CN109892675B

CN109892675B - Vegetable dehydrator

Info

Publication number: CN109892675B
Application number: CN201910275860.9A
Authority: CN
Inventors: 黄学玲
Original assignee: Guangxi Rongshui County Furongbei Jiangyuan Agricultural Development Co ltd
Current assignee: Guangxi Rongshui County Furongbei Jiangyuan Agricultural Development Co.,Ltd.
Priority date: 2019-04-08
Filing date: 2019-04-08
Publication date: 2020-11-06
Anticipated expiration: 2039-04-08
Also published as: CN109892675A

Abstract

The invention relates to the field of dehydration devices, in particular to a vegetable dehydrator, which comprises a base, a squeezing driver, a continuous squeezing carrier and an intermittent conveyor, wherein the front end of the squeezing driver is fixedly connected to the base; the vegetable squeezing and dewatering device has the advantages that the transported vegetables can be continuously and automatically squeezed and dewatered, the efficiency of dewatering the batches of vegetables is high, the dewatering speed is high, and further the dewatering quality of a large number of vegetables is guaranteed.

Description

Vegetable dehydrator

Technical Field

The invention relates to the field of dehydration devices, in particular to a vegetable dehydrator.

Background

Patent No. CN201410782334.9 discloses an automatic dewatering device for vegetables, which comprises a dewatering machine, wherein the dewatering machine comprises a frame and a dewatering barrel. Automatic dewatering device of vegetables blows in the air in can be to the clearance between dewatering barrel and the inner bag bucket through the mouth of blowing mainly, the apopore that makes the air pass through the inner bag bucket blows in inside the inner bag bucket, blow down vegetables on the inner bag bucket inner wall automatically, can be with the vegetables complete clean in the hydroextractor, avoid long-time remaining, prevent to breed the bacterium and cause the pollution, high work efficiency, prevent that vegetables are damaged, the integrality of vegetables has been guaranteed, the article looks of vegetables product has been improved, the position that the mouth of blowing set up mainly makes the air of blowing in touch inner bag bucket diapire earlier or the inner wall of bucket, make the air current form the torrent, increase air velocity, guarantee to blow into the air of inner bag bucket through the apopore can hang down vegetables automatically. But this equipment can't realize the vegetables and dewater in succession, and work efficiency is low.

Disclosure of Invention

The invention aims to provide a vegetable dehydrator which has the advantages that conveyed vegetables can be continuously and automatically squeezed and dehydrated, the efficiency of dehydrating batches of vegetables is high, the dehydration speed is high, and the dehydration quality of a large amount of vegetables is further guaranteed.

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

the invention aims to provide a vegetable dehydrator which comprises a base, a squeezing driver, a continuous squeezing bearing device and an intermittent conveyor, wherein the front end of the squeezing driver is fixedly connected onto the base, the upper end of the squeezing driver is connected into the base in a sliding mode, the rear end of the squeezing driver is connected with the continuous squeezing bearing device through meshing transmission, the continuous squeezing bearing device is connected onto the base in a rotating mode, the lower end of the squeezing driver is connected with the intermittent conveyor through meshing transmission, and the intermittent conveyor is communicated with the squeezing driver.

As a further optimization of the invention, the base comprises a bottom plate, a side plate, a front plate, an upper plate, two sliding seats, two T-shaped sliding grooves, a feeding pipe fixing hole, a baffle sliding groove, a left fixing plate, a rear fixing plate, a front fixing plate and a rotating round hole, wherein the side plate and the front plate are respectively fixedly connected to the left end and the front end of the bottom plate, the upper plate is fixedly connected to the side plate and the front plate, the upper ends of the two sliding seats are respectively fixedly connected to the lower end of the upper plate, the two T-shaped sliding grooves are respectively arranged at the inner ends of the two sliding seats, the feeding pipe fixing hole penetrates through the side plate from left to right, the baffle sliding groove is arranged at the right end of the side plate, the baffle sliding groove is communicated with the feeding pipe fixing hole, the left fixing plate, the rear.

