CN112122236A - A hierarchical formula cleaning system for food flavouring raw materials - Google Patents

Abstract

The invention discloses a hierarchical cleaning system for food seasoning raw materials, which relates to the technical field of food seasoning production, wherein a bearing and collecting unit with matched size is fixedly arranged at the top end of a bearing frame of equipment, a raw material sorting unit is fixedly arranged at the rear side inside the bearing and collecting unit, a hierarchical raw material cleaning unit is fixedly arranged at the front side inside the bearing and collecting unit, a water circulation unit is fixedly arranged inside the bearing frame of the equipment and at the position corresponding to the hierarchical raw material cleaning unit, the system adds the same seasoning into the raw material sorting unit by utilizing the path of different particle sizes, the raw materials with different particle sizes enter corresponding collecting structures and then fall into the cleaning units with corresponding levels, the raw materials with different levels are independently cleaned, the cleaning effect can be improved, the cleaned sewage falls into a collecting box and is correspondingly treated, the recycling is realized, the water resource is saved, and the production cost is reduced.

Description

A hierarchical formula cleaning system for food flavouring raw materials

Technical Field

The invention relates to the technical field of food seasoning production, in particular to a hierarchical cleaning system for food seasoning raw materials.

Background

In daily life, a food seasoning is one of the essential components for making a delicious food, and the food seasoning includes solid salt, chicken essence and the like in addition to liquid seasonings such as soy sauce, vinegar, cooking wine and the like, and the solid seasoning also includes round or nearly round seasoning materials such as tsaoko cardamom, garlic, onion and the like.

In the prior art, for the production of the round or approximately round seasoning, the same seasoning raw material is generally sorted before the sorted seasoning raw materials of different grades are cleaned.

However, in the prior art, the above processes are usually completed manually, and when sorting and cleaning are performed manually, not only efficiency is low, progress is slow, but also a large amount of manual work is required for a large amount of seasoning raw materials, so that production cost of food seasoning is greatly increased.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a hierarchical cleaning system for food seasoning raw materials, which solves the problem of how to replace manual sorting and cleaning of seasoning raw materials by using a mechanical structure or mode.

In order to achieve the purpose, the invention is realized by the following technical scheme: a hierarchical cleaning system for food seasoning raw materials comprises an equipment bearing frame, wherein a bearing and collecting unit with matched size is fixedly installed at the top end of the equipment bearing frame, a raw material sorting unit is fixedly installed at the rear side in the bearing and collecting unit, a hierarchical raw material cleaning unit is fixedly installed at the front side in the bearing and collecting unit, and a water circulating unit is fixedly installed in the equipment bearing frame and corresponds to the hierarchical raw material cleaning unit;

the raw material sorting unit comprises a bearing support fixedly arranged above a bearing collection unit, a small particle screening cylinder, a medium particle screening cylinder and a large particle screening cylinder are respectively and rotatably connected above the bearing support, the small particle screening cylinder, the medium particle screening cylinder and the large particle screening cylinder are connected in series through cylinder sleeves, the small particle screening cylinder, the medium particle screening cylinder and the large particle screening cylinder are integrally in an inclined state, a blocking hopper is fixedly arranged at the corresponding lowest end of the large particle screening cylinder, a plurality of first blanking holes, second blanking holes and third blanking holes are respectively and correspondingly arranged in the small particle screening cylinder, the medium particle screening cylinder and the large particle screening cylinder, the first blanking holes, the second blanking holes and the third blanking holes are sequentially increased in aperture and sequentially reduced in distribution density, and a large belt disc is fixedly arranged at the corresponding highest end of the small particle screening cylinder, a raw material adding port communicated with the inside of the small particle screening cylinder is formed in the large belt pulley, a three-phase asynchronous alternating current motor is fixedly installed in the bearing support, and a small belt pulley is fixedly installed at the driving end of the three-phase asynchronous alternating current motor;

the classified raw material cleaning unit comprises a small particle cleaning mechanism, a medium particle cleaning mechanism and a large particle cleaning mechanism which are fixedly arranged above the bearing and collecting unit, the driven ends of the small particle cleaning mechanism, the medium particle cleaning mechanism and the large particle cleaning mechanism extend to the lower part of the bearing and collecting unit, and are fixedly provided with a driven belt wheel, the bottom end of the bearing and collecting unit is fixedly provided with a driving motor, and the driving end of the driving motor is fixedly provided with a driving belt wheel;

