CN112495574A - Caffeine equipment for decomposing defective coffee beans and old coffee beans through microbial aerobic fermentation - Google Patents

Abstract

The invention relates to a coffee bean treatment device, in particular to a caffeine device for decomposing inferior coffee beans and old coffee beans through microbial aerobic fermentation, wherein the inferior coffee beans and old coffee beans are generally used as wastes in the coffee bean processing field to be burned or buried, but the nutritional components of the inferior coffee beans and old coffee beans are not changed greatly, in order to improve the application value of the inferior coffee beans and old coffee beans, the device is invented, coffee beans doped with new and old inferior coffee beans are added into a primary screening assembly, the primary screening can screen mildew beans with density smaller than water, the secondary screening can screen inferior beans with density smaller than water, the screened inferior beans, mildew beans and microbial substrates are added into an aerobic fermentation decomposition box, after Acidulo microorganisms rapidly propagate and become flora, the PH of a fermentation environment is rapidly reduced to form an acidic environment, and the growth of pathogenic fungi of the coffee beans and old coffee beans is inhibited, meanwhile, the flavor of the defective coffee beans and the old coffee beans is improved.

Description

Caffeine equipment for decomposing defective coffee beans and old coffee beans through microbial aerobic fermentation

Technical Field

The invention relates to a coffee bean treatment device, in particular to a caffeine device for decomposing inferior coffee beans and old coffee beans through microbial aerobic fermentation.

Background

The coffee beans are easy to mildew due to careless storage, the quality of the coffee beans is influenced, and the taste of the coffee is influenced by incomplete peeling of the coffee beans. The defective coffee beans and the old coffee beans are generally burned or buried as wastes in the field of coffee bean processing, but the nutritional ingredients of the defective coffee beans and the old coffee beans are not changed much, and the burning and the burying are not favorable for the deep utilization of the coffee beans. The device is invented in order to improve the application value of defective coffee beans and old coffee beans.

Disclosure of Invention

The invention aims to provide caffeine equipment for decomposing defective coffee beans and old coffee beans through microbial aerobic fermentation, which can perform primary sedimentation screening, secondary vibration screening and itching fermentation of defective coffee beans and old coffee beans after three times of shelling treatment, and can inhibit the growth of harmful pathogenic fungi of the defective coffee beans and the old coffee beans by utilizing an acidic environment generated by Aciduo microbial propagation.

The purpose of the invention is realized by the following technical scheme:

the caffeine equipment for decomposing defective coffee beans and old coffee beans through microbial aerobic fermentation comprises a primary screening assembly, a secondary screening aerobic fermentation assembly and a tertiary screening assembly, and is characterized in that: the primary screening assembly is connected with the secondary screening aerobic fermentation assembly, and the secondary screening aerobic fermentation assembly is connected with the tertiary screening assembly.

As a further optimization of the technical scheme, the primary screening assembly comprises an upper settling chamber, a sieve plate chamber I, a sieve plate chamber II, a lower settling chamber, a motor shaft bracket, a belt wheel I, a belt wheel II, a direction change gear I, a direction change gear II shaft bracket, a lifting gear I, a belt wheel III, a belt II, a belt wheel IV shaft bracket, a lifting gear II, a connecting plate, a rack bracket, a rack bracket slide rail, a lifting connecting rod I, a lifting connecting rod II, a coffee bean outlet, a half sieve plate I, a half sieve plate II, a limiting slide bar, a limiting slide groove, a slide column, a spring I and a sieve plate limiting bracket, wherein the upper settling chamber is connected with the sieve plate chamber I and the sieve plate chamber II, the sieve plate chamber I and, the motor is connected with a sieve plate storeroom I, the motor is connected with a motor shaft, the motor shaft is rotatably connected with a motor shaft bracket, a motor shaft bracket is connected with the sieve plate storeroom I, the motor shaft is connected with a belt wheel I, the belt wheel I is connected with a belt wheel II through a belt I, the belt wheel II is connected with a shaft of the belt wheel II, the shaft of the belt wheel II is connected with a change gear I, the change gear I is meshed with the change gear II, the change gear II is connected with a shaft of the change gear II, the shaft of the change gear II is rotatably connected with a shaft bracket of the change gear II, the shaft bracket of the change gear II is connected with a lifting gear I, the shaft of the belt wheel II is connected with a belt wheel III, the belt wheel III is connected with a belt wheel IV through a belt II, the belt wheel IV is connected with a shaft of the belt wheel IV, the shaft of the belt wheel IV, the belt wheel IV shaft support is connected with a lifting gear II, a connecting plate is connected with two rack supports, the two rack supports are respectively connected with two racks, the lifting gear I, the lifting gear II is respectively connected with two racks in a meshed mode, the two rack supports are respectively connected with two rack support sliding rails in a sliding mode, the two rack support sliding rails are both connected with an upper settling chamber, the connecting plate is hinged with a lifting connecting rod I and a lifting connecting rod II, the lifting connecting rod I is hinged with a half sieve plate I, the lifting connecting rod II is hinged with the half sieve plate II, the half sieve plate I is connected with a sieve plate storage chamber II in a sliding mode, the half sieve plate II is connected with the sieve plate storage chamber I in a sliding mode, a coffee bean outlet is located on a lower settling chamber, a limiting sliding rod is connected with the half sieve plate I, a limiting sliding chute is located on the half sieve plate II, a sliding column is connected with the half sieve plate II, The sliding columns are in contact, the spring I is in a compressed state, and the sieve plate limiting support is connected with the sedimentation chamber.