As a further optimization of the invention, the squeezing driver comprises a servo motor, a master gear, a master hinge post, a hinge rod, a slave hinge post, a connecting rod, an upper sliding fixing plate, a squeezing hammer and two T-shaped sliding blocks, wherein the servo motor is fixedly connected to the front plate, the master gear is fixedly connected to a transmission shaft of the servo motor, the master hinge post is fixedly connected to an eccentric part at the rear end of the master gear, two ends of the hinge rod are respectively hinged to the master hinge post and the slave hinge post, the slave hinge post is fixedly connected to the lower end of the connecting rod, the upper end of the connecting rod is fixedly connected to the front end of the upper sliding fixing plate, the two T-shaped sliding blocks are respectively fixedly connected to the left end and the right end of the upper sliding fixing plate, the two T-shaped sliding blocks are respectively slidably connected to the two T.

As a further optimization of the invention, the squeezing driver also comprises a lower gear, a lower rotating shaft, a half fan driving gear and a main bevel gear, wherein the upper end of the lower gear is in meshed transmission with the main gear, the lower gear and the main bevel gear are both fixedly connected on the lower rotating shaft, the half fan driving gear is fixedly connected at the rear end of the lower rotating shaft, and the lower rotating shaft is rotatably connected in the front plate and the rotating circular hole.

As a further optimization of the invention, the continuous squeezing bearing device comprises a bearing rotating shaft, a bearing driving gear, a rotating round seat, a water flow diversion groove and a plurality of bearing devices, wherein two ends of the bearing rotating shaft are respectively and rotatably connected in a rear fixing plate and a front fixing plate, the bearing driving gear is fixedly connected on the bearing rotating shaft, the lower end of the bearing driving gear is meshed with the half-fan driving gear for transmission, the rotating round seat is fixedly connected at the middle end of the bearing rotating shaft, the water flow diversion groove is arranged at the middle end of the outer wall of the rotating round seat, and the plurality of bearing devices are uniformly and fixedly connected on the rotating round seat.

As a further optimization of the invention, the plurality of carriers are arranged, each carrier comprises a fixed shaft, a fixed connecting plate, fixed bearing plates, a fixed bottom shaft, a vegetable dehydration extrusion cylinder, a water flow through hole and a filter plate, the fixed shaft is fixedly connected in the rotary round seat, the two fixed connecting plates are respectively and fixedly connected at two ends of the fixed shaft, the three fixed bearing plates are fixedly connected between the two fixed connecting plates from top to bottom, the fixed bottom shafts are fixedly connected at the middle ends of the three fixed bearing plates, the vegetable dehydration extrusion cylinder is fixedly connected at the upper end of the fixed bottom shaft, the water flow through hole vertically penetrates through the vegetable dehydration extrusion cylinder and the middle ends of the fixed bottom shafts, and the filter plate is fixedly connected at the upper side of the inner.

As a further optimization of the invention, the intermittent conveyor comprises a vegetable conveying pipe, a lower opening, a sliding baffle plate, a driving block, a cam, a left rotating shaft, an upper belt wheel, a lower belt wheel, a connecting rod, a driven bevel gear and a side fixing shaft, wherein the vegetable conveying pipe is fixedly connected in a fixing hole of a feeding pipe, the lower opening is arranged on the vegetable conveying pipe, the lower opening is communicated with a baffle plate sliding chute, the sliding baffle plate is slidably connected in the lower opening and the baffle plate sliding chute, the right end of the sliding baffle plate is fixedly connected with the driving block, the lower end of the driving block is slidably connected on the cam, the cam and the upper belt wheel are both fixedly connected on the left rotating shaft, two ends of the left rotating shaft are respectively rotatably connected in a side plate and a left fixing plate, the upper belt wheel is connected with the lower belt wheel through a belt, the lower belt, the four connecting rods are fixedly connected between the lower belt pulley and the driven bevel gear.

As a further optimization of the invention, the extrusion hammer is in clearance fit in the vegetable dehydration extrusion cylinder.

As a further optimization of the invention, the water flow through holes are communicated with the water flow drainage grooves.

As a further optimization of the invention, the vegetable conveying pipe is communicated with the vegetable dewatering squeezing barrel.

