CN111642766A

CN111642766A - Be applied to dewatering subassembly of vegetables surface dehydration

Info

Publication number: CN111642766A
Application number: CN202010505933.1A
Authority: CN
Inventors: 不公告发明人
Original assignee: Anhui Shuojing Electromechanical Design Service Co ltd
Current assignee: Anhui Shuojing Electromechanical Design Service Co ltd
Priority date: 2020-06-05
Filing date: 2020-06-05
Publication date: 2020-09-11

Abstract

The invention provides a water removal assembly applied to vegetable surface dehydration, which comprises a feeding funnel (110), a conveying mechanism (120), a guide mechanism (130) and a water removal mechanism (140), wherein the conveying mechanism (120) is used for receiving root vegetables which are guided by the feeding funnel (110) to fall and conveying the root vegetables to the guide mechanism (130), the guide mechanism (130) is used for guiding the output of the root vegetables and enabling the root vegetables to complete primary water removal treatment in the output process, and the water removal mechanism (140) is used for carrying out surface air drying treatment on the root vegetables in the process that the guide mechanism (130) guides the root vegetables; it can carry out the surface dewatering to rhizome class vegetables automatically and handle, and among the dewatering treatment process, the reciprocating drive component operation drives the transmission pipeline/air-out branch pipeline/fly leaf three in the dewatering component and carries out reciprocating motion along the direction of guidance of sliding guide part to the wind-force that makes the dewatering component provide evenly distributed in connecting the shell, the air-dry effect is better.

Description

Be applied to dewatering subassembly of vegetables surface dehydration

Technical Field

The invention relates to the field of food processing, in particular to a root vegetable surface dewatering assembly.

Background

The root vegetables mainly refer to edible parts which are roots or stems, such as potatoes, sweet potatoes, radishes and the like, the outer surfaces of the root vegetables are adhered with soil after being collected, workers need to clean the root vegetables for subsequent processing, a large amount of water drops are remained on the surfaces of the root vegetables after being cleaned, generally, the root vegetables are placed in a vegetable basket for standing for a period of time for draining water, but the method can not completely remove water on the surfaces of the root vegetables, the root vegetables are good in family life, when large canteens such as schools and factories work, the water drops remained on the surfaces of the root vegetables can make food processing environments moist and the moist environments can easily cause bacterial growth, in addition, the water on the surfaces of the root vegetables can also cause serious influences on storage of the root vegetables, such as germination and mildew, and the like, therefore, the invention needs to provide a device for removing water on the surfaces of the root vegetables, the equipment can automatically perform surface dewatering treatment on the root vegetables, is not only suitable for surface dewatering of the root vegetables before storage, but also suitable for surface dewatering treatment of the root vegetables after being cleaned in a canteen, and has wider applicability; in the primary dewatering treatment process, two modes of draining and primary air drying are adopted to be matched, so that the dewatering effect is better; in the secondary air drying treatment process, the wind guide plate can enable wind force to be in uniform contact with the surfaces of the root vegetables, the buffer component can prevent the root vegetables from colliding with the wall of the air drying shell cavity and being damaged, and the dehumidifying component can dehumidify humid gas generated in the secondary air drying treatment process.

Disclosure of Invention

In order to solve the defects of the prior art, the invention aims to provide a root vegetable surface dewatering assembly which can automatically perform surface dewatering treatment on root vegetables, wherein the dewatering treatment also comprises primary dewatering treatment and secondary air drying treatment, and the surface dewatering effect of the root vegetables is better when the primary dewatering treatment and the secondary air drying treatment are matched; in the primary dewatering treatment process, two modes of draining and primary air drying are adopted to be matched, so that the dewatering effect is better; in the secondary air drying treatment process, the wind guide plate can enable wind force to be in uniform contact with the surfaces of the root vegetables, the buffer component can prevent the root vegetables from colliding with the wall of the air drying shell cavity and being damaged, and the dehumidifying component can dehumidify humid gas generated in the secondary air drying treatment process.

In order to achieve the technical purpose, the technical scheme adopted by the invention is as follows.

Be applied to dewatering subassembly of vegetables surface dehydration, it includes feed hopper (110), conveying mechanism (120), guiding mechanism (130), dewatering mechanism (140), conveying mechanism (120) are used for receiving root class vegetables that feed hopper (110) guide dropped and carry it to guiding mechanism (130) on, guiding mechanism (130) are used for guiding root class vegetables output and make root class vegetables accomplish preliminary waterlogging caused by excessive rainfall at output process and handle, dewatering mechanism (140) are used for carrying out the air-dry processing of surface at guiding mechanism (130) guide root class vegetables's in-process.

The technical scheme is further improved and optimized.

The guide mechanism (130) comprises a connecting shell (131), a guide net rack (132), a drainage cylinder (133) and a guide cylinder (134), the connecting shell (131) comprises a bottom plate and a baffle plate, the bottom plate can be divided into two parts which are respectively a guide section and a connecting section, the connecting section is horizontally arranged, the guide section is obliquely arranged, the bottom end of the guide section is fixedly connected with the end part of the connecting section, the baffle plate is vertically fixed on the upper end surface of the bottom plate, the large surface of the baffle plate is vertical to the width direction of the bottom plate, and the baffle plate is provided with two groups and is respectively positioned on one side of the bottom plate along the width direction of the baffle;

the guide net rack (132) is fixedly arranged between the two groups of baffles of the connecting shell (131), the guide net rack (132) is close to the bottom plate of the connecting shell (131), and the guide net rack (132) can be divided into two parts along the extending direction of the guide net rack (132) and is respectively a traction section positioned above the guide section of the bottom plate of the connecting shell (131) and a feeding section positioned above the connecting section of the bottom plate;

the bottom plate linkage segment of connecting shell (131) set up the apopore that runs through its thickness, a drain section of thick bamboo (133) be vertical arrange and both ends open-ended rectangle tube structure from top to bottom to fixed connection switches on between the upper end of a drain section of thick bamboo (133) and the lower drill way of apopore, a guide section of thick bamboo (134) arrange and both ends open-ended tube structure from top to bottom for the slope, fixed connection switches on between the upper end of a guide section of thick bamboo (134) and the lower open end of a drain section of thick bamboo (133).