As a further optimization of the technical scheme, the secondary screening aerobic fermentation assembly comprises an aerobic fermentation decomposition box support, an aerobic fermentation decomposition box, a servo motor support, a fixing support, a limiting disc, a servo motor shaft, fan blades, a discharge port, a discharge baffle plate, a discharge sieve plate, a discharge plate slide rail I, a spring II, a discharge plate and a discharge plate slide rail II, wherein the two aerobic fermentation decomposition box supports are respectively connected with a sieve plate storeroom I and a sieve plate storeroom II, the two aerobic fermentation decomposition box supports are respectively connected with the aerobic fermentation decomposition box support of the aerobic fermentation decomposition box, the servo motor is connected with the servo motor support, the servo motor support is connected with a sedimentation chamber, the fixing support is rotatably connected with the limiting disc, the servo motor is connected with the servo motor shaft, the servo motor shaft is connected with the limiting disc, The flabellum is connected, and the discharge gate is connected with the coffee bean export, and the discharge gate is connected with discharge baffle, and ejection of compact sieve is articulated mutually with the discharge gate, goes out flitch slide rail I and is connected with the discharge gate, and spring II cup joints on going out flitch slide rail I, and spring II is in compression state, and II both ends of spring contact with going out flitch, play flitch slide rail I respectively, go out flitch and go out flitch slide rail I, go out II sliding connection of flitch slide rail, go out flitch slide rail II and be connected with the.

As a further optimization of the technical scheme, the tertiary screening assembly comprises a double-head motor, a double-head motor support, a double-head motor shaft I, a belt wheel V, a belt III, a belt wheel VI, a cam, a shell support, a double-head motor shaft II, a friction wheel, a screening cylinder, a spiral heating sheet and a bearing, wherein the double-head motor is connected with the double-head motor support, the double-head motor support is connected with an aerobic fermentation decomposition box support of the aerobic fermentation decomposition box, the double-head motor is connected with the double-head motor shaft I and the double-head motor shaft II, the double-head motor shaft I is rotatably connected with the aerobic fermentation decomposition box, the double-head motor shaft I is connected with the belt wheel V, the belt wheel V is connected with the belt wheel VI through the belt III, the belt wheel VI is connected with the belt wheel VI, the belt wheel VI is rotatably connected with, the shell is connected with shell support, and double-end motor shaft II rotates with shell support to be connected, and shell 3 is connected with a screening section of thick bamboo through the bearing, and double-end motor shaft II is connected with the friction pulley, and the friction pulley contacts with a screening section of thick bamboo, and the spiral generates heat the piece and is connected with a screening section of thick bamboo.

The caffeine equipment for decomposing the defective coffee beans and the old coffee beans through microbial aerobic fermentation has the beneficial effects that: adding coffee beans doped with new and old defective products into a primary screening assembly, controlling fan blades to slowly rotate and soak for a period of time, enabling mildewed old beans and defective beans to float to the water surface, controlling two half sieve plates to rise to finish primary screening, controlling the fan blades to rotate at an accelerated speed, opening a discharge plate under the action of centrifugal force, screening the coffee beans by a vibrating discharge sieve plate, screening coffee beans with density smaller than that of water by secondary screening, enabling the coffee beans to fall onto a spiral heating piece, drying and colliding with each other to start peeling, discharging bean skins from a shell and a screening barrel, finishing separation, adding the screened old beans, mildewed beans and microbial substrates into an aerobic fermentation decomposition box, and starting microbial aerobic fermentation decomposition. After Acidulo microorganisms rapidly propagate and become dominant flora, the pH of the fermentation environment is rapidly reduced to form an acidic environment, so that the growth of harmful pathogenic fungi of inferior coffee beans and old coffee beans is inhibited, and the flavors of the inferior coffee beans and old coffee beans are improved.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

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

FIG. 2 is a first schematic structural view of the first screening assembly 1 of the present invention;

FIG. 3 is a second schematic structural view of the first screening assembly 1 of the present invention;

FIG. 4 is a schematic structural diagram III of the first screening assembly 1 of the present invention;