Compared with the prior art, the technical scheme provided by the invention has the beneficial effects that the base, the squeezing driver, the continuous squeezing carrier and the intermittent conveyor can continuously and automatically squeeze and dewater the transported vegetables, the efficiency of dewatering the batches of vegetables is high, the dewatering speed is high, and further the dewatering quality of a large amount of vegetables is ensured.

Drawings

FIG. 1 is a first general structural diagram of the present invention;

FIG. 2 is a second overall structural schematic of the present invention;

FIG. 3 is a schematic structural view of the base of the present invention;

FIG. 4 is a schematic view of the construction of the press drive of the present invention;

FIG. 5 is a schematic view of the construction of the continuous press carrier of the present invention;

FIG. 6 is a schematic view of the construction of the carrier of the present invention;

FIG. 7 is a schematic cross-sectional view of the carrier of the present invention;

fig. 8 is a schematic view of the intermittent conveyor structure of the present invention.

In the figure: a base 1; a bottom plate 1-1; side plates 1-2; a front panel 1-3; an upper plate 1-4; 1-5 of a sliding seat; 1-6 of T-shaped chutes; 1-7 feed pipe fixing holes; 1-8 baffle chutes; 1-9 parts of a left fixing plate; 1-10 parts of a rear fixing plate; front fixing plates 1-11; rotating the round holes 1-12; a press driver 2; a servo motor 2-1; a main gear 2-2; a main hinge column 2-3; hinge rods 2-4; from hinge columns 2-5; 2-6 of a connecting rod; an upper sliding fixing plate 2-7; 2-8 of T-shaped slide blocks; 2-9 parts of an extrusion hammer; 2-10 parts of a lower gear; 2-11 parts of a lower rotating shaft; half fan drive gears 2-12; 2-13 parts of a main bevel gear; a continuous press carrier 3; bearing a rotating shaft 3-1; a carrier drive gear 3-2; rotating the round seat by 3-3; 3-4 parts of a water flow drainage groove; a carrier 3-5; 3-5-1 parts of a fixed shaft; 3-5-2 of a fixed connecting plate; fixing a bearing plate 3-5-3; 3-5-4 of a fixed bottom shaft; 3-5-5 parts of a vegetable dehydration extrusion cylinder; 3-5-6 parts of a water through hole; 3-5-7 parts of a filter plate; an intermittent conveyor 4; 4-1 of a vegetable conveying pipe; a lower opening 4-2; 4-3 of a sliding baffle plate; a drive block 4-4; 4-5 of a cam; 4-6 parts of a left rotating shaft; 4-7 of an upper belt wheel; 4-8 parts of a lower belt pulley; 4-9 of a connecting rod; the driven bevel gears 4-10; side fixed shafts 4-11.

Detailed Description

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

The fixed connection in the device can be fixed by welding, thread fixing and the like, the rotary connection can be realized by baking the bearing on a shaft, a spring retainer groove or an inter-shaft baffle is arranged on the shaft or a shaft hole, the axial fixation of the bearing is realized by clamping an elastic retainer ring in the spring retainer groove or the inter-shaft baffle, and the rotation is realized by the relative sliding of the bearing; different connection modes are used in combination with different use environments.

The first embodiment is as follows:

as shown in fig. 1-8, a vegetable dehydrator comprises a base 1, a squeezing driver 2, a continuous squeezing carrier 3 and an intermittent conveyor 4, wherein the front end of the squeezing driver 2 is fixedly connected to the base 1, the upper end of the squeezing driver 2 is slidably connected in the base 1, the rear end of the squeezing driver 2 is connected with the continuous squeezing carrier 3 through meshing transmission, the continuous squeezing carrier 3 is rotatably connected to the base 1, the lower end of the squeezing driver 2 is connected with the intermittent conveyor 4 through meshing transmission, and the intermittent conveyor 4 is communicated with the squeezing driver 2. Through 4 intermittent type nature of intermittent type conveyer to squeezing the carrier 3 in succession transportation vegetables, squeeze the dehydration to squeezing the vegetables of carrier 3 in succession automatically through squeezing driver 2 in succession, and then reduce the vegetables moisture content.