the small particle cleaning mechanism, the medium particle cleaning mechanism and the large particle cleaning mechanism are three components with the same structure;

the small particle cleaning mechanism, the medium particle cleaning mechanism and the large particle cleaning mechanism respectively comprise a bearing seat fixedly installed at the bottom end inside the bearing and collecting unit in a penetrating mode, a transmission shaft rod is rotatably connected inside the bearing seat, the top end of the transmission shaft rod extends to the inside of a section of solid-liquid separation bucket and is fixedly connected with the section of solid-liquid separation bucket, and an anti-overflow cover is fixedly connected above the section of solid-liquid separation bucket;

small granule wiper mechanism, well granule wiper mechanism and large granule wiper mechanism still all include fixed mounting at the braced frame who bears the inside bottom of collection unit braced frame's top through type fixed mounting has a transparent material's washing protective tube the inside of wasing the protective tube is provided with a transport auger, the bottom of carrying auger and washing protective tube all extends to the inside that prevents overflowing the cover, and carries the bottom of auger and pass through shaft coupling fixed connection together with the top of transmission axostylus axostyle.

Preferably, bear the weight of the collecting unit and include a fixed mounting at the equipment and bear the weight of the base plate of frame top and size looks adaptation bear the weight of the fixed welding in edge on base plate top and have a hurdle fixed welding in the middle of the inside of the overall structure that base plate and hurdle formed has a baffle, the baffle will overall structure is separated into two cavities of bearing cavity and waste water collection cavity bearing the weight of the inside of base plate and corresponding waste water collection cavity's part offer the hole of falling into water that a plurality of equidistance distributes.

Preferably, a plurality of reinforcing plates with inclination angles parallel to the small particle screening cylinder, the medium particle screening cylinder and the large particle screening cylinder are fixedly arranged in the bearing support.

Preferably, a rotary bearing structure is formed between the bearing support and an integral structure formed by the small particle screening cylinder, the medium particle screening cylinder and the large particle screening cylinder through a plurality of cylinder sleeves and a plurality of groups of carrier rollers, and each group of carrier rollers corresponds to one cylinder sleeve.

Preferably, a transmission belt is sleeved outside the small belt pulley and the large belt pulley together, and the transmission ratio of the small belt pulley to the large belt pulley is 5: 1.

Preferably, a small particle collecting mechanism, a medium particle collecting mechanism and a large particle collecting mechanism are respectively and fixedly arranged at the top of the bearing bracket and below the small particle screening cylinder, the medium particle screening cylinder and the large particle screening cylinder.

Preferably, the small particle collecting mechanism, the medium particle collecting mechanism and the large particle collecting mechanism are three members with the same structure.

Preferably, the small particle collecting mechanism, the medium particle collecting mechanism and the large particle collecting mechanism all comprise a supporting plate fixedly mounted at the top of the bearing support, a collecting tank with a semi-cylindrical structure is fixedly welded at the top end of the supporting plate, two ends of the collecting tank form a blocking structure through a blocking plate with an arc-shaped top, and a discharging groove is communicated with the lowest point inside the collecting tank.

Preferably, the transmission ratio of each driven pulley and each driving pulley is 1:1, and transmission connection structures are formed between each driven pulley and the driving motor through synchronous belts.

Preferably, the gap of the side wall of the first-section solid-liquid separation bucket is movably connected with a second-section solid-liquid separation bucket in a matched manner through a plurality of buckles in a clamping manner, and a plurality of drain holes distributed at equal intervals are formed in the side walls of the bottoms of the second-section solid-liquid separation bucket and the first-section solid-liquid separation bucket;

the top end of the cleaning protective pipe is fixedly connected with a receiving hopper, and a plurality of vertically distributed spray nozzle mounting holes are formed in the side wall of the cleaning protective pipe.

Preferably, the water circulation unit comprises a water storage tank fixedly installed inside the equipment bearing frame and provided with an open structure at the top, the water storage tank is located under the wastewater collection chamber, a plurality of groups of sliding grooves are symmetrically installed on two side walls inside the water storage tank, and a filter plate is connected between the two sliding grooves on the same horizontal plane in a sliding mode.

Preferably, a plurality of filter plates are vertically distributed in the water storage tank, and the filter apertures of the plurality of filter plates are sequentially reduced according to the sequence from top to bottom.