FIG. 5 is a fourth schematic structural view of the first screening assembly 1 of the present invention;

fig. 6 is a first structural sectional view of the first screening assembly 1 of the present invention;

fig. 7 is a structural sectional view ii of the primary screening assembly 1 of the present invention;

FIG. 8 is a schematic structural diagram I of the secondary screening aerobic fermentation assembly 2 of the present invention;

FIG. 9 is a schematic structural diagram of a secondary screening aerobic fermentation assembly 2 according to the present invention;

FIG. 10 is a sectional view of the secondary screening aerobic fermentation assembly 2 according to the present invention;

FIG. 11 is a schematic structural diagram III of the secondary screening aerobic fermentation assembly 2 of the present invention;

FIG. 12 is a fourth schematic structural diagram of the secondary screening aerobic fermentation assembly 2 according to the present invention;

FIG. 13 is a schematic structural view of a secondary screening assembly 3 of the present invention;

figure 14 is a cross-sectional view of the construction of the secondary screening assembly 3 of the present invention;

in the figure: screening the combination 1 for the first time; an upper settling chamber 1-1; a sieve plate storeroom I1-2; sieve plate storeroom II 1-3; 1-4 of a lower settling chamber; 1-5 of a motor; a motor shaft 1-6; motor shaft supports 1-7; 1-8 belt wheels; 1-9 parts of a belt; 1-10 belt wheels; 1-11 of a belt wheel II shaft; 1-12 of a change gear; direction changing gears II 1-13; 1-14 of a direction changing gear II shaft; 1-15 shaft supports of a direction-changing gear II; lifting gears I1-16; belt wheels III 1-17; belts II 1-18; pulley IV 1-19; 1-20 of belt wheel IV shaft; a pulley IV shaft support 1-21; lifting gears II 1-22; connecting plates 1-23; rack supports 1-24; racks 1-25; rack support slide rails 1-26; lifting connecting rods I1-27; lifting connecting rods II 1-28; coffee bean outlet 1-29; 1-30 parts of a half sieve plate I; 1-31 parts of a half sieve plate II; 1-32 of a limiting slide bar; 1-33 of a limiting chute; sliding columns 1-34; springs I1-35 and sieve plate limiting brackets 1-36; secondary screening of the aerobic fermentation assembly 2; 2-1 of an aerobic fermentation decomposition box bracket; 2-2 of an aerobic fermentation decomposition box; 2-3 of a servo motor; 2-4 of a servo motor bracket; 2-5 of a fixed support; 2-6 of a limiting disc; servo motor shaft 2-7; 2-8 of fan blades; 2-9 of a discharge port; 2-10 parts of a discharge baffle; 2-11 parts of a discharging sieve plate; a discharge plate slide rail I2-12; 2-13 parts of a spring; 2-14 parts of a discharge plate; a discharge plate slide rail II 2-15; thirdly, screening the combination 3; a double-head motor 3-1; a double-head motor bracket 3-2; a double-end motor shaft I3-3; a belt pulley V3-4; 3-5 of a belt III; a belt wheel VI 3-6; 3-7 of a belt wheel VI shaft; 3-8 parts of a cam; 3-9 parts of a shell; 3-10 parts of a shell bracket; a double-end motor shaft II 3-11; 3-12 parts of friction wheel; 3-13 parts of a screening cylinder; 3-14 parts of spiral heating sheets; and 3-15 parts of bearings.

Detailed Description

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

The fixed connection in the device is realized by welding; the fixing is carried out in a thread fixing mode, different fixing modes are used in combination with different use environments, the rotating connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the axial fixing of the bearing is realized by clamping the elastic retainer ring in the retainer ring groove, so that the rotation is realized; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the caffeine apparatus for decomposing inferior coffee beans and old coffee beans by microbial aerobic fermentation according to the present embodiment is described below with reference to fig. 1 to 14, and includes a primary screening assembly 1, a secondary screening aerobic fermentation assembly 2, and a tertiary screening assembly 3, and is characterized in that: the primary screening assembly 1 is connected with the secondary screening aerobic fermentation assembly 2, and the secondary screening aerobic fermentation assembly 2 is connected with the tertiary screening assembly 3.