The technical scheme is further improved and optimized.

An air inlet hole (1311) penetrating through the thickness of the baffle is formed in one group of baffles connected with the shell (131), the guide direction of the air inlet hole (1311) is parallel to the guide direction of the bottom plate guide section connected with the shell (131), an air outlet hole (1312) is formed in the other group of baffles connected with the shell (131), and a blocking net (1313) used for preventing root vegetables from falling out is arranged in the air outlet hole (1312);

the water removing mechanism (140) comprises a water removing member (1410), the water removing member (1410) comprises a first air blower (1411), a main connecting pipe (1412), a transmission pipeline (1413), an air outlet pipeline (1414) and a movable plate (1415), the transmission pipeline (1413) is of a pipeline structure which is hollow inside and has an extension direction parallel to the guide direction of the bottom plate guide section of the connecting shell (131), a sliding guide part is arranged between the upper end surface of the transmission pipeline (1413) and the bottom plate bottom surface of the connecting shell (131), and the transmission pipeline (1413) and the bottom plate bottom surface of the connecting shell (131) are movably connected through the sliding guide part;

the movable plate (1415) is movably arranged in the air inlet hole (1311) and forms sliding guide fit, the movable plate (1415) is provided with a mounting hole penetrating through the thickness of the movable plate, the bottom of the transfer pipeline (1413) is provided with an air inlet connector (1413 b) communicated with an inner cavity of the transfer pipeline, and the side part of the transfer pipeline (1413) close to the air inlet hole (1311) is provided with an air outlet connector (1413 c) communicated with the inner cavity of the transfer pipeline;

the main connecting pipeline (1412) is of a hose structure, one end of the main connecting pipeline (1412) is fixedly connected and communicated with the air outlet end of the first air blower (1411), and the other end of the main connecting pipeline (1412) is fixedly connected and communicated with an air inlet connector (1413 b) arranged at the bottom of the transfer pipeline (1413);

the air outlet branch pipeline (1414) is of a hard pipeline structure, one end of the air outlet branch pipeline (1414) is fixedly connected and communicated with an air outlet connector (1413 c) arranged on the side portion of the transfer pipeline (1413), the other end of the air outlet branch pipeline is positioned in a mounting hole arranged on the movable plate (1415) and fixedly connected with the air outlet connector (1413 c), a plurality of groups are arranged in the air outlet branch pipeline (1414) along the extending direction array of the movable plate (1415), and the air outlet connector (1413 c) arranged on the side portion of the transfer pipeline (1413) and the mounting hole arranged on the movable plate (1415) are uniformly and correspondingly provided with a plurality of groups.

The technical scheme is further improved and optimized.

The sliding guide component comprises an installation bulge (1413 a) arranged on the upper end surface of the transmission pipeline (1413) and an installation sliding chute arranged on the bottom surface of the bottom plate of the connecting shell (131), and the installation bulge (1413 a) is movably connected with the installation sliding chute to form sliding guide fit with the guide direction parallel to the extension direction of the transmission pipeline (1413).

The technical scheme is further improved and optimized.

The water removing mechanism (140) further comprises a reciprocating driving member (1420), wherein the reciprocating driving member (1420) is used for driving the transmission pipe (1413)/the air outlet pipe (1414)/the movable plate (1415) to reciprocate along the guiding direction of the sliding guide component;

the bottom end of the transmission pipeline (1413) is provided with a connecting bulge (1413 d), the reciprocating driving component (1420) comprises a driving motor (1421), a first linkage rod (1422) and a second linkage rod (1423), the axial direction of an output shaft of the driving motor (1421) is parallel to the width direction of the transmission pipeline (1413), the bottom of a bottom plate connecting section of the connecting shell (131) is provided with a fastening plate, and the driving motor (1421) is fixedly installed on the fastening plate;

the extending directions of the first linkage rod (1422) and the second linkage rod (1423) are parallel to the length direction of the transmission pipeline (1413), one end of the first linkage rod (1422) is fixedly connected with the power output end of the driving motor (1421), the other end of the first linkage rod (1422) is hinged with one end of the second linkage rod (1423), the other end of the second linkage rod (1423) is hinged with a connecting protrusion (1413 d) arranged at the bottom end of the transmission pipeline (1413), the axial direction of a hinge shaft formed at the hinged position between the first linkage rod (1422) and the second linkage rod (1423) is parallel to the axial direction of an output shaft of the driving motor (1421), and the axial direction of the hinge shaft formed at the hinged position between the second linkage rod (1423) and the connecting protrusion (1413 d) is parallel to the axial direction of the output shaft of the driving motor (1421).

The technical scheme is further improved and optimized.