Preferably, the water circulation unit further comprises a water pump fixedly installed at the bottom end inside the equipment bearing frame, water inlets of the water storage tank and the water pump are connected in series, a water outlet of the water pump is fixedly connected with a water purification conveying pipe in series, three water outlets of the water purification conveying pipe are provided with three water outlets, the three water outlets are respectively and correspondingly provided with a plurality of spray heads, and the plurality of spray heads correspondingly extend to the inside of the cleaning protection pipe.

Advantageous effects

The invention provides a staged cleaning system for food seasoning raw materials. Compared with the prior art, the method has the following beneficial effects:

1. a hierarchical cleaning system for food seasoning raw materials is characterized in that a bearing and collecting unit with matched size is fixedly arranged at the top end of a bearing frame of equipment, a raw material sorting unit is fixedly arranged at the rear side inside the bearing and collecting unit, a graded raw material cleaning unit is fixedly arranged at the front side inside the bearing and collecting unit, and a water circulating unit is fixedly arranged inside the bearing frame of the equipment and corresponding to the graded raw material cleaning unit, in the structure, when the hierarchical cleaning system is in practical use, firstly, the same seasoning is added into the raw material sorting unit by utilizing the paths with different particle sizes, the raw materials with different particle sizes enter the corresponding collecting structures and then fall into the cleaning units with corresponding levels, the raw materials with different levels are independently cleaned, the cleaning effect can be improved, the cleaned raw materials are correspondingly collected, and the cleaned sewage falls into a collecting box, and after corresponding treatment, the water is conveyed to each cleaning unit again, so that the water is recycled, the water resource is saved, and the production cost is reduced.

2. A hierarchical cleaning system for food seasoning raw materials, a small particle cleaning mechanism, a medium particle cleaning mechanism and a large particle cleaning mechanism which are arranged above a bearing and collecting unit, wherein the driven ends of the small particle cleaning mechanism, the medium particle cleaning mechanism and the large particle cleaning mechanism extend to the lower part of the bearing and collecting unit, and are fixedly provided with a driven belt wheel, the bottom end of the bearing and collecting unit is fixedly provided with a driving motor, and the driving end of the driving motor is fixedly provided with a driving belt wheel, the structure is characterized in that the small particle cleaning mechanism, the medium particle cleaning mechanism and the large particle cleaning mechanism are driven by one driving motor and have the same transmission ratio when in actual use, each cleaning mechanism can be synchronized when cleaning, the cleaning efficiency is accelerated, and the upper half part of each cleaning mechanism is fixed when rotating, the latter half is rotatory along with motor transmission power, and the latter half is the separation part of raw materials and washing water again, and the centrifugation can let the speed of raw materials and liquid water separation increase, has improved efficiency.

3. The utility model provides a hierarchical formula cleaning system for food flavouring raw materials, the water purification directly injects into transparent material's washing protective tube through pipeline and shower nozzle directly to the cooperation washs the transport auger that sets up in the protective tube, and the cavity that every auger flabellum was located all corresponds a shower nozzle, and the raw materials follows the in-process that the auger moved down, can be handled by the washing through a lot of, thereby has improved the cleaning performance.

Drawings

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

FIG. 2 is a front view of the present invention;

FIG. 3 is a right side view of the present invention;

FIG. 4 is a top view of the present invention;

FIG. 5 is a schematic structural diagram of a carrying and collecting unit according to the present invention;

FIG. 6 is a schematic view of the material sorting unit of the present invention in a first viewing angle;

FIG. 7 is a schematic view of the material sorting unit of the present invention in a second viewing angle;

FIG. 8 is a schematic structural view of the large, medium and small particle collecting mechanism of the present invention;

FIG. 9 is a schematic diagram of the configuration of the classified raw material cleaning unit according to the present invention;

FIG. 10 is an exploded view of the large, medium and small particle cleaning mechanism of the present invention;

FIG. 11 is a schematic view of the assembly structure of the large, medium and small particle cleaning mechanism of the present invention;

FIG. 12 is a top view of the large, medium and small particle cleaning mechanism of the present invention;

FIG. 13 is a cross-sectional view taken along section A-A of FIG. 12 in accordance with the present invention;

FIG. 14 is a schematic view of the structure of the water circulation unit of the present invention.