The second embodiment is as follows:

the first screening assembly 1 comprises an upper settling chamber 1-1, a sieve plate storage chamber I1-2, a sieve plate storage chamber II 1-3, a lower settling chamber 1-4, a motor 1-5, a motor shaft 1-6, a motor shaft bracket 1-7, a belt wheel I1-8, a belt I1-9, a belt wheel II 1-10, a belt wheel II shaft 1-11, a change gear I1-12, a change gear II 1-13, a change gear II shaft 1-14, a change gear II shaft bracket 1-15, a lifting gear I1-16, a belt wheel III 1-17, a belt II 1-18, a belt wheel IV 1-19, a belt wheel IV shaft 1-20, a belt wheel IV shaft bracket 1-21, a change gear II shaft bracket 1-15, a lifting gear I1-16, a belt wheel III 1-17, a belt II 1-18, a belt wheel IV 1-19, a belt wheel IV, 1-22 parts of lifting gears, 1-23 parts of connecting plates, 1-24 parts of rack supports, 1-25 parts of racks, 1-26 parts of rack support slide rails, 1-27 parts of lifting connecting rods, 1-28 parts of lifting connecting rods, 1-29 parts of coffee bean outlets, 1-30 parts of half sieve plates, 1-31 parts of half sieve plates, 1-32 parts of limiting slide rods, 1-33 parts of limiting slide chutes, 1-34 parts of slide columns, 1-35 parts of springs and 1-36 parts of sieve plate limiting supports, wherein an upper settling chamber 1-1 is connected with a sieve plate storeroom I1-2 and a sieve plate storeroom II 1-3, a sieve plate storeroom I1-2 and a sieve plate storeroom II 1-3 are connected with a lower settling chamber 1-4, a motor 1-5 is connected with the sieve plate storeroom I1-2, and a motor 1-5 is connected with a motor shaft, the motor shaft 1-6 is rotationally connected with the motor shaft support 1-7, the motor shaft support 1-7 is connected with the sieve plate storeroom I1-2, the motor shaft 1-6 is connected with the belt wheel I1-8, the belt wheel I1-8 is connected with the belt wheel II 1-10 through the belt I1-9, the belt wheel II 1-10 is connected with the belt wheel II shaft 1-11, the belt wheel II shaft 1-11 is connected with the change gear I1-12, the change gear I1-12 is meshed with the change gear II 1-13, the change gear II 1-13 is connected with the change gear II shaft 1-14, the change gear II shaft 1-14 is rotationally connected with the change gear II shaft support 1-15, the change gear II shaft support 1-15 is connected with the sieve plate storeroom I1-2, the direction changing gear II shaft support 1-15 is connected with the lifting gear I1-16, the belt wheel II shaft 1-11 is connected with the belt wheel III 1-17, the belt wheel III 1-17 is connected with the belt wheel IV 1-19 through the belt II 1-18, the belt wheel IV 1-19 is connected with the belt wheel IV shaft 1-20, the belt wheel IV shaft 1-20 is rotationally connected with the belt wheel IV shaft support 1-21, the belt wheel IV shaft support 1-21 is connected with the sieve plate storeroom II 1-3, the belt wheel IV shaft support 1-21 is connected with the lifting gear II 1-22, the connecting plate 1-23 is connected with the two rack supports 1-24, the two rack supports 1-24 are respectively connected with the two racks 1-25, the lifting gear I1-16 and the lifting gear II 1-22 are respectively engaged with the two racks 1-25, two rack supports 1-24 are respectively connected with two rack support sliding rails 1-26 in a sliding manner, the two rack support sliding rails 1-26 are connected with an upper settling chamber 1-1, a connecting plate 1-23 is hinged with a lifting connecting rod I1-27 and a lifting connecting rod II 1-28, the lifting connecting rod I1-27 is hinged with a half sieve plate I1-30, the lifting connecting rod II 1-28 is hinged with a half sieve plate II 1-31, the half sieve plate I1-30 is connected with a sieve plate storeroom II 1-3 in a sliding manner, the half sieve plate II 1-31 is connected with a sieve plate storeroom I1-2 in a sliding manner, a coffee bean outlet 1-29 is positioned on a lower settling chamber 1-4, a limiting sliding rod 1-32 is connected with the half sieve plate I1-30, and a limiting sliding chute 1-33 is positioned on the half sieve plate II 1-31, the sliding columns 1-34 are connected with the half sieve plates II 1-31 in a sliding mode, the springs I1-35 are located in the half sieve plates II 1-31, two ends of the springs I1-35 are respectively in contact with the half sieve plates II 1-31 and the sliding columns 1-34, the springs I1-35 are in a compressed state, and the sieve plate limiting supports 1-36 are connected with the lower settling chambers 1-4.