The second embodiment is as follows:

as shown in fig. 1 to 8, the first embodiment is further described in the present embodiment, the base 1 includes a bottom plate 1-1, a side plate 1-2, a front plate 1-3, an upper plate 1-4, two sliding seats 1-5, two T-shaped sliding chutes 1-6, feed pipe fixing holes 1-7, baffle sliding chutes 1-8, left fixing plates 1-9, rear fixing plates 1-10, front fixing plates 1-11, and rotating round holes 1-12, the side plate 1-2 and the front plate 1-3 are respectively fixedly connected to the left end and the front end of the bottom plate 1-1, the upper plate 1-4 is fixedly connected to the side plate 1-2 and the front plate 1-3, the upper ends of the two sliding seats 1-5 are respectively fixedly connected to the lower ends of the upper plate 1-4, the two T-shaped sliding chutes 1-6 are respectively disposed at the inner ends of the two sliding seats 1-5, the left and right feed pipe fixing holes 1-7 are arranged on the side plates 1-2 in a penetrating mode, the baffle sliding grooves 1-8 are arranged at the right ends of the side plates 1-2, the baffle sliding grooves 1-8 are communicated with the feed pipe fixing holes 1-7, the left fixing plate 1-9, the rear fixing plate 1-10 and the front fixing plate 1-11 are fixedly connected to the bottom plate 1-1, and the rotating round holes 1-12 are arranged on the front fixing plate 1-11 in a penetrating mode.

The third concrete implementation mode:

as shown in fig. 1 to 8, the second embodiment is further explained in the present embodiment, the squeezing driver 2 includes a servo motor 2-1, a main gear 2-2, a main hinge post 2-3, a hinge rod 2-4, a slave hinge post 2-5, a connecting rod 2-6, an upper sliding fixing plate 2-7, a squeezing hammer 2-9 and two T-shaped sliders 2-8, the servo motor 2-1 is fixedly connected to the front plate 1-3, the main gear 2-2 is fixedly connected to a transmission shaft of the servo motor 2-1, the main hinge post 2-3 is fixedly connected to an eccentric position at the rear end of the main gear 2-2, two ends of the hinge rod 2-4 are respectively hinged to the main hinge post 2-3 and the slave hinge post 2-5, the slave hinge post 2-5 is fixedly connected to the lower end of the connecting rod 2-6, the upper end of the connecting rod 2-6 is fixedly connected with the front end of the upper sliding fixing plate 2-7, the two T-shaped sliding blocks 2-8 are respectively and fixedly connected with the left end and the right end of the upper sliding fixing plate 2-7, the two T-shaped sliding blocks 2-8 are respectively and slidably connected in the two T-shaped sliding chutes 1-6, and the extrusion hammer 2-9 is fixedly connected with the rear side of the lower end of the upper sliding fixing plate 2-7. The servo motor 2-1 drives the main gear 2-2 and the main hinge column 2-3 to rotate, and further drives the connecting rod 2-6 to reciprocate up and down through the hinge rod 2-4 and the auxiliary hinge column 2-5, so that the upper sliding fixing plate 2-7 and the extrusion hammer 2-9 slide in the two T-shaped sliding grooves 1-6 through the two T-shaped sliding blocks 2-8, and further drives the upper sliding fixing plate 2-7 and the extrusion hammer 2-9 to reciprocate up and down.

The fourth concrete implementation mode:

as shown in fig. 1 to 8, the third embodiment is further described in the present embodiment, the squeezing driver 2 further includes a lower gear 2-10, a lower rotating shaft 2-11, a half-fan driving gear 2-12 and a main bevel gear 2-13, the upper end of the lower gear 2-10 is in meshing transmission with the main gear 2-2, the lower gear 2-10 and the main bevel gear 2-13 are both fixedly connected to the lower rotating shaft 2-11, the half-fan driving gear 2-12 is fixedly connected to the rear end of the lower rotating shaft 2-11, and the lower rotating shaft 2-11 is rotatably connected to the front plate 1-3 and the rotating circular hole 1-12. The rotating main gear 2-2 simultaneously drives the lower gear 2-10 to rotate, thereby rotating the lower shaft 2-11, the half fan drive gear 2-12 and the main bevel gear 2-13.