The conveying mechanism (120) comprises an installation shell (1210), a conveying member (1220) and a power member (1230), wherein the installation shell (1210) comprises an installation plate and vertical plates, the installation plate is horizontally arranged, the vertical plates are vertically arranged, the bottom ends of the vertical plates are fixedly connected with the side surfaces of the installation plate, three groups of vertical plates are arranged on the vertical plates, discharge notches are formed among the three groups of vertical plates, and the discharge notches of the installation shell (1210) are fixedly connected with the top end of a connection shell (131) of the guide mechanism (130);

the conveying member (1220) is used for receiving the dropping root vegetables guided by the feeding hopper (110) and conveying the dropping root vegetables to the guide mechanism (130), and the power member (1230) is used for providing power for the operation of the conveying member (1220).

The technical scheme is further improved and optimized.

The conveying member (1220) comprises conveying rollers (1221) and a conveying belt (1222), the axial direction of the conveying rollers (1221) is parallel to the width direction of the connecting shell (131), the conveying rollers (1221) are movably mounted in the mounting shell (1210) and can rotate around the axial direction of the conveying rollers, the conveying rollers (1221) are provided with two groups, one group of conveying rollers (1221) is arranged at the discharging notch of the mounting shell (1210), the other group of conveying rollers (1221) is close to a vertical plate of the mounting shell (1210) and far away from the discharging notch of the conveying rollers, and the two groups of conveying rollers (1221) are located in the same horizontal plane;

the conveying belt (1222) is arranged between two groups of conveying rollers (1221), a traction convex plate (1223) is arranged on the outer surface of the conveying belt (1222), and a plurality of groups of traction convex plates (1223) are arranged in an array mode along the extending direction of the conveying belt (1222);

the feeding hopper (110) is fixedly arranged at the top end of the vertical plate of the mounting shell (1210), and the feeding hopper (110) is also positioned right above the feeding end of the conveying member (1220).

The technical scheme is further improved and optimized.

The power member (1230) comprises a conveying motor (1231) and a power transmission piece (1232), the axial direction of an output shaft of the conveying motor (1231) is parallel to the axial direction of the conveying roller (1221), the conveying motor (1231) is fixedly installed at the bottom of the installation shell (1210), and the power transmission piece (1232) is arranged between the power output end of the conveying motor (1231) and the power input end of the conveying roller (1221) located at the discharging notch of the installation shell (1210) and used for power connection and transmission between the power output end and the power input end.

The technical scheme is further improved and optimized.

The power transmission piece (1232) is of a belt transmission structure.

Compared with the prior art, the method has the advantages that the method can automatically perform surface water removal treatment on the root vegetables, the water removal treatment also comprises primary water removal treatment and secondary air drying treatment, and the surface water removal effect of the root vegetables is better when the primary water removal treatment and the secondary air drying treatment are matched; in the primary dewatering treatment process, the reciprocating driving component operates and drives the transmission pipeline/air outlet pipeline/movable plate in the dewatering component to reciprocate along the guiding direction of the sliding guide component, so that the wind power provided by the dewatering component is uniformly distributed in the connecting shell, and the air drying effect is better; in the secondary air drying treatment process, the setting of aviation baffle can make the wind that blows into in the air-dry shell through the blast air connector be broken up and evenly blow to the net rack that draws, it is better to make root class vegetables surface air-dry effect, buffering subassembly set up can prevent that root class vegetables from passing through the feed port when carrying in to the air-dry shell and air-dry between the shell cavity wall and bump and receive the damage, the setting of dehumidification component can carry out dehumidification to the humid gas that produces in the secondary air drying treatment process, prevent that humid gas from discharging to increase the ambient humidity in the external environment.

Drawings

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

FIG. 2 is a schematic structural diagram of a primary water removal device according to the present invention.

Fig. 3 is a schematic structural diagram of the conveying mechanism of the present invention.

Fig. 4 is a schematic structural view of a conveying member and a power member of the present invention.

Fig. 5 is a schematic structural view of the guide mechanism of the present invention.

Fig. 6 is a schematic structural view of the joint housing and the drain cylinder of the present invention.

Fig. 7 is a partial cross-sectional view of the connection housing and drain cartridge of the present invention.

FIG. 8 is a schematic structural diagram of a connecting housing and a water removing mechanism according to the present invention.

FIG. 9 is a schematic structural diagram of a water removing mechanism according to the present invention.

FIG. 10 is a schematic structural diagram of a water removing member according to the present invention.

Fig. 11 is a schematic structural view of a transfer pipe of the present invention.

FIG. 12 is a schematic view of the reciprocating drive member and transfer conduit of the present invention.

Fig. 13 is a schematic structural view of the secondary air drying device of the present invention.

Fig. 14 is a schematic structural view of the secondary air drying device of the present invention.

Fig. 15 is a schematic structural view of an airing member of the present invention.

Fig. 16 is a schematic view of the internal structure of the seasoning member of the present invention.

FIG. 17 is a schematic view of a cushion assembly according to the present invention.

Fig. 18 is a schematic structural view of a dehumidifying member of the present invention.

Fig. 19 is a schematic view of the structure of the refrigeration assembly of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and the protection scope of the present invention is not limited thereby.

The utility model provides a rhizome class vegetables surface removes water machine, it includes one-level water trap 100, the second grade air-dries device 200 and installs in ground and fixed connection between the discharge end of one-level water trap 100 and the feed end that the device 200 was air-dried to the second grade, one-level water trap 100 is used for carrying out the surface dewatering to rhizome class vegetables such as potato carrot and handles and carry the rhizome class vegetables guide after the dewatering to the second grade air-dries device 200 in, the second grade air-dries device 200 and is used for guiding the output of rhizome class vegetables and carries out further surface air-drying processing to rhizome class vegetables at the output process.

