CN212328389U - Automatic peeling production line for quick-frozen fresh corn kernels - Google Patents

Abstract

The utility model provides an automatic desquamation production line of bright kernel of quick-freeze, the operating efficiency who solves prior art existence is low, and output is little, and the temperature variation range of bright kernel of corn is big in the course of working, lacks the bran collection device, influences product quality's problem. Including the discharge gate with select separately the one-level desquamation device that mobile bellows links to each other, its characterized in that: the discharge end of the separation flowing air box is connected with the middle section separation roller screen, the belt type conveying freezing box connected with the discharge port of the middle section separation roller screen is connected with the second-stage flowing air box, and the discharge end of the second-stage flowing air box is connected with the second-stage peeling device; the discharge end of a third-stage flowing air box connected with the discharge port of the second-stage peeling device is connected with the third-stage peeling device, and the discharge port of the third-stage peeling device is connected with a discharge sorting roller screen; the bran discharge port of each peeling device is respectively connected with a bran collecting device. The device has the advantages of reasonable design, compact structure, high production efficiency, good product uniformity, no bran and chaff inclusion, small temperature change in the processing process and capability of effectively collecting the bran and chaff.

Description

Automatic peeling production line for quick-frozen fresh corn kernels

Technical Field

The utility model belongs to the technical field of the grain desquamation, concretely relates to production efficiency is high, and the product homogeneity is good, there is not the husk mix with, and the temperature variation range in the course of working is little, does benefit to nutrient composition and remains, can effectively collect the automatic desquamation production line of the bright kernel of quick-freeze of grinding husk.

Background

The corn contains rich unsaturated fatty acid, especially linoleic acid with content of more than 60%, and it can reduce blood cholesterol concentration and prevent it from depositing on blood vessel wall under the synergistic action of vitamin E in corn germ. Therefore, the corn has certain prevention and treatment effects on coronary heart disease, atherosclerosis, hyperlipidemia, hypertension and the like. Especially fresh corn, is accepted by people due to fresh and sweet taste and nutrition. The sticky corn is one kind of corn, also called waxy corn, and is increasingly favored by people who advocate health and well-being in modern times due to the nature of coarse grains and the taste of fine grains. However, most of the sticky corn products in the current market are fresh or quick-frozen products, most of the sticky corn products are eaten after the corn cobs are cooked, and the sticky corn needs a long time for cooking. People also often use corn dregs made by crushing peeled dry corn to make porridge, but after the cooked porridge made by the dry corn dregs enters the mouth, the porridge always has granular feeling, is not tasty and refreshing and is difficult to swallow; meanwhile, the corn loses the unique sweet and sticky taste of fresh corn in the drying process, and the nutritive value of the corn is not as good as that of quick-frozen fresh corn, so that the corn is more obvious for sticky corn.

The peeled fresh corn has smooth taste, is softer and more glutinous than corn grit porridge after being boiled, is very suitable for special crowds such as children, old people and the like, and has high nutritional value. The existing grain peeling technology is very mature, but only the grains which are mature and dried in the sun and have certain hardness can be peeled; if it is desired to make corn gruel from fresh corn kernels, fresh, tender corn kernels need to be decorticated. At present, the peeled fresh corn is produced by mainly adopting a mode of grinding and peeling quick-frozen fresh corn kernels. The traditional grinding and peeling method for the quick-frozen fresh corn kernels adopts a manual grinding and screening mode, so that the labor intensity is high, the operation efficiency is low, the yield is low, and the uniformity of the product is poor. In addition, some existing mechanical grinding and peeling equipment for quick-frozen fresh corn kernels is unreasonable in structure, a large amount of bran is mixed in the peeled fresh corn kernels, and the temperature change range of the fresh corn kernels in the processing process is large, so that the preservation of nutritional ingredients is not facilitated; meanwhile, an effective bran collecting device is lacked, so that the pollution to the working environment is easily caused, the product quality is influenced, and the practicability is poor. Therefore, the prior art of the peeling process and the processing equipment of the quick-frozen fresh corn kernels needs to be improved.

SUMMERY OF THE UTILITY MODEL

The utility model discloses just to above-mentioned problem, provide a production efficiency height, the product homogeneity is good, no bran mix with, and the temperature variation range in the course of working is little, does benefit to nutrient composition and remains, can effectively collect the automatic desquamation production line of the bright kernel of quick-freeze of grinding bran.

The utility model adopts the technical proposal that: this automatic desquamation production line of bright kernel of corn of quick-freeze includes one-level desquamation device, its characterized in that: the feeding port of the primary peeling device is connected with the discharging end of the primary flowing air box, and the feeding end of the primary flowing air box is connected with the discharging port of the block frozen corn crusher through a conveying pipeline; the discharge port of the first-stage peeling device is connected with the feed end of the separation flowing air box through a conveying pipeline, the discharge end of the separation flowing air box is connected with the feed port of the middle-stage separation roller screen, the discharge port of the middle-stage separation roller screen is connected with the feed port of the belt-type conveying freezing box, the discharge port of the belt-type conveying freezing box is connected with the feed end of the second-stage flowing air box through a conveying pipeline, and the discharge end of the second-stage flowing air box is connected with the feed port of the second-stage peeling device; the discharge port of the second-stage peeling device is connected with the feed end of the third-stage flowing air box through a conveying pipeline, the discharge end of the third-stage flowing air box is connected with the feed port of the third-stage peeling device, and the discharge port of the third-stage peeling device is connected with the feed port of the discharge sorting roller screen; the device comprises a first-stage peeling device, a second-stage peeling device, a third-stage peeling device, a dust remover, a first-stage peeling device, a second-stage peeling device, a third-stage peeling device, a fourth-stage peeling device.

The first-stage peeling device comprises a plurality of groups of frozen corn grinding and peeling machines which are arranged in parallel, a corn kernel feeding hopper is arranged above a feeding port of each frozen corn grinding and peeling machine, the first-stage flowing air box is arranged on one side above the corn kernel feeding hopper, and a discharging end at the lower part of the first-stage flowing air box is connected with an inlet of the corn kernel feeding hopper; an air inducing port on the side part of the primary flowing air box is connected with a primary high-pressure induced draft fan, and an air outlet of the primary high-pressure induced draft fan is connected with an ice chip collecting cloth bag through a pipeline; the discharge port of the frozen corn grinding and peeling machine is respectively connected with a primary peeled corn collecting hopper below the frozen corn grinding and peeling machine through a discharge chute, the lower end of the primary peeled corn collecting hopper is connected with the feed end of the side part of the sorting flow air box through a conveying pipeline, an air induction port at the other side of the sorting flow air box is connected with a sorting high-pressure induced draft fan, and an air outlet of the sorting high-pressure induced draft fan is connected with a flow bran collector through a pipeline; the flowing bran collector is composed of a coarse bran collecting cyclone cylinder, the lower port of the coarse bran collecting cyclone cylinder is connected with a coarse bran collecting cloth bag, and the upper port of the coarse bran collecting cyclone cylinder is connected with a fine bran collecting cloth bag through a ventilation cap cylinder. Conveying frozen corn particles scattered by the blocky frozen corn crusher into a corn particle feeding hopper by using a primary flowing air box through a conveying pipeline, and grinding and peeling the frozen corn particles by using a frozen corn grinding and peeling machine; and then conveying the peeled frozen corn particles into a separation flow air box to separate bran from the frozen corn particles.