In the figure: 1. an equipment carrying frame; 2. a load bearing and collecting unit; 21. a carrier substrate; 22. a hurdle frame; 23. a partition plate; 24. a load-bearing chamber; 25. a wastewater collection chamber; 26. a water falling hole; 3. a raw material sorting unit; 31. a load bearing support; 32. a reinforcing plate; 33. a small particle collection mechanism; 34. a medium particle collecting mechanism; 35. a large particle collection mechanism; 351. a support plate; 352. collecting tank; 353. a plugging plate; 354. a discharging groove; 36. a carrier roller; 37. a small particle screening cylinder; 38. a medium particle screening cylinder; 39. a large particle screening cartridge; 310. blocking the hopper; 311. a barrel sleeve; 312. a first blanking hole; 313. a second blanking hole; 314. a third blanking hole; 315. a large belt pulley; 316. a raw material addition port; 317. a three-phase asynchronous ac motor; 318. a small belt pulley; 319. a drive belt; 4. a classified raw material cleaning unit; 41. a small particle cleaning mechanism; 411. a bearing seat; 412. a drive shaft; 413. a first section of solid-liquid separation bucket; 414. a second section solid-liquid separation hopper; 415. buckling; 416. a drain hole; 417. an anti-overflow cover; 418. a support frame; 419. cleaning the protective tube; 4110. conveying the auger; 4111. a receiving hopper; 4112. a nozzle mounting hole; 42. a medium particle cleaning mechanism; 43. a large particle cleaning mechanism; 44. a driven pulley; 45. a drive motor; 46. a driving pulley; 47. a synchronous belt; 5. a water circulation unit; 51. a water storage tank; 52. a water pump; 53. a chute; 54. a filter plate; 55. a purified water delivery pipe; 56. and (4) a spray head.

Detailed Description

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

Referring to fig. 1-4, the present invention provides a technical solution: the utility model provides a hierarchical formula cleaning system for food flavouring raw materials, includes equipment bearing frame 1, has the collection unit 2 that bears of size looks adaptation at the top fixed mounting of equipment bearing frame 1, has raw materials to select separately unit 3 bearing the inside rear side fixed mounting of collection unit 2, has hierarchical raw materials cleaning unit 4 bearing the inside front side fixed mounting of collection unit 2, has water circulating unit 5 in the inside of equipment bearing frame 1 and the position fixed mounting that corresponds hierarchical raw materials cleaning unit 4.

Referring to fig. 6-7, the raw material sorting unit 3 includes a supporting bracket 31 fixedly installed above the supporting and collecting unit 2, a small particle screening cylinder 37, a medium particle screening cylinder 38 and a large particle screening cylinder 39 are respectively rotatably connected above the supporting bracket 31, the small particle screening cylinder 37, the medium particle screening cylinder 38 and the large particle screening cylinder 39 are connected in series by a cylinder sleeve 311 to form a communicating structure, the small particle screening cylinder 37, the medium particle screening cylinder 38 and the large particle screening cylinder 39 are integrally in an inclined state, a blocking hopper 310 is fixedly installed at the lowest end of the large particle screening cylinder 39, a plurality of first blanking holes 312, second blanking holes 313 and third blanking holes 314 are respectively and correspondingly formed in the small particle screening cylinder 37, the medium particle screening cylinder 38 and the large particle screening cylinder 39, the first blanking holes 312, the second blanking holes 313 and the third blanking holes 314 are sequentially increased in diameter, the distributed density is reduced in sequence, a large belt pulley 315 is fixedly mounted at the highest end corresponding to the small particle screening cylinder 37, a raw material adding port 316 communicated with the inside of the small particle screening cylinder 37 is formed in the large belt pulley 315, a three-phase asynchronous alternating current motor 317 is fixedly mounted in the bearing support 31, and a small belt pulley 318 is fixedly mounted at the driving end of the three-phase asynchronous alternating current motor 317.

Referring to fig. 9, the classified raw material cleaning unit 4 includes a small particle cleaning mechanism 41, a medium particle cleaning mechanism 42 and a large particle cleaning mechanism 43 fixedly installed above the carrying and collecting unit 2, the small particle cleaning mechanism 41, the medium particle cleaning mechanism 42 and the large particle cleaning mechanism 43 are three members with the same structure, the driven ends of the small particle cleaning mechanism 41, the medium particle cleaning mechanism 42 and the large particle cleaning mechanism 43 all extend to the lower side of the carrying and collecting unit 2, and a driven pulley 44 is fixedly installed, a driving motor 45 is fixedly arranged at the bottom end of the bearing and collecting unit 2, a driving belt wheel 46 is fixedly arranged at the driving end of the driving motor 45, the transmission ratio of each driven belt wheel 44 to the driving belt wheel 46 is 1:1, and a transmission connection structure is formed between each driven pulley 44 and between the driven pulleys 44 and the driving motor 45 through a synchronous belt 47.