The secondary air drying device 200 comprises a base 210, an air drying member 220, a second blower 230 and a storage tank 250, wherein the base 210 is horizontally arranged on the ground, the air drying member 220 is used for receiving the root vegetables subjected to surface water removal by the primary water removal device 100 and guiding the root vegetables into the storage tank 250, and the second blower 230 is used for further performing surface air drying treatment on the root vegetables in the guiding output process of the root vegetables in the air drying member 220.

The air-drying member 220 comprises an air-drying shell 221 and a traction net rack 222, wherein the air-drying shell 221 is of a rectangular shell structure with openings at the upper end and the lower end, the lower opening end of the air-drying shell 221 is fixedly connected with the base 210, a feeding hole 2211 penetrating through the wall thickness of the air-drying shell 221 is formed in the side surface of the air-drying shell 221, the feeding hole 2211 is close to the upper opening end of the air-drying shell 221, an air blowing nozzle 2212 connected with the inner cavity of the air-drying shell 221 is further formed in the side surface of the air-drying shell 221 provided with the feeding hole 2211, and.

The side of the air drying shell 221 parallel to and far from the aperture of the feeding hole 2211 is provided with a discharging cylinder 2213, the discharging cylinder 2213 is a rectangular shell structure with openings at two ends, one opening end of the discharging cylinder 2213 is fixedly connected with the side of the air drying shell 221, the other opening end is a discharging end, and the discharging cylinder 2213 is further positioned between the feeding hole 2211 and the blowing nozzle 2212.

The traction net rack 222 is fixedly arranged in the air drying shell 221, concretely, the traction net rack 222 can be divided into two parts and respectively is an inclined section and a horizontal section, the top end of the inclined section and the wall of the air drying shell 221, which is provided with the feeding hole 2211, are fixedly connected, and the top end of the inclined section is also positioned between the feeding hole 2211 and the discharging cylinder 2213, the bottom end of the inclined section is positioned in the discharging cylinder 2213, the bottom end of the inclined section is also close to the lower cavity wall of the discharging cylinder 2213, the horizontal section is horizontally arranged, one end of the horizontal section is fixedly connected with the bottom end of the inclined section, and the other end of the horizontal section and the end face of the discharging end of the discharging cylinder 221.

The storage box 250 is fixedly mounted on the base 210 and the storage box 250 is also positioned right below the discharge end of the discharge cylinder 2213.

The second blower 230 is fixedly mounted on the base 210, and the air outlet end of the second blower 230 is fixedly connected and communicated with the air blowing nozzle 2212.

The working process of the secondary air drying device 200 is specifically as follows: the rhizome class vegetables after the surface dewatering of one-level water trap 100 can be carried to air-dry shell 221 in through feed port 2211 in, subsequently, the rhizome class vegetables can drop to pull on the rack 222 and drop to storage tank 250 in through the guide of pulling the rack 222, and this in-process, the operation of second air-blower 230 and to the interior blowing of air-dry shell 221, and then reach the purpose of carrying out the air-dry processing of surface to the rhizome class vegetables.

More preferably, the air deflector 223 is further disposed on the cavity wall of the air drying casing 221 provided with the air blowing nozzle 2212, the air deflector 223 is obliquely disposed, the bottom end of the air deflector 223 is fixedly connected to the cavity wall of the air drying casing 221 provided with the air blowing nozzle 2212, the bottom end of the air deflector 223 and the bottom surface of the air blowing nozzle 2212 are located at the same height, and the top end of the air deflector 223 is close to the lower cavity wall of the discharge cylinder 2213; due to the arrangement of the air deflector 223, air blown into the air drying shell 221 through the air blowing nozzle 2212 can be dispersed and uniformly blown to the traction net rack 222, so that the surface air drying effect of the root vegetables is better.

More preferably, in order to prevent the root vegetables from colliding with and being damaged by the wall of the air drying casing 221 provided with the discharge cylinder 2213 when the root vegetables are conveyed into the air drying casing 221 through the feed hole 2211, the wall of the air drying casing 221 provided with the discharge cylinder 2213 is further provided with a buffer component 224, and the buffer component 224 is opposite to the feed hole 2211 and is used for preventing the root vegetables from colliding with the wall of the air drying casing 221.

Buffer unit 224 include guide bar 2241, buffer board 2242, buffer spring 2243, the extending direction of guide bar 2241 is on a parallel with the axial of feed port 2211, the chamber wall that air-dry shell 221 is provided with out feed cylinder 2213 still is provided with the guide hole that runs through its wall thickness, guide bar 2241 movable sleeve is located in the guide hole and is constituted the slip guide cooperation, the one end of guide bar 2241 is located air-dry shell 221 for stiff end and this end, the other end is outside for spacing end and this end is located air-dry shell 221, the spacing end of guide bar 2241 is provided with the bolt.

Preferably, the guide rods 2241 are provided with four groups, four groups of guide rods 2241 are distributed in a four-point manner, and four groups of guide holes are correspondingly provided.

Buffer board 2242 be the rectangular plate body structure that the big face is on a parallel with feed port 2211 drill way, fixed connection between buffer board 2242 and the stiff end of guide bar 2241, preferably, buffer board 2242 is provided with the cushion layer of being made by rubber materials towards the big face of feed port 2211.