The frozen corn grinding and peeling machine comprises a peeling machine main body, wherein a grinding cylinder with an upper opening and a lower opening is fixedly arranged in the peeling machine main body, a grinding runner is rotatably arranged in a grinding and peeling cavity of the grinding cylinder, a rotating vertical shaft is arranged in the middle of the grinding runner, and the lower end of the rotating vertical shaft is connected with an output shaft of a peeling driving motor through a transmission mechanism; a conical upper cover is arranged above the upper opening of the grinding cylinder, and a peeling feeding hopper is arranged at the top of the conical upper cover; a ground corn falling bin is arranged below the lower opening of the grinding cylinder, and a bottom outlet of the ground corn falling bin is connected with a peeling discharge chute; a plurality of bran powder leakage nets which are arranged along the circumference of the transverse section of the grinding cylinder are arranged on the vertical cylinder wall of the grinding cylinder, the lower parts of the outer sides of the bran powder leakage nets are communicated with a bran powder accumulation cavity below the peeling machine main body through a bran powder lower leakage opening, a bran powder stirring cavity is arranged at the lower part of the bran powder accumulation cavity, and a bran powder discharge opening is formed in the side wall of the bran powder stirring cavity; the inside of the bran powder conveying cavity is rotatably provided with a bran powder shifting wheel, the bran powder shifting wheel is provided with an arc-shaped shifting wheel blade, and a rotating shaft in the middle of the bran powder shifting wheel is coaxially connected with a rotating vertical shaft of the grinding rotating wheel. The rotating vertical shaft is driven to rotate by the peeling driving motor and the transmission mechanism, so that the grinding rotating wheel is driven to rotate in the grinding and peeling cavity of the grinding cylinder, and the frozen corn particles are ground and peeled; meanwhile, the bran powder poking wheel rotating along with the rotating vertical shaft pokes and sends out bran powder falling into the bran powder accumulation cavity through the bran powder leakage net on the side wall of the grinding cylinder from the bran powder discharge hole.

The grinding rotating wheel is composed of a cylindrical rotating wheel main body, and a wheel body cavity is arranged in the cylindrical rotating wheel main body; the upper end of the cylindrical rotating wheel main body is provided with a rotating wheel upper cover, the middle part of the rotating wheel upper cover is provided with a vertical shaft through hole, the lower end of the cylindrical rotating wheel main body is provided with a rotating wheel lower cover, and the middle part of the rotating wheel lower cover is also provided with a vertical shaft through hole; the rotating vertical shaft passes through the cylindrical rotating wheel main body of the whole grinding rotating wheel through vertical shaft through holes on the rotating wheel upper cover and the rotating wheel lower cover. After long-time use, when the grinding rotating wheel is worn excessively, only the cylindrical rotating wheel main body needs to be replaced, the maintenance is convenient, and the cost is saved.

A plurality of groups of grinding rubber blocks which are arranged at equal intervals along the circumference of the transverse section of the cylinder body are arranged on the inner side wall of the grinding cylinder, and each group of grinding rubber blocks is respectively connected with a guide sliding hole on the vertical cylinder wall of the grinding cylinder in a sliding manner through a guide inserting column which is arranged horizontally; and the grinding rubber block is also connected with a rubber block adjusting bolt penetrating through the wall of the grinding cylinder, the front end of the rubber block adjusting bolt is connected with the middle part of the grinding rubber block, and the adjusting part at the rear end of the rubber block adjusting bolt is positioned outside the peeling machine main body. So that the distance between the grinding rubber block on the inner wall of the grinding cylinder and the outer wall of the middle grinding runner can be adjusted conveniently, and the applicability of the device is effectively improved; meanwhile, the grinding rubber block is convenient to replace.

The middle section sorting roller screen and the discharging sorting roller screen are of the same structure and respectively comprise roller screen main bodies, a sectional roller screen cylinder is rotatably arranged in each roller screen main body, the driving end of the sectional roller screen cylinder is connected with the output shaft of a roller screen driving motor on the outer side of one end of each roller screen main body, and the inlet of the sectional roller screen cylinder is connected with a roller screen feeding pipe on the other end of each roller screen main body; the lower part of the roller screen main body is sequentially provided with a fine grain discharge port, a coarse grain discharge port and a finished product discharge port along the conveying direction of materials in the sectional roller screen cylinder, and a vibrating type conveying device is arranged below the finished product discharge port. Residual bran mixed in the frozen corn grains which enter the segmented roller screen cylinder through the roller screen feeding pipe and are ground and peeled is segmented and screened out, and the quality of an intermediate product is improved.

The primary flow air box, the sorting flow air box, the secondary flow air box and the tertiary flow air box are the same in structure and respectively comprise inverted triangular air box main bodies, air box feed ends and air box induced air ports are respectively arranged on two sides of the upper part of the air box main body, and air box discharge ends are arranged on the lower part of the air box main body; and a material guide inclined plane is arranged on one side of the inside of the air box main body, which is close to the feeding end of the air box, and an arc-shaped material guide plate is arranged on the upper part of the other side of the inside of the air box main body and below the air box air inducing port. The frozen corn particles are introduced into the air box main body through the air box feeding end by the draught fan connected with the air box draught opening, and bran mixed in the frozen corn particles are preliminarily separated from the air box draught opening by utilizing the arc-shaped material guide plate.

The first-stage bran collecting device and the last-stage bran collecting device are identical in structure and respectively comprise a bran cyclone collecting cylinder, the bran cyclone collecting cylinder is composed of a cyclone collecting cylinder body, a bran wind inlet is formed in one side of the upper portion of the cyclone collecting cylinder body, and a fine bran wind outlet is formed above the bran wind inlet and on the side portion of the upper end of the cyclone collecting cylinder body; the cyclone collecting cylinder body is internally and rotatably provided with a wall scraping blade, and the upper end of a wall scraping rotating shaft in the middle of the wall scraping blade is connected with the driving end of a cyclone driving motor at the upper end of the cyclone collecting cylinder body; a closed discharge valve is arranged at a discharge port at the lower end of the cylinder body of the cyclone collecting cylinder; the bran air inlets of the bran cyclone collecting cylinders of the first-stage bran collecting device and the last-stage bran collecting device are respectively connected with the bran discharge ports of the corresponding peeling devices through bran powder conveying pipelines, the fine bran-containing air outlets of the bran cyclone collecting cylinders are respectively connected with the air inlet of a bran collecting induced draft fan through a bran fine powder suction pipeline, and the exhaust port of the bran collecting induced draft fan is connected with a dust remover through an induced draft fan exhaust pipe; a bran conveyer belt is arranged below the closed discharge valve at the lower end of the bran cyclone collecting cylinder. The ground frozen corn bran discharged from the bran discharge outlets of the first-stage peeling device, the second-stage peeling device and the third-stage peeling device is collected in a centralized manner.

The second-stage peeling device comprises a plurality of groups of frozen corn grinding and peeling machines which are arranged in parallel, a corn kernel feeding hopper is arranged above a feeding port of each frozen corn grinding and peeling machine, the second-stage flowing air box is arranged on one side above the corn kernel feeding hopper, and a discharging end at the lower part of the second-stage flowing air box is connected with an inlet of the corn kernel feeding hopper; an induced draft port on the side part of the secondary flow air box is connected with a secondary high-pressure induced draft fan, the feed end of the secondary flow air box is connected with the discharge port of the belt-type conveying freezing box through a conveying pipeline, and the air outlet of the secondary high-pressure induced draft fan is connected with a flow bran collector through a pipeline; the flowing bran collector is composed of a coarse bran collecting cyclone cylinder, the lower port of the coarse bran collecting cyclone cylinder is connected with a coarse bran collecting cloth bag, and the upper port of the coarse bran collecting cyclone cylinder is connected with a fine bran collecting cloth bag through a ventilation cap cylinder; the discharge port of the frozen corn grinding and peeling machine is respectively connected with a secondary peeling and collecting hopper below the discharge port through a discharge chute, and the lower end of the secondary peeling and collecting hopper is connected with the feed end of the side part of the tertiary flow air box through a conveying pipeline. Conveying the frozen corn particles at the discharge port of the belt-type conveying freezing box into a corn particle feeding hopper above a secondary peeling device by using a secondary flowing air box through a conveying pipeline, separating bran and chaff included in the frozen corn particles, and grinding and peeling the corn particles by using a frozen corn grinding and peeling machine; the peeled frozen corn particles are then transferred to a tertiary flow windbox.