Referring to fig. 10-13, each of the small particle cleaning mechanism 41, the medium particle cleaning mechanism 42, and the large particle cleaning mechanism 43 includes a bearing seat 411 fixedly installed at the bottom end inside the load-bearing collection unit 2 in a penetrating manner, a transmission shaft 412 is rotatably connected inside the bearing seat 411, the top end of the transmission shaft 412 extends to the inside of the first-segment solid-liquid separation bucket 413, and is fixedly connected with the first-segment solid-liquid separation bucket 413, a gap on the side wall of the first-segment solid-liquid separation bucket 413 is movably connected with a second-segment solid-liquid separation bucket 414 in a snap-fit manner through a plurality of buckles 415, a plurality of drain holes 416 are formed on the side walls at the bottom of the second-segment solid-liquid separation bucket 414 and the first-segment solid-liquid separation bucket 413, an anti-overflow cover 417 is fixedly connected above the first-segment solid-liquid separation bucket 413, and each of the small particle cleaning mechanism 41, the medium particle cleaning mechanism 42, and the braced frame 418 of end, there is a transparent material to wash protective tube 419 at braced frame 418's top run-through fixed mounting, the inside of washing protective tube 419 is provided with a transport auger 4110, the bottom of carrying auger 4110 and washing protective tube 419 all extends to the inside that anti-overflow covers 417, and the bottom of carrying auger 4110 and the top of transmission shaft 412 pass through shaft coupling fixed connection together, top fixedly connected with at washing protective tube 419 connects hopper 4111, and set up a plurality of shower nozzle mounting hole 4112 that is vertical distribution at the lateral wall of washing protective tube 419.

Referring to fig. 5, the bearing and collecting unit 2 includes a bearing substrate 21 fixedly installed at the top end of the equipment bearing frame 1 and having a size adapted to the size, a fence 22 is fixedly welded at the edge of the top end of the bearing substrate 21, a partition plate 23 is fixedly welded in the middle of the inside of the integral structure formed by the bearing substrate 21 and the fence 22, the partition plate 23 divides the integral structure into a bearing chamber 24 and a waste water collecting chamber 25, and a plurality of water falling holes 26 distributed at equal intervals are formed in the part corresponding to the waste water collecting chamber 25 inside the bearing substrate 21.

A plurality of reinforcing plates 32 with inclination angles which are integrally parallel to the small particle screening cylinder 37, the medium particle screening cylinder 38 and the large particle screening cylinder 39 are fixedly arranged in the bearing support 31, a rotary bearing structure is formed between the bearing support 31 and an integral structure formed by the small particle screening cylinder 37, the medium particle screening cylinder 38 and the large particle screening cylinder 39 respectively through a plurality of cylinder sleeves 311 and a plurality of groups of carrier rollers 36, each group of carrier rollers 36 corresponds to one cylinder sleeve 311, a transmission belt 319 is sleeved outside the small belt pulley 318 and the large belt pulley 315 together, the transmission ratio of the small belt pulley 318 and the large belt pulley 315 is 5:1, a small particle collecting mechanism 33, a medium particle collecting mechanism 34 and a large particle collecting mechanism 35 are fixedly arranged at the top of the bearing support 31 and below the small particle screening cylinder 37, the medium particle screening cylinder 38 and the large particle screening cylinder 39 respectively, the small particle collecting mechanism 33, the medium particle collecting mechanism 34, and the large particle collecting mechanism 35 are three members having the same structure.

Referring to fig. 8, the small particle collecting mechanism 33, the medium particle collecting mechanism 34, and the large particle collecting mechanism 35 each include a supporting plate 351 fixedly mounted on the top of the supporting frame 31, a collecting tank 352 having a semi-cylindrical structure is fixedly welded to the top end of the supporting plate 351, two ends of the collecting tank 352 form a blocking structure through a blocking plate 353 having an arc-shaped top, and a discharging chute 354 is disposed in communication with the lowest point inside the collecting tank 352.