Buffer spring 2243 cover locate the guide bar 2241 outside, buffer spring 2243's one end is contradicted with buffer board 2242, the other end is contradicted with the chamber wall that air-dries shell 221 and be provided with feed cylinder 2213, buffer spring 2243's elasticity orders about buffer board 2242 and is close to the motion of feed port 2211, buffer spring 2243 one-to-one is provided with four groups.

The working process of the buffer assembly 224 is specifically as follows: in-process that rhizome class vegetables were carried to air-dry in the shell 221 through feed port 2211, the contact can take place for root class vegetables and buffer board 2242, under buffer spring 2243 and the cooperation of cushion layer, root class vegetables can not cause the damage because of the collision.

More specifically, the wind provided by the second air blower 230 is exhausted from the upper opening end of the air drying casing 221 after drying the root vegetables, that is, the moisture mixed with the moisture is exhausted into the external environment through the air drying casing 221, which increases the humidity of the surrounding environment, not only reduces the service life of the device, but also makes the surface of the root vegetables have water drops again, and for this reason, the upper opening end of the air drying casing 221 is also provided with a dehumidifying member 240 for dehumidifying the humid gas in a matching manner.

The dehumidifying component 240 includes a guiding end cover 241, an exhaust duct 242, a fixed casing 243, and a refrigerating assembly, wherein the guiding end cover 241 is a rectangular platform structure with openings at the upper and lower ends, the horizontal cross-sectional area of the guiding end cover 241 decreases progressively from bottom to top along the direction perpendicular to the ground, and the lower opening end of the guiding end cover 241 is fixedly connected and communicated with the upper opening end of the air drying casing 221.

The exhaust duct 242 may be divided into two parts, which are respectively a first exhaust section and a second exhaust section arranged vertically, one end of the first exhaust section is fixedly connected to the upper opening end of the guide end cover 241, and the other end of the first exhaust section is fixedly connected to the top end of the second exhaust section.

The fixed casing 243 is a shell structure with openings at the upper and lower ends, the upper opening end of the fixed casing 243 is fixedly connected and communicated with the two bottom ends of the exhaust section of the exhaust duct 242, and the side surface of the fixed casing 243 is provided with a through hole penetrating the wall thickness of the fixed casing 243.

The refrigeration assembly comprises a cooling fin group 244, cooling fins and a cooling fan 246, one end of the cooling fin group 244 is located in the fixed shell 243, the other end of the cooling fin group 244 penetrates through a through hole formed in the side face of the fixed shell 243 and is located outside the fixed shell 243, specifically, the cooling fin group 244 comprises a cooling plate and a plurality of groups of cooling fins, the cooling plate is of a plate body structure with a large surface parallel to a through hole orifice, the cooling fins are of an arc-shaped sheet structure, the axial direction of the cooling fins is parallel to the axial direction of the through hole, the cooling fins are fixedly connected with the cooling plate along one axial end of the cooling fins, and the other end of the cooling fins penetrates through the through hole and is parallel to the fixed shell.

One surface of the refrigerating sheet is a heat absorption surface, the other surface of the refrigerating sheet is a heat dissipation surface, the heat absorption surface of the refrigerating sheet is fixedly connected with the cooling plate and used for reducing the temperature of the cooling sheet set 244, and the heat dissipation surface of the refrigerating sheet is provided with a heat dissipation fan 246 used for performing heat dissipation treatment on the heat dissipation surface of the refrigerating sheet; the refrigeration piece is the prior art, and the description thereof is not repeated too much.

Preferably, in order to make the heat dissipation effect of the heat dissipation fan 246 on the cooling surface of the cooling fins better, a heat conduction plate group 245 is arranged between the heat dissipation fan 246 and the cooling surface of the cooling fins, and the heat conduction plate group 245 is connected between the heat dissipation fan 246 and the cooling surface of the cooling fins; while the heat of the cooling surface of the cooling fin is transferred to the heat conducting fin set 245, the heat conducting fin set 245 is cooled by the cooling fan 246, and the contact area between the heat conducting fin set 245 and the air is large, so that the heat of the cooling surface of the cooling fin is dissipated quickly.

The operation process of the dehumidifying component 240 is embodied as follows: after the root vegetables are air-dried by the wind provided by the second air blower 230, the humid air mixed by the wind and the moisture is discharged outwards through the guide end cover 241, the exhaust duct 242 and the fixed shell 243 in sequence, wherein when the humid air passes through the fixed shell 243, the refrigeration assembly can condense the water vapor into liquid and discharge the liquid, and the purpose of reducing the humidity in the discharged air is achieved.

One-level water trap 100 include feed hopper 110, conveying mechanism 120, guiding mechanism 130, dewatering mechanism 140, conveying mechanism 120 is used for receiving the rhizome class vegetables that feed hopper 110 guide dropped and carry it to guiding mechanism 130 on, guiding mechanism 130 is used for guiding rhizome class vegetables to roll to second grade air-dry device 200 in and make rhizome class vegetables accomplish preliminary waterlogging caused by excessive rainfall processing at the roll in-process, dewatering mechanism 140 is used for carrying out the preliminary air-dry processing in surface to it at guiding mechanism 130 guide rhizome class vegetables's in-process.