The three-stage peeling device comprises a plurality of groups of frozen corn grinding and peeling machines which are arranged in parallel, a corn kernel feeding hopper is arranged above a feeding port of each frozen corn grinding and peeling machine, the three-stage flowing air box is arranged on one side above the corn kernel feeding hopper, and a discharging end at the lower part of the three-stage flowing air box is connected with an inlet of the corn kernel feeding hopper; an induced draft port on the side part of the third-stage flowing air box is connected with a third-stage high-pressure induced draft fan, the feed end of the third-stage flowing air box is connected with the lower end of the secondary peeling and collecting hopper through a conveying pipeline, and the air outlet of the third-stage high-pressure induced draft fan is connected with a flowing bran collector through a pipeline; the discharge gate department that freezes maize and grinds decorticator is provided with cooling air curtain machine, and the lower extreme of cooling air curtain machine is provided with and connects the hopper box, and the below that connects the hopper box is provided with belt conveyor, and belt conveyor's front portion links to each other with the lower extreme of lift conveyor, lift conveyor's upper end with the pan feeding mouth of ejection of compact sorting roller screen links to each other. Conveying the frozen corn particles ground and peeled by the second-stage peeling device into a corn particle feeding hopper above the third-stage peeling device by using a third-stage flowing air box through a conveying pipeline, separating bran from the frozen corn particles, and then grinding and peeling the frozen corn particles by using a frozen corn grinding and peeling machine; frozen corn grinding and peeling machine through the three-stage peeling device grinds frozen corn particles after peeling, and after the cooling of the cooling air curtain machine at the discharge port, the frozen corn particles fall onto the belt conveyor from the receiving hopper box, and enter into the feed inlet of the discharge sorting roller screen through the lifting conveyor.

The utility model has the advantages that: because the utility model adopts the first-stage peeling device with the feeding port connected with the discharge end of the first-stage flowing bellows, the feeding end of the first-stage flowing bellows is connected with the discharge port of the block-shaped frozen corn crusher through the conveying pipeline; the discharge port of the first-stage peeling device is connected with the feed end of the separation flowing air box through a conveying pipeline, the discharge end of the separation flowing air box is connected with the feed port of the middle-stage separation roller screen, the discharge port of the middle-stage separation roller screen is connected with the feed port of the belt-type conveying freezing box, the discharge port of the belt-type conveying freezing box is connected with the feed end of the second-stage flowing air box through a conveying pipeline, and the discharge end of the second-stage flowing air box is connected with the feed port of the second-stage peeling device; the discharge port of the second-stage peeling device is connected with the feed end of the third-stage flowing air box through a conveying pipeline, the discharge end of the third-stage flowing air box is connected with the feed port of the third-stage peeling device, and the discharge port of the third-stage peeling device is connected with the feed port of the discharge sorting roller screen; the bran discharge port of the first-stage peeling device and the bran discharge ports of the second-stage peeling device and the third-stage peeling device are respectively connected with the first-stage bran collecting device and the last-stage bran collecting device through conveying pipelines, so that the corn peeling machine is reasonable in design, compact in structure, high in peeling production efficiency of frozen corn particles, good in uniformity of product particles and free of bran impurities; the temperature change range in the processing process is small, the nutrient components are well kept, meanwhile, the hardness of the frozen corn particles is stable, and the peeling quality of the frozen fresh corn is guaranteed. And moreover, the corn bran which is ground is collected in a unified manner, so that the pollution to the working environment is effectively avoided, and the practicability is high.

Drawings

Fig. 1 is a schematic view of the overall arrangement of the present invention.

Fig. 2 is a view in the direction a of fig. 1.

Figure 3 is a schematic view of a configuration of the primary peeling apparatus of figure 1.

Fig. 4 is a front view of fig. 3.

Fig. 5 is a schematic view showing a structure of the frozen corn milling and peeling machine of fig. 3.

Fig. 6 is a view from direction B of fig. 5.

Fig. 7 is a front view of fig. 5.

Fig. 8 is a cross-sectional view taken along line C-C of fig. 7.

Figure 9 is a schematic view of one configuration of the grinding wheel of figure 8.

Fig. 10 is a sectional view of the internal structure of fig. 9.

Fig. 11 is a cross-sectional view taken along line D-D of fig. 7.

Fig. 12 is a cross-sectional view taken along line E-E of fig. 7.

Fig. 13 is a schematic view of a construction of the mid-section sort roller screen of fig. 1.

Fig. 14 is a front view of fig. 13.

Fig. 15 is a schematic diagram of a construction of the sectioned trommel drum of fig. 14.

Fig. 16 is a schematic diagram of a belt-type freezer shown in fig. 13.

FIG. 17 is a schematic view of a structure of the primary flow windbox (sorting flow windbox, secondary flow windbox, tertiary flow windbox) in FIG. 1.

Fig. 18 is a schematic view showing a structure of the first stage bran collector (the last stage bran collector) in fig. 1.

Fig. 19 is a schematic view of a structure of the bran cyclone collecting cartridge of fig. 18.

Fig. 20 is a schematic view of a construction of the paring blade in fig. 19.

FIG. 21 is a schematic illustration of one configuration of the closed discharge valve of FIG. 19.

Figure 22 is a schematic view of a connection of the secondary and tertiary peeling devices of figure 1.

The sequence numbers in the figures illustrate: 1 block frozen corn crusher, 2 first-stage flowing bellows, 3 first-stage peeling device, 4 sorting flowing bellows, 5 first-stage bran collecting device, 6 middle-stage sorting roller screen, 7 belt type conveying freezing box, 8 second-stage flowing bellows, 9 second-stage peeling device, 10 third-stage flowing bellows, 11 third-stage peeling device, 12 discharging sorting roller screen, 13 last-stage bran collecting device, 14 dust remover, 15 maintenance operation platform, 16 first-stage high-pressure induced draft fan, 17 ice chip collecting cloth bag, 18 corn grain feeding hopper, 19 frozen corn grinding peeling machine, 20 discharging chute, 21 primary peeling corn collecting hopper, 22 sorting high-pressure induced draft fan, 23 flowing bran collector, 24 coarse bran collecting cyclone, 25 ventilating cap cylinder, 26 coarse bran collecting cloth bag, 27 fine bran collecting cloth bag, 28 peeling machine main body, 29 conical upper cover, 30 peeling feeding hopper, 31 anti-blocking cleaning door, 32 cleaning door lock, 33 rubber block adjusting bolt, 34 material control lifting baffle plate, 35 peeling discharge chute, 36 bran powder accumulation cavity, 37 bran powder stirring and feeding cavity, 38 bran powder discharge port, 39 peeling driving motor, 40 transmission mechanism, 41 grinding cylinder, 42 bran powder leakage net, 43 bran powder lower leakage port, 44 feeding adjusting valve plate, 45 grinding and peeling cavity, 46 grinding rotating wheel, 47 guiding insertion column, 48 grinding rubber block, 49 rotating vertical shaft, 50 middle bearing, 51 bran powder stirring wheel, 52 ground corn falling bin, 53 cylindrical rotating wheel main body, 54 rotating wheel upper cover, 55 rotating wheel lower cover, 56 cavity, 57 vertical shaft through hole, 58 stirring wheel blade, 59 rolling sieve main body, 60 rolling sieve driving motor, 61 rolling sieve feeding pipe, 62 fine particle discharge port, 63 coarse particle discharge port, 64 finished product discharge port, 65 vibration type conveying device, 66 conveying belt freezing box main body, 67 sectional rolling sieve cylinder, 69 sieve main body, 66 conveying belt freezing box main body, 67 freezing box main body, 68 sectional rolling cylinder, 70 spiral material conveying plate, 71 screening material inlet, 72 fine grain sieve section, 73 coarse grain sieve section, 74 finished product sieve section, 75 tail end material outlet, 76 rolling screen driving end, 77 refrigerator, 78 frozen corn hopper, 79 air box main body, 80 air box feeding end, 81 air box air inducing port, 82 air box discharging end, 83 arc material guiding plate, 84 material guiding inclined plane, 85 bran powder conveying pipeline, 86 bran cyclone collecting cylinder, 87 bran conveying belt, 88 bran fine powder suction pipeline, 89 bran collecting induced draft fan, 90 induced draft fan exhaust pipe, 91 cyclone collecting cylinder body, 92 bran air inlet, 93 fine bran containing air outlet, 94 cyclone driving motor, 95 wall scraping rotating shaft, 96 wall scraping blade, 97 closed discharge valve, 98 motor, 99 rotating blade body, 100 middle hollow, 101 blade supporting frame, 102 discharge valve body, 103 valve body material inlet, 104 valve body discharge port, 105 closed rotating blade, 105 discharge valve body, 106 second-stage high-pressure induced draft fans, 107 secondary peeling collecting hoppers, 108 cooling air curtain machines, 109 hopper receiving boxes, 110 belt conveyors, 111 third-stage high-pressure induced draft fans and 112 lifting conveyors.