The third concrete implementation mode:

the second screening aerobic fermentation assembly 2 comprises an aerobic fermentation decomposition box support 2-1, an aerobic fermentation decomposition box 2-2, a servo motor 2-3, a servo motor support 2-4, a fixed support 2-5, a limiting disc 2-6, a servo motor shaft 2-7, a fan blade 2-8, a discharge port 2-9, a discharge baffle 2-10, a discharge sieve plate 2-11, a discharge plate slide rail I2-12, a spring II 2-13, a discharge plate 2-14 and a discharge plate slide rail II 2-15, wherein two aerobic fermentation decomposition box supports 2-1 are respectively connected with a sieve plate storage chamber I1-2 and a sieve plate storage chamber II 1-3, and two aerobic fermentation decomposition box supports 2-1 are respectively connected with the aerobic fermentation decomposition box support 2-1 The frame 2-1 is connected, the servo motor 2-3 is connected with a servo motor bracket 2-4, the servo motor bracket 2-4 is connected with the lower settling chamber 1-4, the fixed bracket 2-5 is rotationally connected with a limiting disc 2-6, the servo motor 2-3 is connected with a servo motor shaft 2-7, the servo motor shaft 2-7 is connected with the limiting disc 2-6 and a fan blade 2-8, the discharge port 2-9 is connected with a coffee bean outlet 1-29, the discharge port 2-9 is connected with a discharge baffle 2-10, a discharge sieve plate 2-11 is hinged with the discharge port 2-9, a discharge plate slide rail I2-12 is connected with the discharge port 2-9, and a spring II 2-13 is sleeved on the discharge plate slide rail I2-12, the springs II 2-13 are in a compressed state, two ends of the springs II 2-13 are respectively in contact with the discharge plates 2-14 and the discharge plate slide rails I2-12, the discharge plates 2-14 are in sliding connection with the discharge plate slide rails I2-12 and the discharge plate slide rails II 2-15, and the discharge plate slide rails II 2-15 are connected with the discharge holes 2-9.

The fourth concrete implementation mode:

the third screening assembly 3 comprises a double-head motor 3-1, a double-head motor bracket 3-2, a double-head motor shaft I3-3, a belt pulley V3-4, a belt III 3-5, a belt pulley VI 3-6, a belt pulley VI 3-7, a cam 3-8, a shell 3-9, a shell bracket 3-10, a double-head motor shaft II 3-11, a friction wheel 3-12, a screening cylinder 3-13, a spiral heating sheet 3-14 and a bearing 3-15, wherein the double-head motor 3-1 is connected with the double-head motor bracket 3-2, the double-head motor bracket 3-2 is connected with the aerobic fermentation decomposition box bracket 2-1, the double-head motor 3-1 is connected with the double-head motor shaft I3-3, the double-head motor 3-3, The double-head motor shaft II 3-11 is connected, the double-head motor shaft I3-3 is rotationally connected with the aerobic fermentation decomposition box 2-2, the double-head motor shaft I3-3 is connected with the belt wheel V3-4, the belt wheel V3-4 is connected with the belt wheel VI 3-6 through the belt III 3-5, the belt wheel VI 3-6 is connected with the belt wheel VI shaft 3-7, the belt wheel VI shaft 3-7 is rotationally connected with the aerobic fermentation decomposition box 2-2, the belt wheel VI shaft 3-7 is connected with the cam 3-8, the cam 3-8 is contacted with the discharging sieve plate 2-11, the shell 3-9 is connected with the shell bracket 3-10, the double-head motor shaft II 3-11 is rotationally connected with the shell bracket 3-10, the shell-93 is connected with the sieving barrel 3-13 through the bearing 3-15, the double-head motor shaft II 3-11 is connected with the friction wheel 3-12, the friction wheel 3-12 is in contact with the screening cylinder 3-13, and the spiral heating piece 3-14 is connected with the screening cylinder 3-13.