Referring to fig. 14, the water circulation unit 5 includes a water storage tank 51 fixedly installed inside the equipment carrying frame 1 and having an open top, the water storage tank 51 is located under the wastewater collection chamber 25, a plurality of sets of chutes 53 are symmetrically installed on two side walls inside the water storage tank 51, a filter plate 54 is jointly slidably connected between the two chutes 53 on the same horizontal plane, the plurality of filter plates 54 are vertically distributed inside the water storage tank 51, and the filter apertures of the plurality of filter plates 54 are sequentially reduced according to the sequence from top to bottom, the water circulation unit 5 further includes a water pump 52 fixedly installed at the bottom end inside the equipment carrying frame 1, the water inlets of the water storage tank 51 and the water pump 52 are connected in series, a purified water delivery pipe 55 is fixedly connected in series to the water outlet of the water pump 52, three water outlets of the purified water delivery pipe 55 are provided, and a plurality of spray heads 56 are respectively, a plurality of spray heads 56 correspondingly extend into the interior of the cleaning shield 419.

When the device is used, firstly, a three-phase asynchronous alternating current motor 317 is started to drive a small belt pulley 318 to rotate, and a large belt pulley 315 is driven to rotate under the action of a transmission belt 319, because the large belt pulley 315, a small particle screening cylinder 37, a medium particle screening cylinder 38 and a large particle screening cylinder 39 form a whole, and under the action of a plurality of groups of carrier rollers 36 and a plurality of cylinder sleeves 311, the whole formed by the large belt pulley 315, the small particle screening cylinder 37, the medium particle screening cylinder 38, the large particle screening cylinder 39 and a plugging hopper 310 can synchronously rotate;

the height of the whole formed by the large belt pulley 315, the small particle screening cylinder 37, the medium particle screening cylinder 38, the large particle screening cylinder 39 and the plugging hopper 310 is gradually reduced towards the direction of the plugging hopper 310, that is, the whole is inclined, at this time, when raw materials are added into the whole through the raw material adding port 316, the raw materials move towards the direction of the plugging hopper 310, and in the moving process, the raw materials with corresponding particle sizes fall into the corresponding small particle collecting mechanism 33, medium particle collecting mechanism 34 and large particle collecting mechanism 35 through the first blanking hole 312, the second blanking hole 313 and the third blanking hole 314;

after falling into the corresponding collection mechanism, the corresponding raw material is received by the collection groove 352, because the collection groove 352 is parallel to the whole, the lowest point exists, and the position of the lowest point is communicated with the blanking groove 354, so that the raw material can fall into the corresponding small particle cleaning mechanism 41, medium particle cleaning mechanism 42 and large particle cleaning mechanism 43 through the blanking groove 354;

after falling into the corresponding cleaning mechanism, the corresponding raw materials enter the cleaning protection pipe 419 by means of the material receiving hopper 4111, and at the moment, the water pump 52 and the driving motor 45 are started simultaneously;

the water pump 52 conveys the liquid water in the water storage tank 51 to the spray heads 56 through the purified water conveying pipe 55, and each spray head is conveyed to the level of the corresponding height of the cleaning protection pipe 419;

the driving motor 45 drives the driving belt wheel 46 to rotate, one of the driven belt wheels 44 is driven to rotate under the action of the synchronous belt 47, and the driven belt wheels 44 are connected through the synchronous belt 47, so that the corresponding driven belt wheel 44 can drive the corresponding transmission shaft rod 412, the transmission shaft rod 412 can drive the whole body formed by the solid-liquid separation bucket 413 of the first section and the solid-liquid separation bucket 414 of the second section to rotate at a high speed on one hand, and the whole conveying auger 4110 can be driven to rotate on the other hand;

in the process of inputting liquid water into the cleaning protection pipe 419, the raw material falling into the cleaning protection pipe 419 is moved downwards and cleaned at the same time, the cleaned raw material naturally falls into the whole formed by the first-section solid-liquid separation bucket 413 and the second-section solid-liquid separation bucket 414 from the cleaning protection pipe 419, and the whole rotates at a high speed, so that the cleaned liquid water is discharged through the water discharge hole 416 under the action of centrifugal force, the raw material is remained in the whole, and when the raw material needs to be taken out, the buckle connecting the first-section solid-liquid separation bucket 413 and the second-section solid-liquid separation bucket 414 is opened, the second-section solid-liquid separation bucket 414 can be taken down, and then the raw material inside can be taken out;