Detailed Description

The specific structure of the present invention will be described in detail with reference to fig. 1 to 22. The automatic peeling production line of the quick-frozen fresh corn kernels comprises a first-stage peeling device 3, wherein the first-stage peeling device 3 consists of a plurality of groups (for example, three groups) of frozen corn grinding and peeling machines 19 which are arranged in parallel; a maintenance operation platform 15 is arranged above the frozen corn grinding and peeling machines 19 which are arranged in parallel. The frozen corn grinding and peeling machine 19 comprises a peeling machine main body 28, wherein an inverted cone-shaped grinding cylinder 41 with an upper opening and a lower opening is fixedly arranged in the peeling machine main body 28; a grinding wheel 46 is rotatably provided in a grinding and peeling chamber 45 inside the grinding cylinder 41. The grinding rotor 46 is constituted by a cylindrical rotor body 53, the cylindrical rotor body 53 is of a grinding wheel type structure in which a common abrasive is fixed and formed by a binder, and a rotor body cavity 56 for reducing the weight is provided inside the cylindrical rotor body 53. The upper end of the cylindrical rotating wheel main body 53 is detachably provided with a rotating wheel upper cover 54, and the middle part of the rotating wheel upper cover 54 is provided with a vertical shaft through hole 57; the lower end of the cylindrical rotating wheel main body 53 is provided with a rotating wheel lower cover 55, and the middle part of the rotating wheel lower cover 55 is also provided with a vertical shaft through hole 57; after long-time use and when the grinding runner 46 is worn excessively, only the cylindrical runner body 53 needs to be replaced, so that the maintenance is convenient and the cost is saved. The middle part of the grinding runner 46 is provided with a rotating vertical shaft 49, the rotating vertical shaft 49 passes through the cylindrical runner body 53 of the whole grinding runner 46 through a vertical shaft through hole 57 in the middle part of a runner upper cover 54 and a runner lower cover 55, and a middle bearing 50 is arranged on the rotating vertical shaft 49 and below the runner lower cover 55. The lower end of the rotating vertical shaft 49 is connected with the output shaft of the peeling driving motor 39 through the belt wheel transmission mechanism 40.

A conical upper cover 29 is arranged above the upper opening of the inverted conical grinding cylinder 41, and a peeling feed hopper 30 is arranged at the top of the conical upper cover 29. A milled corn falling bin 52 for collecting the milled and peeled frozen corn particles is arranged below the lower opening of the milling cylinder 41; the outlet at the bottom of the milled corn falling bin 52 is connected with the peeling discharge chute 35. The vertical cylinder wall of the grinding cylinder 41 is provided with a plurality of bran powder leakage nets 42 which are arranged at equal intervals along the circumference of the transverse section of the cylinder body, and the lower part of the outer side of each bran powder leakage net 42 is communicated with a bran powder accumulation cavity 36 below the peeling machine main body 28 through a bran powder lower leakage opening 43. A bran powder transferring cavity 37 is arranged at the lower part of the bran powder accumulating cavity 36, and a bran powder discharging hole 38 is arranged on the side wall of the bran powder transferring cavity 37. A bran powder shifting wheel 51 is rotatably arranged inside the bran powder shifting cavity 37, and at least two groups of arc-shaped shifting wheel blades 58 are arranged on the bran powder shifting wheel 51; and the rotating shaft at the middle part of the bran powder shifting wheel 51 is coaxially connected with the lower end of the rotating vertical shaft 49 at the middle part of the grinding rotating wheel 46. Further, the rotating vertical shaft 49 is driven to rotate by the peeling driving motor 39 and the belt wheel transmission mechanism 40, so as to drive the grinding rotating wheel 46 to continuously rotate in the grinding peeling cavity 45 of the grinding cylinder 41, and the frozen corn particles are ground and peeled; meanwhile, the bran powder shifting wheel 51 rotating together with the rotating vertical shaft 49 shifts the bran powder falling into the bran powder accumulation chamber 36 through the bran powder leakage net 42 on the side wall of the grinding cylinder 41 into the bran powder conveying pipeline 85 from the bran powder discharge port 38.

The inner side wall of the grinding cylinder 41 is provided with a plurality of groups of grinding rubber blocks 48 which are arranged along the circumference of the transverse section of the cylinder body at equal intervals, and each group of grinding rubber blocks 48 are respectively connected with the guide sliding holes on the vertical cylinder wall of the grinding cylinder 41 in a sliding manner through the guide inserting columns 47 which are arranged horizontally. The grinding rubber block 48 is also connected with a rubber block adjusting bolt 33 penetrating through the cylinder wall of the grinding cylinder 41, the front end of the rubber block adjusting bolt 33 is connected with the middle part of the grinding rubber block 48, and the adjusting part of the rear end of the rubber block adjusting bolt 33 is positioned at the outer side of the peeling machine main body 28; so that the distance between the grinding rubber block 48 on the inner wall of the grinding cylinder 41 and the outer wall of the middle grinding runner 46 can be adjusted, the applicability of the grinding runner 46 can be effectively improved, and the replacement of the grinding rubber block 48 is convenient. The outer wall of the peeling machine main body 28 and the position corresponding to the bran powder leakage net 42 of the grinding cylinder 41 are respectively provided with an anti-blocking cleaning door 31, one end of the anti-blocking cleaning door 31 is rotatably connected with the side edge of the opening of the outer wall of the peeling machine main body 28 through a hinge, and the other end of the anti-blocking cleaning door 31 is movably connected with the outer wall of the peeling machine main body 28 through a cleaning door lock 32; and then when the bran powder leakage net 42 and the bran powder lower leakage opening 43 are blocked, the anti-blocking cleaning door 31 is opened for cleaning. The milled corn falls into a peeling discharge chute 35 at the bottom of the bin 52, and a material control lifting baffle 34 for adjusting the discharge amount of the frozen corn grinding and peeling machine 19 is arranged. A feeding adjusting valve plate 44 for controlling the input amount of frozen corn particles entering the grinding and peeling cavity 45 is arranged on a vertical pipeline of the peeling hopper 30 connected with the conical upper cover 29.