Guide mechanism 130 including connecting shell 131, guide net rack 132, a water drainage tube 133, a guide tube 134, connecting shell 131 includes the bottom plate, the baffle, the bottom plate can be divided into two parts and be the guide section respectively, the linkage segment is the level and arranges, fixed connection and linkage segment up end lie in same height with pore wall under the feed hole 2211 between the linkage segment and the side that air-dry shell 221 is provided with feed hole 2211, the guide section is the slope and arranges and the bottom of guide section keeps away from fixed connection between the tip of air-drying shell 221 with the linkage segment, the vertical width direction that is fixed in the bottom plate up end and the big face perpendicular to bottom plate of baffle, the baffle be provided with two sets of and lie in the bottom plate respectively along one side of self width direction.

The guiding net rack 132 is fixedly installed between two sets of baffles connected with the shell 131 and the guiding net rack 132 is close to the bottom plate connected with the shell 131, and the guiding net rack 132 can be divided into two parts along the extending direction of the guiding net rack 132 and is respectively a traction section above the bottom plate guiding section connected with the shell 131 and a feeding section above the bottom plate connecting section.

The bottom plate linkage segment of connecting shell 131 set up the apopore that runs through its thickness and the apopore is close to and air-dries shell 221, a drain section of thick bamboo 133 be vertical arrange and both ends open-ended rectangle tube structure from top to bottom to fixed connection switches on between the upper end of a drain section of thick bamboo 133 and the lower drill way of apopore, a guide section of thick bamboo 134 for slope arrange and both ends open-ended tube structure from top to bottom, fixed connection switches on between the upper end of a guide section of thick bamboo 134 and the lower open end of a drain section of thick bamboo 133.

The operation process of the guiding mechanism 130 is specifically as follows: conveying mechanism 120 receives the rhizome class vegetables in feed hopper 110 and carries it to on the top of guiding mechanism 130, afterwards, the root class vegetables guide through guiding mechanism 130's guide rack 132 and pass feed port 2211 and finally drop to air-dry in the shell 221, and in this process, the water that root class vegetables drove out loops through the apopore, a drainage tube 133, a guide tube 134 discharges, and simultaneously, dewatering mechanism 140 still carries out the preliminary air-dry processing in surface to root class vegetables through the air-dry mode.

An air inlet hole 1311 penetrating the thickness of the baffle is formed in one group of baffles connected with the outer shell 131, the guide direction of the air inlet hole 1311 is parallel to the guide direction of the bottom plate guide section connected with the outer shell 131, an air outlet hole 1312 is formed in the other group of baffles connected with the outer shell 131, and preferably, a blocking net 1313 used for preventing root vegetables from falling out is arranged in the air outlet hole 1312.

The water removing mechanism 140 includes a water removing member 1410, the water removing member 1410 includes a first blower 1411, a main connecting pipe 1412, a transmitting pipe 1413, a branch outlet pipe 1414 and a movable plate 1415, the transmitting pipe 1413 is a pipe structure with an internal hollow structure and an extending direction parallel to the guiding direction of the bottom plate guiding section of the connecting shell 131, a sliding guiding member is arranged between the upper end surface of the transmitting pipe 1413 and the bottom plate bottom surface of the connecting shell 131, and the sliding guiding member is movably connected with the bottom plate bottom surface of the connecting shell 131 through the sliding guiding member, specifically, the sliding guiding member includes an installation protrusion 1413a arranged on the upper end surface of the transmitting pipe 1413 and an installation chute arranged on the bottom plate bottom surface of the connecting shell 131, and the installation protrusion 1413a and the installation chute are movably connected with each other and form a sliding guiding direction parallel to the.

The movable plate 1415 is movably installed in the air inlet hole 1311 and forms sliding guide fit, a mounting hole penetrating the thickness of the movable plate 1415 is formed in the movable plate 1415, an air inlet connector 1413b communicated with an inner cavity of the transmission pipeline 1413 is arranged at the bottom of the transmission pipeline 1413, and an air outlet connector 1413c communicated with the inner cavity of the transmission pipeline 1413 is arranged on the side portion, close to the air inlet hole 1311, of the transmission pipeline 1413.

The side surface of the air drying shell 221 provided with the feeding hole 2211 is also horizontally and fixedly provided with a bearing plate, the bearing plate is positioned below the guide mechanism 130, and the first blower 1411 is fixedly installed on the bearing plate.

The main connecting pipe 1412 is of a hose structure, one end of the main connecting pipe 1412 is fixedly connected and communicated with the air outlet end of the first blower 1411, and the other end of the main connecting pipe 1412 is fixedly connected and communicated with an air inlet nozzle 1413b arranged at the bottom of the transfer pipe 1413.

The air outlet branch pipe 1414 is of a hard pipe structure, one end of the air outlet branch pipe 1414 is fixedly connected and communicated with an air outlet connector 1413c arranged on the side portion of the transfer pipe 1413, the other end of the air outlet branch pipe 1414 is positioned in a mounting hole arranged on the movable plate 1415 and is fixedly connected with the air outlet connector 1413c, preferably, the air outlet branch pipe 1414 is provided with a plurality of groups in an array mode along the extension direction of the movable plate 1415, and the air outlet connector 1413c arranged on the side portion of the transfer pipe 1413 and the mounting hole arranged on the movable plate 1415 are uniformly and correspondingly provided with a plurality of groups.

The operation of the water removal unit 1410 is as follows: in the process that the guiding mechanism 130 guides the root vegetables to roll, wind power provided by the first air blower 1411 is blown into the connecting shell 131 through the main connecting pipeline 1412, the delivery pipeline 1413 and the air outlet pipeline 1414, and then primary surface air drying treatment is carried out on the root vegetables.