the cleaned liquid water falls into the wastewater collection chamber 25, then falls into the water storage tank 51 through the water falling hole 26, and then is filtered by the multiple layers of filter plates 54 in the water storage tank 51, so that the clean liquid water can return to each cleaning unit again through the water pump 52, thereby saving water resources and reducing the production cost.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. A grading type cleaning system for food seasoning raw materials comprises an equipment bearing frame (1), and is characterized in that a bearing and collecting unit (2) with the matched size is fixedly installed at the top end of the equipment bearing frame (1), a raw material sorting unit (3) is fixedly installed at the rear side inside the bearing and collecting unit (2), a grading raw material cleaning unit (4) is fixedly installed at the front side inside the bearing and collecting unit (2), and a water circulating unit (5) is fixedly installed inside the equipment bearing frame (1) and at the position corresponding to the grading raw material cleaning unit (4);

raw materials sorting unit (3) are including bearing support (31) that fixed mounting bore the weight of collecting element (2) top bear support (31) the top of bearing support (31) is rotated respectively and is connected with tiny particle screening drum (37), well granule screening drum (38) and large granule screening drum (39), all form the intercommunication structure of concatenating together through barrel casing (311) between tiny particle screening drum (37), well granule screening drum (38) and the large granule screening drum (39), and tiny particle screening drum (37), well granule screening drum (38) and large granule screening drum (39) are whole to be the tilt state, the minimum end fixed mounting that large granule screening drum (39) correspond has shutoff to fight (310), correspond respectively in the inside of tiny particle screening drum (37), well granule screening drum (38) and large granule screening drum (39) and seted up a plurality of first blanking hole (312), The particle size distribution device comprises a second blanking hole (313) and a third blanking hole (314), the pore diameters of the first blanking hole (312), the second blanking hole (313) and the third blanking hole (314) are sequentially increased, the distribution density is sequentially reduced, a large belt pulley (315) is fixedly mounted at the highest end corresponding to the small particle screening cylinder (37), a raw material adding port (316) communicated with the inside of the small particle screening cylinder (37) is formed in the large belt pulley (315), a three-phase asynchronous alternating current motor (317) is fixedly mounted in the bearing support (31), and a small belt pulley (318) is fixedly mounted at the driving end of the three-phase asynchronous alternating current motor (317);

the classified raw material cleaning unit (4) comprises a small particle cleaning mechanism (41), a medium particle cleaning mechanism (42) and a large particle cleaning mechanism (43) which are fixedly arranged above the bearing and collecting unit (2), the driven ends of the small particle cleaning mechanism (41), the medium particle cleaning mechanism (42) and the large particle cleaning mechanism (43) all extend to the lower part of the bearing and collecting unit (2), and are fixedly provided with a driven pulley (44), the bottom end of the bearing and collecting unit (2) is fixedly provided with a driving motor (45), and the driving end of the driving motor (45) is fixedly provided with a driving pulley (46);

the small particle cleaning mechanism (41), the medium particle cleaning mechanism (42) and the large particle cleaning mechanism (43) are three components with the same structure;

the small particle cleaning mechanism (41), the medium particle cleaning mechanism (42) and the large particle cleaning mechanism (43) respectively comprise a bearing seat (411) fixedly installed at the bottom end inside the bearing and collecting unit (2) in a penetrating mode, a transmission shaft rod (412) is rotatably connected inside the bearing seat (411), the top end of the transmission shaft rod (412) extends to the inside of the solid-liquid separation bucket (413) of one section and is fixedly connected with the solid-liquid separation bucket (413) of one section, and an anti-overflow cover (417) is fixedly connected above the solid-liquid separation bucket (413) of one section;

small particle wiper mechanism (41), well granule wiper mechanism (42) and large granule wiper mechanism (43) still all include fixed mounting at the braced frame (418) who bears the weight of the inside bottom of collection unit (2) the top run-through fixed mounting of braced frame (418) has a transparent material wash protective tube (419) wash the inside of protective tube (419) and be provided with one and carry auger (4110), carry auger (4110) and wash the inside that protective tube (419)'s bottom all extends to anti-overflow cover (417), and carry the bottom of auger (4110) and pass through shaft coupling fixed connection together with the top of transmission shaft pole (412).

2. The staged cleaning system for food seasoning raw material according to claim 1, wherein the supporting and collecting unit (2) comprises a supporting base plate (21) which is fixedly installed on the top end of the equipment supporting frame (1) and has a suitable size, a fence (22) is fixedly welded on the edge of the top end of the supporting base plate (21), a partition plate (23) is fixedly welded in the middle of the inside of the integral structure formed by the supporting base plate (21) and the fence (22), the partition plate (23) divides the integral structure into two chambers, namely a supporting chamber (24) and a waste water collecting chamber (25), and a plurality of water falling holes (26) which are distributed equidistantly are formed in the inside of the supporting base plate (21) and correspond to the waste water collecting chamber (25).