The corn kernel feeding hopper 18 is arranged above the peeling hopper 30 of the frozen corn grinding and peeling machine 19 and on the horizontal table surface of the maintenance operation platform 15. A primary flowing air box 2 is arranged on one side above the corn kernel feeding hopper 18, and an air box discharging end 82 at the lower part of the primary flowing air box 2 is connected with an inlet of the corn kernel feeding hopper 18. The first-stage flowing bellows 2 includes an inverted triangular bellows main body 79, a bellows feed end 80 and a bellows suction port 81 are provided on both sides of an upper portion of the bellows main body 79, respectively, and a bellows discharge end 82 is provided on a lower portion of the bellows main body 79. The air box feeding end 80 of the first-stage flowing air box 2 is connected with the discharge hole of the block-shaped frozen corn crusher 1 through a conveying pipeline, a guide inclined plane 84 is arranged on one side, close to the air box feeding end 80, inside the air box main body 79, and an arc-shaped guide plate 83 is arranged on the upper portion of the other side inside the air box main body 79 and below the air box air induction hole 81. The bellows induced air port 81 of the lateral part of the first-stage flowing bellows 2 is connected with the first-stage high-pressure induced fan 16, and the air outlet of the first-stage high-pressure induced fan 16 is connected with the ice chip collecting cloth bag 17 through a pipeline. The frozen corn particles are introduced into the air box main body 79 through the air box inlet port 81 of the first-stage flowing air box 2 by the induced draft fan connected with the air box inlet port 81, and bran and scrap ice blocks mixed in the frozen corn particles are primarily separated from the air box inlet port 81 by the arc-shaped material guide plate 83.

The peeling discharge chutes 35 of the frozen corn grinding and peeling machines 19 of the primary peeling device 3 are respectively connected with the primary peeling corn collecting hoppers 21 below the primary peeling device through discharge chutes 20, the lower ends of the primary peeling corn collecting hoppers 21 are connected with air box feed ends 80 at the side parts of the separation flow air boxes 4 through conveying pipelines, and the structure of the separation flow air boxes 4 is the same as that of the primary flow air boxes 2; the air box induced draft port 81 on the other side of the separation flowing air box 4 is connected with the separation high-pressure induced draft fan 22, and the air outlet of the separation high-pressure induced draft fan 22 is connected with the flowing bran collector 23 through a pipeline. The flowing bran collector 23 is composed of a coarse bran collecting cyclone cylinder 24 which is vertically arranged, the lower port of the coarse bran collecting cyclone cylinder 24 is connected with a coarse bran collecting cloth bag 26, and the upper port of the coarse bran collecting cyclone cylinder 24 is connected with a fine bran collecting cloth bag 27 through a ventilation cap cylinder 25 which is transversely arranged. Further, the frozen corn particles scattered by the blocky frozen corn crusher 1 are conveyed into a corn particle feeding hopper 18 at the upper part of the primary peeling device 3 by a first-stage flowing air box 2 through a conveying pipeline, and are ground and peeled by a frozen corn grinding and peeling machine 19; then, the frozen corn particles after the primary grinding and peeling are conveyed into a separation flowing air box 4, and bran included in the frozen corn particles is separated.

The air box discharging end 82 of the sorting flowing air box 4 is connected with a roller screen feeding pipe 61 of the middle-section sorting roller screen 6, the middle-section sorting roller screen 6 comprises a roller screen main body 59, and a sectional roller screen cylinder 68 is rotatably arranged inside the roller screen main body 59; the segmented roller screen cylinder 68 is composed of a screen cylinder main body 69 with screen holes on the side wall, a spiral material conveying plate 70 arranged continuously is arranged on the inner side wall of the screen cylinder main body 69, a screening material inlet 71 is arranged at one end of the screen cylinder main body 69, and a roller screen driving end 76 is arranged at the other end of the screen cylinder main body 69. A fine grain sieve section 72, a coarse grain sieve section 73 and a finished product sieve section 74 are sequentially arranged on the inner side wall of the sieve cylinder main body 69 along the conveying direction of materials in the cylinder, the sieve pore diameter of the fine grain sieve section 72 is 2-4 mm, the sieve pore diameter of the coarse grain sieve section 73 is 4-6 mm, and the sieve pore diameter of the finished product sieve section 74 is 6-10 mm; in front of the finished product sieve section 74 and on the side wall of the end of the sieve cylinder body 69, there are several groups of end discharge ports 75 arranged at equal intervals along the circumference of the cylinder wall. The roller screen driving end 76 of the sectional roller screen cylinder 68 is connected with the output shaft of the roller screen driving motor 60 at the outer side of one end of the roller screen main body 59, and the screening material inlet 71 of the sectional roller screen cylinder 68 is connected with the roller screen material inlet pipe 61 at the other end of the roller screen main body 59. In addition, a fine grain discharge port 62, a coarse grain discharge port 63, and a finished product discharge port 64 are provided in the lower portion of the roller screen main body 59 in order along the conveying direction of the material in the segment roller screen cylinder 68, which correspond to the positions of the fine grain sieve section 72, the coarse grain sieve section 73, and the finished product sieve section 74 on the inner side wall of the screen cylinder main body 69, respectively. Thereby screening out the residual bran and chaff mixed in the frozen corn grains which enter the middle section sorting roller screen 6 through the roller screen feeding pipe 61 and are ground and peeled in a segmented manner so as to improve the quality of the intermediate product.

A vibrating type material conveying device 65 is arranged below a finished product discharge port 64 of the middle section sorting roller screen 6, and the output end of the vibrating type material conveying device 65 is connected with a feeding port of a belt type conveying freezing box 7 which is used for quickly freezing the peeled frozen corn particles and is convenient for subsequent processing. The belt-type conveying freezer 7 is composed of a freezer body 67, a freezer conveyor belt 66 is arranged at the lower part of the inner side of the freezer body 67, a plurality of groups of refrigerators 77 (for example, H503CS-AL type refrigerators) arranged along the material conveying direction are arranged above the freezer conveyor belt 66 and at the upper part of the inner side of the freezer body 67; a frozen corn hopper 78 is arranged below the discharge hole of the belt-type conveying freezing box 7, and the bottom outlet of the frozen corn hopper 78 is connected with a bellows feed end 80 of a secondary flowing bellows 8 arranged above the secondary peeling device 9 through a conveying pipeline; the secondary flow windbox 8 is identical in structure to the primary flow windbox 2. The second-stage peeling device 9 comprises a plurality of groups (for example, two groups) of frozen corn grinding and peeling machines 19 which are arranged in parallel, a corn kernel feeding hopper 18 is arranged above a peeling feeding hopper 30 of the frozen corn grinding and peeling machines 19 and on a horizontal table top of the maintenance operation platform 15, a second-stage flowing air box 8 is arranged on one side above the corn kernel feeding hopper 18, and an air box discharging end 82 at the lower part of the second-stage flowing air box 8 is connected with an inlet of the corn kernel feeding hopper 18; and an air box air inducing port 81 on the side part of the second-stage flowing air box 8 is connected with a second-stage high-pressure induced draft fan 106, and an air outlet of the second-stage high-pressure induced draft fan 106 is connected with the flowing bran collector 23 through a pipeline. The flowing bran collector 23 is composed of a coarse bran collecting cyclone cylinder 24, the lower port of the coarse bran collecting cyclone cylinder 24 is connected with a coarse bran collecting cloth bag 26, and the upper port of the coarse bran collecting cyclone cylinder 24 is connected with a fine bran collecting cloth bag 27 through a ventilation cap cylinder 25.