The invention relates to a caffeine device for decomposing defective coffee beans and old coffee beans by microbial aerobic fermentation, which has the working principle that: adding coffee beans and water mixed with new and old defective products into an upper settling chamber 1-1, enabling the coffee beans and the water to fall into a lower settling chamber 1-4, starting a servo motor 2-3 and regulating slow rotation, enabling the servo motor 2-3 to drive a servo motor shaft 2-7 to rotate, enabling a servo motor shaft 2-7 to drive a limiting disc 2-6 to rotate in a fixed support 2-5 and axially limiting the servo motor shaft 2-7, enabling a servo motor shaft 2-7 to drive a fan blade 2-8 to rotate, enabling the fan blade 2-8 to rotate slowly and stirring the coffee beans and the water in the settling chamber 1-4 to enable defective beans and mildews with lower density at the bottom to float to the water surface, enabling the fan blade 2-8 to stir aquatic products to generate centrifugal force to generate pressure on the inner wall of the lower settling chamber 1-4, and enabling water to flow to pass through a coffee bean outlet 1-29 and a water outlet under the pressure, The discharge plate 2-14 is pushed to slide along the discharge plate slide rail I2-12 and the discharge plate slide rail II 2-15, the spring II 2-13 is compressed, the pressure at the moment is not enough to further compress the spring II 2-13, the discharge plate 2-14 can not completely slide out of the discharge port 2-9 to continuously block coffee beans and water from flowing out, when defective beans and mildewed beans with lower density float on the water surface, the motor 1-5 is started, the motor 1-5 drives the motor shaft 1-6 to rotate, the motor shaft 1-6 drives the belt wheel I1-8 to rotate, the belt wheel I1-8 drives the belt wheel II 1-10 to rotate through the belt I1-9, the belt wheel II 1-10 drives the belt wheel II shaft 1-11 to rotate, the belt wheel II shaft 1-11 drives the change gear I1-12 to rotate, the change gear I1-12 drives the change gear II 1-13 to rotate oppositely, the direction changing gear II 1-13 drives the direction changing gear II shaft 1-14 to rotate, the direction changing gear II shaft 1-14 drives the lifting gear I1-16 to rotate, the belt wheel II shaft 1-11 drives the belt wheel III 1-17 to rotate, the belt wheel III 1-17 drives the belt wheel IV 1-19 to rotate through the belt II 1-18, the belt wheel IV 1-19 drives the belt wheel IV shaft 1-20 to rotate, the belt wheel IV shaft 1-20 drives the lifting gear II 1-22 to rotate, the lifting gear I1-16 and the lifting gear II 1-22 rotate oppositely to drive the two racks 1-25 to move upwards simultaneously, the two racks 1-25 drive the two rack supports 1-24 to slide upwards in the two rack support slide rails 1-26, the two rack supports 1-24 drive the connecting plate 1-23 to move upwards, the connecting plate 1-23 drives the hinged lifting connecting rod I1-27 and the lifting connecting rod II 1-28 to move upwards, the lifting connecting rod I1-27 and the lifting connecting rod II 1-28 drive the half sieve plate I1-30 and the half sieve plate II 1-31 to slide out of the sieve plate storeroom II 1-3 and the sieve plate storeroom I1-2, when the limiting slide bar 1-32 is completely butted with the limiting slide groove 1-33, the half sieve plate I1-30 and the half sieve plate II 1-31 completely slide out of the sieve plate storeroom II 1-3 and the sieve plate storeroom I1-2, the half sieve plate I1-30 and the half sieve plate II 1-31 are spliced into a sieve plate and continuously ascend along the upper settling chamber 1-1 to collect and lift defective beans and mildew beans which float to the lower density of the water surface to the top of the upper settling chamber 1-1, and then the defective beans and the mildew beans can be cleaned, placing defective beans and mildewed beans into an aerobic fermentation decomposition box 2-2, reversing a motor 1-5, repeating the transmission process, enabling a half sieve plate I1-30 and a half sieve plate II 1-31 to descend along an upper settling chamber 1-1, enabling a sliding column 1-34 to pop out to drive the half sieve plate I1-30 and the half sieve plate II 1-31 to be separated and respectively slide into a sieve plate storage chamber II 1-3 and a sieve plate storage chamber I1-2 under the action of a spring I1-35 when the half sieve plate I1-30 and the half sieve plate II 1-31 are in contact with a sieve plate limiting support 1-36, completing sieve plate resetting, adjusting the height of a servo motor 2-3 to rotate after the first screening is completed, enabling fan blades 2-8 to rotate at a high speed, and pushing a discharge plate 2-14 to push a discharge plate along a discharge plate slide rail I2-12, The discharge plate slide rails II 2-15 slide, the springs II 2-13 compress, the pressure at the moment is enough to further compress the springs II 2-13, the discharge plates 2-14 completely slide out of the discharge ports 2-9, coffee beans flow out of the discharge ports 2-9 to contact with the discharge baffle 2-10 and fall onto the discharge sieve plates 2-11, the double-head motor 3-1 is started, the double-head motor 3-1 drives the double-head motor shaft I3-3 and the double-head motor shaft II 3-11 to rotate, the double-head motor shaft I3-3 drives the belt pulley V3-4 to rotate, the belt pulley V3-4 drives the belt pulley VI 3-6 to rotate through the belt III 3-5, the belt pulley VI 3-6 drives the belt pulley VI shaft 3-7 to rotate, the belt pulley VI shaft 3-7 drives the cams 3-8 to rotate, the cams 3-8 drive the discharge sieve plates 2-11, the discharging sieve plate 2-11 vibrates reciprocally to drive defective beans with larger density and smaller volume and water in the coffee beans to fall into the aerobic fermentation decomposition box 2-2 through sieve holes, the coffee beans screened twice fall into the screening cylinder 3-13 through the discharging sieve plate 2-11, the double-head motor shaft II 3-11 drives the friction wheel 3-12 to rotate, the friction wheel 3-12 drives the screening cylinder 3-13 to rotate, the friction wheel 3-12 is axially limited and rotated by the bearing 3-15 in the shell 3-9, the coffee beans are aerobically fermented in the screening cylinder 3-13 to move along the track of the spiral heating sheet 3-14, the spiral heating sheet 3-14 dries the coffee beans, the dried coffee bean skins are very easy to fall off, the coffee bean skins collide with each other, fall off and are discharged to the shell 3-9 through the sieve holes of the screening cylinder 3-13, at this time, bean skin can be collected at the bottom of the shell, the dried coffee beans are collected at the bottom of the screening cylinder 3-13, and the screened old beans, mildewed beans and microbial matrix are all added into the aerobic fermentation decomposition box 2-2, at this time, aerobic fermentation decomposition can be started.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (4)