3. The staged cleaning system for food seasoning ingredients of claim 1 wherein a plurality of reinforcing plates (32) are fixedly installed inside the supporting bracket (31) and have an inclination angle integrally parallel to the small particle screening cylinder (37), the medium particle screening cylinder (38) and the large particle screening cylinder (39);

a rotary bearing structure is formed between the integral structure formed by the small particle screening cylinder (37), the medium particle screening cylinder (38) and the large particle screening cylinder (39) and the bearing bracket (31) through a plurality of cylinder sleeves (311) and a plurality of groups of carrier rollers (36), and each group of carrier rollers (36) corresponds to one cylinder sleeve (311);

a transmission belt (319) is sleeved outside the small belt pulley (318) and the large belt pulley (315) together, and the transmission ratio of the small belt pulley (318) to the large belt pulley (315) is 5: 1.

4. The staged cleaning system for food seasoning ingredients of claim 1 wherein a small particle collection mechanism (33), a medium particle collection mechanism (34) and a large particle collection mechanism (35) are separately and fixedly installed on the top of the carrier rack (31) and under the corresponding small particle screening drum (37), medium particle screening drum (38) and large particle screening drum (39).

5. The staged cleaning system for food seasoning ingredients of claim 4 wherein the small particle collection means (33), the medium particle collection means (34) and the large particle collection means (35) are three identical components;

the small particle collecting mechanism (33), the medium particle collecting mechanism (34) and the large particle collecting mechanism (35) comprise supporting plates (351) fixedly installed at the tops of bearing supports (31), a collecting tank (352) with a semi-cylindrical structure is fixedly welded to the top end of each supporting plate (351), two ends of each collecting tank (352) form a blocking structure through blocking plates (353) with arc-shaped structures at the tops, and a discharging groove (354) is arranged at the lowest point inside each collecting tank (352) in a communicated mode.

6. The staged cleaning system for seasoning food materials as claimed in claim 1, wherein the transmission ratio of each driven pulley (44) and the driving pulley (46) is 1:1, and a transmission connection structure is formed between each driven pulley (44) and between the driven pulley (44) and the driving motor (45) through a synchronous belt (47).

7. The staged cleaning system for food seasoning raw materials as claimed in claim 1, wherein a plurality of snap-fit two-stage solid-liquid separation bucket (414) are movably connected to the gap of the side wall of the one-stage solid-liquid separation bucket (413) in a snap-fit manner, and a plurality of drain holes (416) are formed in the side walls of the bottoms of the two-stage solid-liquid separation bucket (414) and the one-stage solid-liquid separation bucket (413) and are distributed equidistantly;

the top end of the cleaning protection pipe (419) is fixedly connected with a material receiving hopper (4111), and a plurality of vertically distributed spray head mounting holes (4112) are formed in the side wall of the cleaning protection pipe (419).

8. The staged cleaning system for seasoning raw materials for food according to claim 2, wherein the water circulation unit (5) comprises a water storage tank (51) fixedly installed inside the apparatus carrying frame (1) and having an open top, the water storage tank (51) is located right below the waste water collecting chamber (25), a plurality of sets of chutes (53) are symmetrically installed on two side walls inside the water storage tank (51), and a filter plate (54) is connected between the two chutes (53) on the same horizontal plane in a sliding manner.

9. The staged cleaning system for seasoning food materials as claimed in claim 8, wherein said plurality of filter plates (54) are vertically arranged inside the water storage tank (51), and the filter apertures of the plurality of filter plates (54) are sequentially decreased from top to bottom.

10. The staged cleaning system for food seasoning raw materials according to claim 8, wherein the water circulation unit (5) further comprises a water pump (52) fixedly installed at the bottom end inside the equipment carrying frame (1), the water storage tank (51) and the water pump (52) have their water inlets connected in series, the water pump (52) has its water outlet fixedly connected in series with a purified water delivery pipe (55), the water outlets of the purified water delivery pipe (55) are provided with three, three water outlets are respectively and correspondingly installed with a plurality of spray heads (56), and a plurality of spray heads (56) correspondingly extend to the inside of the cleaning protection pipe (419).

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