The peeling discharge chutes 35 of the two groups of frozen corn grinding and peeling machines 19 of the secondary peeling device 9 are respectively connected with the secondary peeling collection hopper 107 below the secondary peeling device through the discharge chutes 20; the lower end of the secondary peeling collection hopper 107 is connected with the air box feed end 80 at the side part of the third-stage flow air box 10 through a conveying pipeline, and the structure of the third-stage flow air box 10 is the same as that of the first-stage flow air box 2. The discharge end of the third-stage flowing air box 10 is connected with a feed inlet of a third-stage peeling device 11, the third-stage peeling device 11 comprises a group of frozen corn grinding and peeling machines 19, and a corn kernel feed hopper 18 is arranged above a peeling feed hopper 30 of the frozen corn grinding and peeling machines 19 and on a horizontal table top of the maintenance operation platform 15; and the three-stage flowing air box 10 is arranged at one side above the corn kernel feeding hopper 18, and the air box discharging end 82 at the lower part of the three-stage flowing air box 10 is connected with the inlet of the corn kernel feeding hopper 18. And an air box induced draft port 81 on the side part of the third-stage flowing air box 10 is connected with a third-stage high-pressure induced draft fan 111, and an air outlet of the third-stage high-pressure induced draft fan 111 is connected with the flowing bran collector 23 through a pipeline. Meanwhile, a discharge port of the frozen corn grinding and peeling machine 19 of the third-stage peeling device 11 is provided with a cooling air curtain machine 108 for reducing the temperature of frozen corn particles and facilitating subsequent conveying. The lower end of the cooling cold air curtain machine 108 is provided with a receiving hopper box 109, a belt conveyor 110 is arranged below the receiving hopper box 109, the front end of the conveying direction of the belt conveyor 110 is connected with the lower end of a lifting conveyor 112, and the upper end of the lifting conveyor 112 is connected with a feeding port of the discharging sorting roller screen 12.

Further, the frozen corn particles at the discharge port of the belt-type conveying freezing box 7 are conveyed into a corn particle feeding hopper 18 above a secondary peeling device 9 by a conveying pipeline by a secondary flowing air box 8, and meanwhile, bran and chaff mixed in the frozen corn particles are separated out and are subjected to secondary grinding and peeling by a frozen corn grinding and peeling machine 19; the twice peeled frozen corn particles are then transported to a third stage flow windbox 10. Then, the frozen corn grains secondarily ground and peeled by the secondary peeling device 9 are conveyed into a corn grain feeding hopper 18 above the tertiary peeling device 11 through a conveying pipeline by using a tertiary flow air box 10, bran and chaff included in the frozen corn grains are separated, and then, the frozen corn grains are ground and peeled for the third time by using a frozen corn grinding and peeling machine 19 of the tertiary peeling device 11. Finally, the peeled frozen corn grains are ground again by the third-stage peeling device 11, cooled by the cooling air curtain machine 108 at the discharge port of the third-stage peeling device 11, dropped onto the belt conveyor 110 from the receiving hopper box 109, and then fed into the roller screen feeding pipe 61 of the discharge sorting roller screen 12 via the lifting conveyor 112. The discharging sorting roller screen 12 and the middle-section sorting roller screen 6 have the same structure, so that residual bran impurities in the frozen corn particles which enter the discharging sorting roller screen 12 through the roller screen feeding pipe 61 and are ground and peeled for three times are screened out in a segmented manner, and the quality of the finished products is further improved; and delivers the frozen corn particles uniformly onto a packaging line via a vibratory feed 65 beneath product outlet 64.

In order to intensively collect the frozen corn bran ground by the first-stage peeling device 3, the second-stage peeling device 9 and the third-stage peeling device 11, the bran powder discharge ports 38 of the frozen corn grinding and peeling machines 19 of each group of the first-stage peeling device 3 are respectively connected with the bran air inlet 92 of the first-stage bran collecting device 5 through a bran powder conveying pipeline 85; the bran powder discharge ports 38 of the frozen corn grinding and peeling machines 19 of the second-stage peeling device 9 and the third-stage peeling device 11 are respectively connected with a bran air inlet 92 of the last-stage bran collecting device 13 through a bran powder conveying pipeline 85. The first-stage bran collecting device 5 and the last-stage bran collecting device 13 are identical in structure and respectively comprise a bran cyclone collecting cylinder 86, the bran cyclone collecting cylinder 86 is composed of a cyclone collecting cylinder body 91 in an inverted cone shape, a bran wind inlet 92 is formed in one side of the upper portion of the cyclone collecting cylinder body 91, and a fine bran wind outlet 93 is formed in the upper portion of the bran wind inlet 92 and the upper end side portion of the cyclone collecting cylinder body 91. The cyclone collecting cylinder body 91 is internally and rotatably provided with wall scraping blades 96, and the wall scraping blades 96 are composed of a plurality of rotating sheet bodies 99 which are arranged on the middle wall scraping rotating shaft 95 at equal intervals along the circumference of a transverse section; the rotating sheet 99 is provided with a hollow part 100, and the lower end of the scraping wall rotating shaft 95 is provided with a blade support frame 101 for enhancing the rotating stability of the scraping wall blade 96. The upper end of the scraping wall rotating shaft 95 at the middle of the scraping wall blade 96 is connected to the driving end of the cyclone driving motor 94 at the upper end of the cyclone cylinder 91.

A closed discharge valve 97 is arranged at the discharge outlet at the lower end of the cyclone collecting cylinder body 91 of the first-stage bran collecting device 5 and the last-stage bran collecting device 13; the closed discharge valve 97 comprises a discharge valve body 102, the upper end of the discharge valve body 102 is provided with a valve body feeding port 103 which is connected with a discharge port at the lower end of the cyclone collecting cylinder 91, and the lower end of the discharge valve body 102 is provided with a valve body discharge port 104; and the inside of the discharge valve body 102 is rotatably provided with a closed rotating blade 105, and the rotating shaft of the closed rotating blade 105 is connected with the driving end of the discharge motor 98 arranged outside the discharge valve body 102. The bran air inlet 92 of the bran cyclone collecting cylinder 86 of the first-stage bran collecting device 5 and the last-stage bran collecting device 13 is respectively connected with the bran discharge port of the corresponding peeling device through a bran powder conveying pipeline 85, the fine bran air outlet 93 of the bran cyclone collecting cylinder 86 is respectively connected with the air inlet of a bran collecting induced draft fan 89 through a bran fine powder suction pipeline 88, and the exhaust port of the bran collecting induced draft fan 89 is connected with the pulse type bag dust collector 14 through an induced draft fan exhaust pipe 90. A bran conveyer belt 87 is arranged below the closed discharge valve 97 at the lower end of the bran cyclone collecting cylinder 86.

When the automatic peeling production line of the quick-frozen fresh corn kernels is used, firstly, frozen blocks of the fresh corn kernels, which are frozen for 8-10 hours in an environment of-40 ℃ to-30 ℃, are conveyed into a block-shaped frozen corn crusher 1 at an environment temperature of not higher than-5 ℃ (for example, -35 ℃ to-5 ℃); then, the frozen corn particles broken into small blocks by the block-shaped frozen corn crusher 1 are conveyed into the primary peeling device 3 by the primary flow wind box 2 through a conveying pipeline, and are ground and peeled by the grinding runner 46 of the frozen corn grinding and peeling machine 19 of the primary peeling device 3; meanwhile, the bran powder in the bran powder accumulation cavity 36 is pushed into the bran powder conveying pipeline 85 from the bran powder discharge port 38 by the bran powder pushing wheel 51 rotating along with the grinding wheel 46, and bran ground by the primary peeling device 3 is collected by the primary peeling device 5 and then is transported in a centralized manner by the bran conveyer 87. The frozen corn particles which are ground and peeled for the first time by the first-stage peeling device 3 fall into the primary peeling corn collecting hopper 21, the sorting flow bellows 4 conveys the frozen corn particles which are ground and peeled for the first time into the middle-section sorting roller screen 6 through the roller screen feeding pipe 61, and then residual bran mixed in the frozen corn particles which are ground and peeled are screened out in sections, so that the quality of intermediate products is improved.

