel gear is fixedly attached to the front side surface of the power rod. Attached, the meshing chamber is installed symmetrically in the front-rear direction in the power chamber, and the transmission rod is attached so as to be rotatable between the front-rear meshing chambers, and is located in the power chamber of the transmission rods. The second bevel gear is fixedly attached to the place where the second bevel gear is engaged, the second bevel gear is meshed with the first bevel gear, and when the motor rotates, the power rod is rotated and interlocked, and the power rod is the first bevel gear and the second bevel gear. The transmission rod is rotated and interlocked by, and the sheave tray is moved and interlocked upward by the rotation of the transmission rod, the solid fermented product is lifted, the separation liquid flows from the outer hole, and the solid-liquid separation sieving function is performed. Realized,
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 a transfer mechanism for rearranging the solid fermented product is provided above the solid chamber. The transfer mechanism can transfer the solid fermented product separated by the sieving mechanism into the solid chamber, and a culture bottle is fixedly attached to the top surface of the can and into the culture bottle. Is a microbial fermentation system with a solid-liquid separation function, which is characterized by 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 screw thread block, and a sandwich plate.
The lifting groove is installed above the meshing chamber, the lifting groove communicates with the fermentation chamber, and the lifting rod is installed in the top wall of the fermentation chamber so as to 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 third bevel gear is fixedly attached to the left and right side surfaces of the transmission rod. The four bevel gears are fixedly attached, the fourth bevel gear is meshed with the third bevel gear, the thread block is attached to the lifting rod by a screw thread, and the sandwich plate is attached to the front and rear side surfaces of the sheave tray. The microbial fermentation system with a solid-liquid separation function according to claim 1, wherein the sandwiching plate is symmetrically and fixedly attached so as to be slidable with the thread block. A limiting groove opened to the right is formed in the sheave tray, and the limiting plate is mounted so as to be slidable in the limiting groove, and the left side surface of the limiting plate and the left inner wall of the limiting groove A first spring is fixedly attached between them, an internal hole is installed in the limiting plate, the external hole communicates with the internal hole, and a hooking 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 microbial fermentation system is formed. The rotating mechanism is composed of an accommodating chamber, a pushing chamber, a rotating shaft, a knob, and a stirrer.
The accommodating chamber is installed on the right side of the fermentation chamber so as to communicate with the accommodating chamber, the pushing chamber is installed on the right side of the accommodating chamber, and the rotating shaft is located between the accommodating chamber and the right side surface of the can. Is attached so as to be rotatable, 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. The microbial 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. , A turning wheel, a fifth bevel gear, a turning groove, a push-up block, a rotating block, a tensile force groove, a second spring, a liquid chamber, and a liquid dropping tube.
The first gear is fixedly attached to a portion of the rotating shaft located in the thrusting chamber, and the transmission chamber is installed on the left side of the thrusting chamber, and the transmission chamber and the transmission chamber are described. The transmission rod is attached to the thrusting chamber so that it can rotate, and the second gear is fixedly attached to the transmission rod located in the thrusting chamber. The second gear is meshed 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. The driven chamber is installed so as to communicate with each other, the turning chamber is installed on the right side of the driven chamber, and the auxiliary rod is installed between the turning chamber and the driven chamber so as to be rotatable. The fourth gear is fixedly attached to the left side surface of the auxiliary rod, and the chain is attached between the fourth gear and the third gear so that the chain can be transmitted, and the front and rear inner walls of the turning chamber. The auxiliary shaft is fixedly attached between the auxiliary shafts, the turning wheel is fixedly attached to the auxiliary shaft, and the fifth bevel gear is fixedly attached to the right end surface of the auxiliary rod. The bevel gear meshes with the turning wheel, the liquid chamber is installed in the culture bottle, and the turning groove is formed so as to communicate between the turning chamber and the liquid chamber. The push-up block is slidably mounted in the turning groove, the tensile force groove opened upward is formed in the bottom wall of the liquid chamber, and the rotation is formed in the rear inner wall of the liquid chamber. The blocks are connected by a hinge, the second spring is fixedly attached between the bottom surface of the rotating block and the bottom wall of the tensile force groove, and the liquid is connected between the liquid chamber and the fermentation chamber. The microbial fermentation system with a solid-liquid separation function according to claim 1, wherein the dropping tubes are installed so as to communicate with each other, and the top surface of the liquid dropping tube can be closed by the rotating block. The microbial fermentation system with a solid-liquid separation function according to claim 1, wherein a lid is attached to the inner wall of the liquid chamber by a screw thread. The dislocation mechanism is composed of a slide groove, a scraper blade, a tooth block, a turning groove, a localization shaft, a fifth gear, a storage groove, a force transmission rod, a turning machine, and a push plate.
The slide groove is formed so as to communicate between the solid chamber and the fermentation chamber, the scraper blade is mounted in the slide groove so as to slide, and a rack is placed on the top surface of the scraper blade. The tooth block, which is a block similar to the above, is fixedly attached, and the rotation groove is formed above the solid chamber so that the localization axis can rotate between the front and rear inner walls of the rotation groove. The fifth gear is fixedly attached to the localization 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 mounted in the inner wall on the right side of the rotation groove so as to be rotatable, and the force transmission rod extends to the left and penetrates the left side surface of the can. The first aspect of the invention is characterized in that the turning disk is fixedly attached to the left side surface, the push plate is attached to the force transmission rod by a screw thread, and the push plate is engaged with the fifth gear. A microbial fermentation system with a solid-liquid separation function described in. The claim is characterized in that 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 to the motor so as to be energized. The microbial fermentation system with a solid-liquid separation function according to 1.

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