1. The caffeine equipment for decomposing defective coffee beans and old coffee beans through microbial aerobic fermentation comprises a primary screening assembly (1), a secondary screening aerobic fermentation assembly (2) and a tertiary screening assembly (3), and is characterized in that: the primary screening assembly (1) is connected with the secondary screening aerobic fermentation assembly (2), and the secondary screening aerobic fermentation assembly (2) is connected with the tertiary screening assembly (3).

2. The apparatus for decomposing inferior coffee beans and aged coffee beans by microbial aerobic fermentation according to claim 1, characterized in that: the primary screening assembly (1) comprises an upper settling chamber (1-1), a sieve plate storeroom I (1-2), a sieve plate storeroom II (1-3), a lower settling chamber (1-4), a motor (1-5), a motor shaft (1-6), a motor shaft support (1-7), a belt wheel I (1-8), a belt I (1-9), a belt wheel II (1-10), a belt wheel II shaft (1-11), a change gear I (1-12), a change gear II (1-13), a change gear II shaft (1-14), a change gear II shaft support (1-15), a lifting gear I (1-16), a belt wheel III (1-17), a belt II (1-18), a belt wheel IV (1-19), a belt wheel IV shaft (1-20), A shaft support (1-21) of a pulley IV shaft, a lifting gear II (1-22), a connecting plate (1-23), a rack support (1-24), a rack (1-25), a rack support slide rail (1-26), a lifting connecting rod I (1-27), a lifting connecting rod II (1-28), a coffee bean outlet (1-29), a half sieve plate I (1-30), a half sieve plate II (1-31), a limit slide rod (1-32), a limit slide groove (1-33), a slide column (1-34), a spring I (1-35) and a sieve plate limit support (1-36), wherein an upper settling chamber (1-1) is connected with a sieve plate collection chamber I (1-2) and a sieve plate collection chamber II (1-3), the sieve plate collection chamber I (1-2) and the sieve plate collection chamber II (1-3) are connected with a lower settling chamber (1-4), the motor (1-5) is connected with the sieve plate storeroom I (1-2), the motor (1-5) is connected with the motor shaft (1-6), the motor shaft (1-6) is rotationally connected with the motor shaft support (1-7), the motor shaft support (1-7) is connected with the sieve plate storeroom I (1-2), the motor shaft (1-6) is connected with the belt wheel I (1-8), the belt wheel I (1-8) is connected with the belt wheel II (1-10) through a belt I (1-9), the belt wheel II (1-10) is connected with the belt wheel II shaft (1-11), the belt wheel II shaft (1-11) is connected with the change gear I (1-12), the change gear I (1-12) is meshed with the change gear II (1-13), the change gear II (1-13) is connected with the change gear II shaft (1-14), the second shaft (1-14) of the direction-changing gear is rotationally connected with the second shaft bracket (1-15) of the direction-changing gear, the second shaft bracket (1-15) of the direction-changing gear is connected with the first sieve plate storeroom (1-2), the second shaft bracket (1-15) of the direction-changing gear is connected with the first lifting gear (1-16), the second shaft (1-11) of the belt wheel is connected with the third belt wheel (1-17), the third belt wheel (1-17) is connected with the fourth belt wheel (1-19) through the second belt (1-18), the fourth belt wheel (1-19) is connected with the fourth belt wheel (1-20), the fourth belt wheel (1-20) is rotationally connected with the fourth belt wheel (1-21), the fourth belt wheel (1-21) is connected with the second sieve plate storeroom (1-3), the fourth belt wheel (1-21) is connected with the second lifting gear (1-22), the connecting plate (1-23) is connected with two rack supports (1-24), the two rack supports (1-24) are respectively connected with two racks (1-25), the lifting gear I (1-16) and the lifting gear II (1-22) are respectively meshed with the two racks (1-25), the two rack supports (1-24) are respectively connected with two rack support sliding rails (1-26) in a sliding manner, the two rack support sliding rails (1-26) are both connected with the upper settling chamber (1-1), the connecting plate (1-23) is hinged with a lifting connecting rod I (1-27) and a lifting connecting rod II (1-28), the lifting connecting rod I (1-27) is hinged with a half sieve plate I (1-30), and the lifting connecting rod II (1-28) is hinged with a half sieve plate II (1-31), the half sieve plate I (1-30) is connected with the sieve plate storeroom II (1-3) in a sliding mode, the half sieve plate II (1-31) is connected with the sieve plate storeroom I (1-2) in a sliding mode, the coffee bean outlet (1-29) is located on the lower settling chamber (1-4), the limiting slide rod (1-32) is connected with the half sieve plate I (1-30), the limiting slide groove (1-33) is located on the half sieve plate II (1-31), the slide column (1-34) is connected with the half sieve plate II (1-31) in a sliding mode, the spring I (1-35) is located in the half sieve plate II (1-31), two ends of the spring I (1-35) are respectively connected with the half sieve plate II (1-31), the sliding columns (1-34) are contacted, the springs I (1-35) are in a compressed state, and the sieve plate limiting supports (1-36) are connected with the lower sedimentation chamber (1-4).