More specifically, in order to make the water removing member 1410 perform the preliminary surface air drying treatment on the root vegetables, the water removing mechanism 140 further includes a reciprocating driving member 1420, and the reciprocating driving member 1420 is used to drive the three of the delivery pipe 1413/the air outlet pipe 1414/the movable plate 1415 to reciprocate along the guiding direction of the sliding guide.

The bottom end of the transmission pipeline 1413 is provided with a connecting protrusion 1413d, the reciprocating driving member 1420 comprises a driving motor 1421, a first linkage bar 1422 and a second linkage bar 1423, the axial direction of the output shaft of the driving motor 1421 is parallel to the width direction of the transmission pipeline 1413, the bottom of the bottom plate connecting section of the connecting shell 131 is provided with a fastening plate, and the driving motor 1421 is fixedly mounted on the fastening plate.

The extending directions of the first linkage bar 1422 and the second linkage bar 1423 are both parallel to the length direction of the transmission pipeline 1413, one end of the first linkage bar 1422 is fixedly connected with the power output end of the driving motor 1421, the other end of the first linkage bar 1422 is hinged with one end of the second linkage bar 1423, the other end of the second linkage bar 1423 is hinged with the connecting protrusion 1413d arranged at the bottom end of the transmission pipeline 1413, the axial direction of a hinge shaft formed at the hinged position between the first linkage bar 1422 and the second linkage bar 1423 is parallel to the axial direction of the output shaft of the driving motor 1421, and the axial direction of a hinge shaft formed at the hinged position between the second linkage bar 1423 and the connecting protrusion 1413d is parallel to the axial direction of the output shaft of the driving.

The operation of the reciprocating drive member 1420 is embodied as: the driving motor 1421 operates and drives the transmission duct 1413/the air outlet duct 1414/the movable plate 1415 to reciprocate along the guiding direction of the sliding guiding component by the cooperation of the first linkage 1422 and the second linkage 1423, so that the wind provided by the water removing member 1410 is uniformly distributed in the connecting housing 131, and the air drying effect is better.

Conveying mechanism 120 including installation shell 1210, conveying member 1220, power component 1230, installation shell 1210 includes mounting panel, vertical board, the mounting panel is the level and arranges, vertical board is vertical and fixed connection between the side of board and the vertical board bottom, vertical board is provided with three groups and is formed with the ejection of compact breach between three groups of vertical boards, fixed connection between the ejection of compact breach of installation shell 1210 and the top of guiding mechanism 130's connection shell 131.

Conveying member 1220 be used for receiving the rhizome class vegetables that feed hopper 110 guide dropped and carry it to guiding mechanism 130 on, conveying member 1220 includes conveying roller 1221, conveyer belt 1222, conveying roller 1221's axial is on a parallel with the width direction who connects shell 131, conveying roller 1221 movable mounting is in installation shell 1210 and can wind self axial rotation, conveying roller 1221 is provided with two sets and a set of conveying roller 1221 sets up in the ejection of compact breach department of installation shell 1210, another set of conveying roller 1221 is close to the vertical board that installation shell 1210 kept away from self ejection of compact breach, two sets of conveying roller 1221 are located coplanar.

The conveying belt 1222 is disposed between two sets of conveying rollers 1221, a traction protruding plate 1223 is disposed on the outer surface of the conveying belt 1222, and the traction protruding plate 1223 is disposed in several sets in an array along the extending direction of the conveying belt 1222.

The feed hopper 110 is fixedly mounted to the top end of the vertical plate of the mounting housing 1210, and the feed hopper 110 is also positioned directly above the feed end of the transport member 1220.

The power member 1230 is used for providing power for the operation of the conveying member 1220, the power member 1230 includes a conveying motor 1231 and a power transmission member 1232, the axial direction of the output shaft of the conveying motor 1231 is parallel to the axial direction of the conveying roller 1221, and the conveying motor 1231 is fixedly installed at the bottom of the installation shell 1210, the power transmission member 1232 is arranged between the power output end of the conveying motor 1231 and the power input end of the conveying roller 1221 at the discharging notch of the installation shell 1210 and used for power connection and transmission between the power output end and the power input end, specifically, the power transmission member 1232 is a belt transmission structure.

The working process of the conveying mechanism 120 is specifically as follows: the root vegetables in the feeding hopper 110 fall to the feeding end of the conveying member 1220, and at the same time, the power member 1230 drives the conveying member 1220 to operate, and the traction protruding plate 1223 disposed on the surface of the conveying belt 1222 pulls the root vegetables to be conveyed toward the guiding mechanism 130, and the root vegetables are finally conveyed into the guiding mechanism 130.