Frozen corn particles screened from a finished product discharge port 64 of the middle-section sorting roller screen 6 enter the belt-type conveying freezing box 7 through the vibrating material conveying device 65 so as to quickly freeze the peeled frozen corn particles, ensure the stability of particle hardness and facilitate subsequent processing. Then, the frozen corn particles at the discharge port of the belt-type conveying freezing box 7 are conveyed into a secondary peeling device 9 by a conveying pipeline by a secondary flowing air box 8, and are subjected to secondary grinding and peeling by a frozen corn grinding and peeling machine 19 of the secondary peeling device 9. Then, the frozen corn particles which are secondarily ground and peeled by the secondary peeling device 9 are conveyed into the tertiary peeling device 11 by the third flowing wind box 10 through a conveying pipeline, and are further ground and peeled for the third time by the frozen corn grinding and peeling machine 19 of the tertiary peeling device 11. Meanwhile, the bran grinded by the second-stage peeling device 9 and the third-stage peeling device 11 is collected in a centralized manner by using the final-stage bran collecting device 13. Finally, the peeled frozen corn grains are ground again by the third-stage peeling device 11, cooled by the cooling air curtain machine 108 at the discharge port of the third-stage peeling device 11, and then dropped onto the belt conveyor 110 from the receiving hopper box 109, and then enters the discharge sorting roller screen 12 for screening by the lifting conveyor 112, thereby further improving the quality of the finished product. The frozen corn particles are uniformly transferred to a packaging line through a vibratory conveying device 65 below a finished product discharge port 64 of the discharge sorting roller screen 12.

Claims (10)

1. The utility model provides an automatic desquamation production line of bright kernel of corn of quick-freeze, includes one-level desquamation device (3), its characterized in that: a feeding port of the primary peeling device (3) is connected with a discharging end of the primary flowing air box (2), and a feeding end of the primary flowing air box (2) is connected with a discharging port of the block-shaped frozen corn crusher (1) through a conveying pipeline; the discharge port of the first-stage peeling device (3) is connected with the feed end of the separation flowing air box (4) through a conveying pipeline, the discharge end of the separation flowing air box (4) is connected with the feed port of the middle-stage separation roller screen (6), the discharge port of the middle-stage separation roller screen (6) is connected with the feed port of the belt-type conveying freezing box (7), the discharge port of the belt-type conveying freezing box (7) is connected with the feed end of the second-stage flowing air box (8) through a conveying pipeline, and the discharge end of the second-stage flowing air box (8) is connected with the feed port of the second-stage peeling device (9); a discharge port of the second-stage peeling device (9) is connected with a feed end of a third-stage flowing air box (10) through a conveying pipeline, a discharge end of the third-stage flowing air box (10) is connected with a feed port of a third-stage peeling device (11), and a discharge port of the third-stage peeling device (11) is connected with a feed port of a discharge sorting roller screen (12); the husk discharge gate of one-level peeling device (3) passes through pipeline and links to each other with first-stage husk collection device (5), the husk discharge gate of second grade peeling device (9) and tertiary peeling device (11) links to each other with last-stage husk collection device (13) through pipeline respectively, and the draught fan gas vent of first-stage husk collection device (5) and last-stage husk collection device (13) all links to each other with dust remover (14).

2. The automatic peeling production line of quick-frozen fresh corn kernels of claim 1, characterized in that: the primary peeling device (3) comprises a plurality of groups of frozen corn grinding and peeling machines (19) which are arranged in parallel, a corn kernel feeding hopper (18) is arranged above a feeding port of each frozen corn grinding and peeling machine (19), the primary flowing air box (2) is arranged on one side above the corn kernel feeding hopper (18), and a discharging end of the lower part of the primary flowing air box (2) is connected with an inlet of the corn kernel feeding hopper (18); an air inducing port at the side part of the primary flowing air box (2) is connected with a primary high-pressure induced draft fan (16), and an air outlet of the primary high-pressure induced draft fan (16) is connected with an ice chip collecting cloth bag (17) through a pipeline; the discharge port of the frozen corn grinding and peeling machine (19) is respectively connected with a primary peeled corn collecting hopper (21) below the frozen corn grinding and peeling machine through a discharge chute (20), the lower end of the primary peeled corn collecting hopper (21) is connected with the feed end of the side part of the separation flow air box (4) through a conveying pipeline, the air induction port on the other side of the separation flow air box (4) is connected with a separation high-pressure induced draft fan (22), and the air outlet of the separation high-pressure induced draft fan (22) is connected with a flow bran collector (23) through a pipeline; the flowing bran collector (23) is composed of a coarse bran collecting cyclone cylinder (24), the lower port of the coarse bran collecting cyclone cylinder (24) is connected with a coarse bran collecting cloth bag (26), and the upper port of the coarse bran collecting cyclone cylinder (24) is connected with a fine bran collecting cloth bag (27) through a ventilation cap cylinder (25).

3. The automatic peeling production line for quick-frozen fresh corn kernels of claim 2, characterized in that: the frozen corn grinding and peeling machine (19) comprises a peeling machine main body (28), a grinding cylinder (41) with an upper opening and a lower opening is fixedly arranged inside the peeling machine main body (28), a grinding rotating wheel (46) is rotationally arranged in a grinding and peeling cavity (45) of the grinding cylinder (41), a rotating vertical shaft (49) is arranged in the middle of the grinding rotating wheel (46), and the lower end of the rotating vertical shaft (49) is connected with an output shaft of a peeling driving motor (39) through a transmission mechanism (40); a conical upper cover (29) is arranged above the upper opening of the grinding cylinder (41), and a peeling feeding hopper (30) is arranged at the top of the conical upper cover (29); a ground corn dropping bin (52) is arranged below the lower opening of the grinding cylinder (41), and the bottom outlet of the ground corn dropping bin (52) is connected with a peeling discharge chute (35); a plurality of bran powder leakage nets (42) which are circumferentially arranged along the transverse section of the grinding cylinder (41) are arranged on the vertical cylinder wall, the lower part of the outer side of each bran powder leakage net (42) is communicated with a bran powder accumulation cavity (36) below the peeling machine main body (28) through a bran powder lower leakage opening (43), a bran powder stirring and conveying cavity (37) is arranged at the lower part of the bran powder accumulation cavity (36), and a bran powder discharge opening (38) is formed in the side wall of the bran powder stirring and conveying cavity (37); a bran powder shifting wheel (51) is rotatably arranged in the bran powder shifting cavity (37), an arc shifting wheel blade (58) is arranged on the bran powder shifting wheel (51), and a rotating shaft in the middle of the bran powder shifting wheel (51) is coaxially connected with a rotating vertical shaft (49) of the grinding rotating wheel (46).