3. The apparatus for decomposing inferior coffee beans and aged coffee beans by microbial aerobic fermentation according to claim 1, characterized in that: the secondary screening aerobic fermentation assembly (2) comprises an aerobic fermentation decomposition box support (2-1), an aerobic fermentation decomposition box (2-2), a servo motor (2-3), a servo motor support (2-4), a fixing support (2-5), a limiting disc (2-6), a servo motor shaft (2-7), fan blades (2-8), a discharge port (2-9), a discharge baffle plate (2-10), a discharge sieve plate (2-11), a discharge plate slide rail I (2-12), a spring II (2-13), a discharge plate (2-14) and a discharge plate slide rail II (2-15), wherein the two aerobic fermentation decomposition box supports (2-1) are respectively connected with a sieve plate storeroom I (1-2) and a sieve plate storeroom II (1-3), two aerobic fermentation decomposition box supports (2-1) are connected with the aerobic fermentation decomposition box support (2-1), a servo motor (2-3) is connected with a servo motor support (2-4), the servo motor support (2-4) is connected with a lower sedimentation chamber (1-4), a fixed support (2-5) is connected with the lower sedimentation chamber (1-4), the fixed support (2-5) is rotationally connected with a limiting disc (2-6), the servo motor (2-3) is connected with a servo motor shaft (2-7), the servo motor shaft (2-7) is connected with the limiting disc (2-6) and a fan blade (2-8), a discharge port (2-9) is connected with a coffee bean outlet (1-29), the discharge port (2-9) is connected with a discharge baffle (2-10), the discharging sieve plate (2-11) is hinged with the discharging port (2-9), the discharging plate sliding rail I (2-12) is connected with the discharging port (2-9), the spring II (2-13) is sleeved on the discharging plate sliding rail I (2-12), the spring II (2-13) is in a compression state, two ends of the spring II (2-13) are respectively contacted with the discharging plate (2-14) and the discharging plate sliding rail I (2-12), the discharging plate (2-14) is in sliding connection with the discharging plate sliding rail I (2-12) and the discharging plate sliding rail II (2-15), and the discharging plate sliding rail II (2-15) is connected with the discharging port (2-9).

4. The apparatus for decomposing inferior coffee beans and aged coffee beans by microbial aerobic fermentation according to claim 1, characterized in that: the three-time screening assembly (3) comprises a double-end motor (3-1), a double-end motor support (3-2), a double-end motor shaft I (3-3), a belt wheel V (3-4), a belt III (3-5), a belt wheel VI (3-6), a belt wheel VI shaft (3-7), a cam (3-8), a shell (3-9), a shell support (3-10), a double-end motor shaft II (3-11), a friction wheel (3-12), a screening cylinder (3-13), a spiral heating sheet (3-14) and a bearing (3-15), the double-end motor (3-1) is connected with the double-end motor support (3-2), the double-end motor support (3-2) is connected with the aerobic fermentation decomposition box support (2-1), the double-head motor (3-1) is connected with a double-head motor shaft I (3-3) and a double-head motor shaft II (3-11), the double-head motor shaft I (3-3) is rotationally connected with the aerobic fermentation decomposition box (2-2), the double-head motor shaft I (3-3) is connected with a belt wheel V (3-4), the belt wheel V (3-4) is connected with a belt wheel VI (3-6) through a belt III (3-5), the belt wheel VI (3-6) is connected with a belt wheel VI shaft (3-7), the belt wheel VI shaft (3-7) is rotationally connected with the aerobic fermentation decomposition box (2-2), the belt wheel VI shaft (3-7) is connected with a cam (3-8), the cam (3-8) is contacted with the discharging sieve plate (2-11), the shell (3-9) is connected with a shell bracket (3-10), the double-head motor shaft II (3-11) is rotationally connected with the shell support (3-10), the shell (-9)3 is connected with the screening cylinder (3-13) through a bearing (3-15), the double-head motor shaft II (3-11) is connected with the friction wheel (3-12), the friction wheel (3-12) is in contact with the screening cylinder (3-13), and the spiral heating piece (3-14) is connected with the screening cylinder (3-13).

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