In actual operation, the root vegetables in the feeding hopper 110 fall to the feeding end of the conveying member 1220, meanwhile, the power member 1230 drives the conveying member 1220 to operate, the traction protruding plate 1223 arranged on the surface of the conveying belt 1222 pulls the root vegetables to be conveyed towards the guiding mechanism 130, and the root vegetables are finally conveyed to the top end of the guiding mechanism 130;

then, the root vegetables are guided by the guide net rack 132 of the guide mechanism 130 and roll towards the direction of the air drying shell 221, in the rolling process, water drained from the root vegetables is discharged through the water outlet hole, the water discharging cylinder 133 and the guide cylinder 134 in sequence, and meanwhile, the driving motor 1421 and the first air blower 1411 are matched to run and carry out surface primary air drying treatment on the root vegetables in an air drying mode;

the rhizome class vegetables are finally carried to air-dry in the shell 221 through feed port 2211 in, afterwards, the rhizome class vegetables can drop to pull on the rack 222 and drop to storage tank 250 in the guide of rack 222, in this process, the operation of second air-blower 230 is bloied to air-dry shell 221 is inside, and then reach the purpose of carrying out the further air-dry processing on the surface to the rhizome class vegetables, simultaneously, the wind that second air-blower 230 provided air-dries the rhizome class vegetables after, the moist gas that wind and moisture mix passes through guide end cover 241, exhaust pipe 242, fixed shell 243 outwards discharges in proper order, wherein when fixed shell 243 is being passed through, refrigerating assembly can make the steam condensation be liquid and discharge, and then reach the purpose that reduces humidity in the exhaust gas.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the technical principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims

1. Be applied to dewatering subassembly of vegetables surface dehydration, characterized in that, it includes feed hopper (110), conveying mechanism (120), guiding mechanism (130), dewatering mechanism (140), conveying mechanism (120) are used for receiving feed hopper (110) guide the rhizome class vegetables that drop and carry it to guiding mechanism (130) on, guiding mechanism (130) are used for guiding the output of rhizome class vegetables and make rhizome class vegetables accomplish preliminary waterlogging caused by excessive rainfall processing at output process, dewatering mechanism (140) are used for carrying out the air-dry processing of surface to it at guiding mechanism (130) guide in-process of rhizome class vegetables.

2. The water removal assembly applied to vegetable surface dehydration of claim 1, characterized in that said guiding mechanism (130) comprises a connecting shell (131), a guiding net rack (132), a drainage cylinder (133), a guiding cylinder (134), said connecting shell (131) comprises a bottom plate and a baffle plate, said bottom plate can be divided into two parts and respectively comprises a guiding section and a connecting section, said connecting section is horizontally arranged, said guiding section is obliquely arranged and the bottom end of said guiding section is fixedly connected with the end of said connecting section, said baffle plate is vertically fixed on the upper end surface of said bottom plate and the large surface of said baffle plate is perpendicular to the width direction of said bottom plate, said baffle plate is provided with two groups and respectively located on one side of said bottom plate along the width direction thereof;

3. The water removal assembly applied to vegetable surface dehydration of claim 2, characterized in that one set of baffles of said connection housing (131) is provided with air inlet holes (1311) passing through the thickness thereof, and the direction of the air inlet holes (1311) is parallel to the direction of the guide section of the bottom plate of the connection housing (131), the other set of baffles of the connection housing (131) is provided with air outlet holes (1312), and the air outlet holes (1312) are provided with a blocking net (1313) for preventing root vegetables from falling out;

4. The water removing assembly applied to vegetable surface dehydration as claimed in claim 3, characterized in that said sliding guiding component comprises a mounting protrusion (1413 a) arranged on the upper end surface of the transferring pipe (1413), a mounting chute arranged on the bottom surface of the bottom plate of the connecting shell (131), the mounting protrusion (1413 a) and the mounting chute are movably connected and form a sliding guiding fit with a guiding direction parallel to the extending direction of the transferring pipe (1413).

5. The assembly of claim 3, wherein the de-watering mechanism (140) further comprises a reciprocating driving member (1420), the reciprocating driving member (1420) is used to drive the three of the delivery pipe (1413)/the air outlet pipe (1414)/the movable plate (1415) to reciprocate along the guiding direction of the sliding guide;

6. The water removal assembly applied to vegetable surface dehydration of any one of the claims 2-5, characterized in that said conveying mechanism (120) comprises a mounting housing (1210), a conveying member (1220), a power member (1230), said mounting housing (1210) comprises a mounting plate and a vertical plate, said mounting plate is horizontally arranged, said vertical plate is vertically arranged and the bottom end of said vertical plate is fixedly connected with the side surface of said mounting plate, said vertical plate is provided with three sets of vertical plates, and discharging notches are formed between said three sets of vertical plates, said discharging notches of said mounting housing (1210) are fixedly connected with the top end of said connecting housing (131) of said guiding mechanism (130);

7. The water removal assembly applied to vegetable surface dehydration of claim 6, characterized in that said conveying member (1220) comprises conveying rollers (1221) and a conveying belt (1222), the axial direction of the conveying rollers (1221) is parallel to the width direction of the connecting housing (131), the conveying rollers (1221) are movably installed in the mounting housing (1210) and can rotate around the axial direction of the conveying rollers, the conveying rollers (1221) are provided with two sets, one set of the conveying rollers (1221) is arranged at the discharging gap of the mounting housing (1210), the other set of the conveying rollers (1221) is close to the vertical plate of the mounting housing (1210) far away from the discharging gap, and the two sets of the conveying rollers (1221) are located in the same horizontal plane;

8. The water removal assembly applied to vegetable surface dehydration of claim 7, characterized in that said power member (1230) comprises a transmission motor (1231), a power transmission member (1232), the output shaft of the transmission motor (1231) is axially parallel to the axial direction of the transmission roller (1221) and the transmission motor (1231) is fixedly installed at the bottom of the installation housing (1210), the power transmission member (1232) is installed between the power output end of the transmission motor (1231) and the power input end of the transmission roller (1221) at the discharging gap of the installation housing (1210) and is used for power connection and transmission therebetween.

9. The assembly of claim 8, wherein the power transmission member (1232) is a belt transmission structure.