4. The automatic peeling production line of the quick-frozen fresh corn kernels of claim 3, characterized in that: the grinding rotating wheel (46) is composed of a cylindrical rotating wheel main body (53), and a wheel body cavity (56) is arranged in the cylindrical rotating wheel main body (53); the upper end of the cylindrical rotating wheel main body (53) is provided with a rotating wheel upper cover (54), the middle part of the rotating wheel upper cover (54) is provided with a vertical shaft through hole (57), the lower end of the cylindrical rotating wheel main body (53) is provided with a rotating wheel lower cover (55), and the middle part of the rotating wheel lower cover (55) is also provided with a vertical shaft through hole (57); the rotating vertical shaft (49) passes through the cylindrical rotating wheel main body (53) of the whole grinding rotating wheel (46) through vertical shaft through holes (57) on the rotating wheel upper cover (54) and the rotating wheel lower cover (55).

5. The automatic peeling production line of the quick-frozen fresh corn kernels of claim 3, characterized in that: a plurality of groups of grinding rubber blocks (48) which are arranged at equal intervals along the circumference of the transverse section of the cylinder body are arranged on the inner side wall of the grinding cylinder (41), and each group of grinding rubber blocks (48) are respectively connected with a guide sliding hole on the vertical cylinder wall of the grinding cylinder (41) in a sliding manner through a guide inserting column (47) which is horizontally arranged; the grinding rubber block (48) is also connected with a rubber block adjusting bolt (33) penetrating through the cylinder wall of the grinding cylinder (41), the front end of the rubber block adjusting bolt (33) is connected with the middle part of the grinding rubber block (48), and an adjusting part at the rear end of the rubber block adjusting bolt (33) is positioned outside the peeling machine main body (28).

6. The automatic peeling production line of quick-frozen fresh corn kernels of claim 1, characterized in that: the middle section sorting roller screen (6) and the discharging sorting roller screen (12) are identical in structure and respectively comprise a roller screen main body (59), a sectional roller screen cylinder (68) is rotatably arranged in the roller screen main body (59), the driving end of the sectional roller screen cylinder (68) is connected with an output shaft of a roller screen driving motor (60) on the outer side of one end of the roller screen main body (59), and the inlet of the sectional roller screen cylinder (68) is connected with a roller screen feeding pipe (61) on the other end of the roller screen main body (59); the material conveying device is characterized in that a fine grain discharge port (62), a coarse grain discharge port (63) and a finished product discharge port (64) are sequentially arranged at the lower part of the roller screen main body (59) along the conveying direction of materials in the sectional roller screen cylinder (68), and a vibrating material conveying device (65) is arranged below the finished product discharge port (64).

7. The automatic peeling production line of quick-frozen fresh corn kernels of claim 1, characterized in that: the structure of the primary flowing air box (2), the structure of the sorting flowing air box (4), the structure of the secondary flowing air box (8) and the structure of the tertiary flowing air box (10) are the same, the primary flowing air box, the sorting flowing air box and the secondary flowing air box all comprise inverted triangular air box main bodies (79), air box feeding ends (80) and air box air inducing openings (81) are respectively arranged on two sides of the upper portion of the air box main bodies (79), and air box discharging ends (82) are arranged on the lower portion of the; and a material guide inclined plane (84) is arranged at one side of the interior of the air box main body (79) close to the feeding end (80) of the air box, and an arc-shaped material guide plate (83) is arranged at the upper part of the other side of the interior of the air box main body (79) and below an air box air guide opening (81).

8. The automatic peeling production line of quick-frozen fresh corn kernels of claim 1, characterized in that: the first-stage bran collecting device (5) and the last-stage bran collecting device (13) are identical in structure and respectively comprise a bran cyclone collecting cylinder (86), the bran cyclone collecting cylinder (86) is composed of a cyclone collecting cylinder body (91), a bran wind inlet (92) is formed in one side of the upper part of the cyclone collecting cylinder body (91), and a fine bran wind outlet (93) is formed in the upper part of the bran wind inlet (92) and the side part of the upper end of the cyclone collecting cylinder body (91); a wall scraping blade (96) is rotatably arranged in the cyclone collecting cylinder body (91), and the upper end of a wall scraping rotating shaft (95) in the middle of the wall scraping blade (96) is connected with the driving end of a cyclone driving motor (94) at the upper end of the cyclone collecting cylinder body (91); a closed discharge valve (97) is arranged at a discharge port at the lower end of the cyclone collecting cylinder body (91); a bran air inlet (92) of a bran cyclone collecting cylinder (86) of the first-stage bran collecting device (5) and the last-stage bran collecting device (13) is respectively connected with a bran discharge port of a corresponding peeling device through a bran powder conveying pipeline (85), a fine bran air outlet (93) of the bran cyclone collecting cylinder (86) is respectively connected with an air inlet of a bran collection draught fan (89) through a bran fine powder suction pipeline (88), and an exhaust port of the bran collection draught fan (89) is connected with a dust remover (14) through a draught fan exhaust pipe (90); a bran conveyer belt (87) is arranged below the closed discharge valve (97) at the lower end of the bran cyclone collecting cylinder (86).

9. The automatic peeling production line of quick-frozen fresh corn kernels of claim 1, characterized in that: the second-stage peeling device (9) comprises a plurality of groups of frozen corn grinding and peeling machines (19) which are arranged in parallel, a corn kernel feeding hopper (18) is arranged above a feeding port of each frozen corn grinding and peeling machine (19), the second-stage flowing air box (8) is arranged on one side above the corn kernel feeding hopper (18), and the discharging end of the lower part of the second-stage flowing air box (8) is connected with an inlet of the corn kernel feeding hopper (18); an induced draft port on the side part of the secondary flow air box (8) is connected with a secondary high-pressure induced draft fan (106), the feed end of the secondary flow air box (8) is connected with the discharge port of the belt-type conveying freezing box (7) through a conveying pipeline, and the air outlet of the secondary high-pressure induced draft fan (106) is connected with a flow bran collector (23) through a pipeline; the flowing bran collector (23) is composed of a coarse bran collecting cyclone cylinder (24), the lower port of the coarse bran collecting cyclone cylinder (24) is connected with a coarse bran collecting cloth bag (26), and the upper port of the coarse bran collecting cyclone cylinder (24) is connected with a fine bran collecting cloth bag (27) through a ventilation cap cylinder (25); the discharge hole of the frozen corn grinding and peeling machine (19) is respectively connected with a secondary peeling and collecting hopper (107) below the frozen corn grinding and peeling machine through a discharge chute (20), and the lower end of the secondary peeling and collecting hopper (107) is connected with the feed end of the side part of the third-stage flowing air box (10) through a conveying pipeline.

10. The automatic peeling production line for quick-frozen fresh corn kernels of claim 9, characterized in that: the three-stage peeling device (11) comprises a plurality of groups of frozen corn grinding and peeling machines (19) which are arranged in parallel, a corn kernel feeding hopper (18) is arranged above a feeding port of each frozen corn grinding and peeling machine (19), the three-stage flowing air box (10) is arranged on one side above the corn kernel feeding hopper (18), and the discharging end of the lower part of the three-stage flowing air box (10) is connected with an inlet of the corn kernel feeding hopper (18); an induced draft port on the side part of the third-stage flowing air box (10) is connected with a third-stage high-pressure induced draft fan (111), the feed end of the third-stage flowing air box (10) is connected with the lower end of the secondary peeling aggregate hopper (107) through a conveying pipeline, and the air outlet of the third-stage high-pressure induced draft fan (111) is connected with a flowing bran collector (23) through a pipeline; the frozen corn grinding and peeling machine is characterized in that a cooling air curtain machine (108) is arranged at a discharge port of the frozen corn grinding and peeling machine (19), a receiving hopper box (109) is arranged at the lower end of the cooling air curtain machine (108), a belt conveyor (110) is arranged below the receiving hopper box (109), the front portion of the belt conveyor (110) is connected with the lower end of a lifting conveyor (112), and the upper end of the lifting conveyor (112) is connected with a feed port of a discharge sorting roller screen (12).

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