The fifth concrete implementation mode:

as shown in fig. 1 to 8, in the present embodiment, to further explain the fourth embodiment, the continuous press carrier 3 includes a carrier rotating shaft 3-1, a carrier driving gear 3-2, the rotary round seat comprises a rotary round seat 3-3, a water flow drainage groove 3-4 and a plurality of load carriers 3-5, wherein two ends of a load-bearing rotary shaft 3-1 are respectively and rotatably connected into a rear fixing plate 1-10 and a front fixing plate 1-11, a load-bearing driving gear 3-2 is fixedly connected onto the load-bearing rotary shaft 3-1, the lower end of the load-bearing driving gear 3-2 is in meshed transmission with a half-fan driving gear 2-12, the rotary round seat 3-3 is fixedly connected at the middle end of the load-bearing rotary shaft 3-1, the water flow drainage groove 3-4 is arranged at the middle end of the outer wall of the rotary round seat 3-3, and the plurality of load carriers 3-5 are uniformly and fixedly connected onto. The rotary half-fan driving gear 2-12 drives the bearing driving gear 3-2 and the bearing rotating shaft 3-1 to periodically and intermittently rotate, so that the rotating round seat 3-3, the water flow drainage groove 3-4 and the plurality of bearings 3-5 periodically and intermittently rotate.

The sixth specific implementation mode:

as shown in figures 1 to 8, the fifth embodiment is further illustrated in the present embodiment, the plurality of carriers 3-5 are provided, the carrier 3-5 comprises a fixed shaft 3-5-1, a fixed connection plate 3-5-2, a fixed bearing plate 3-5-3, a fixed bottom shaft 3-5-4, a vegetable dehydration extrusion cylinder 3-5-5, a water through hole 3-5-6 and a filter plate 3-5-7, the fixed shaft 3-5-1 is fixedly connected in the rotating circular base 3-3, two fixed connection plates 3-5-2 are respectively and fixedly connected at two ends of the fixed shaft 3-5-1, three fixed bearing plates 3-5-3 are fixedly connected between the two fixed connection plates 3-5-2 from top to bottom, the fixed bottom shaft 3-5-4 is fixedly connected with the middle ends of the three fixed bearing plates 3-5-3, the vegetable dehydration extrusion cylinder 3-5-5 is fixedly connected with the upper end of the fixed bottom shaft 3-5-4, the water flow through hole 3-5-6 vertically penetrates through the middle ends of the vegetable dehydration extrusion cylinder 3-5-5 and the fixed bottom shaft 3-5-4, and the filter plate 3-5-7 is fixedly connected with the upper side of the inner wall of the water flow through hole 3-5-6.

The seventh embodiment:

as shown in fig. 1 to 8, in the sixth embodiment, the intermittent conveyor 4 further includes a vegetable conveying pipe 4-1, a lower opening 4-2, a sliding baffle 4-3, a driving block 4-4, a cam 4-5, a left rotating shaft 4-6, an upper belt pulley 4-7, a lower belt pulley 4-8, a connecting rod 4-9, a driven bevel gear 4-10 and a side fixing shaft 4-11, the vegetable conveying pipe 4-1 is fixedly connected in a feeding pipe fixing hole 1-7, the lower opening 4-2 is arranged on the vegetable conveying pipe 4-1, the lower opening 4-2 is communicated with the baffle sliding chute 1-8, the sliding baffle 4-3 is slidably connected in the lower opening 4-2 and the baffle sliding chute 1-8, the right end of the sliding baffle 4-3 is fixedly connected with the driving block 4-4, the lower end of a driving block 4-4 is connected to a cam 4-5 in a sliding mode, the cam 4-5 and an upper belt pulley 4-7 are fixedly connected to a left rotating shaft 4-6, two ends of the left rotating shaft 4-6 are respectively connected into a side plate 1-2 and a left fixing plate 1-9 in a rotating mode, the upper belt pulley 4-7 is connected with a lower belt pulley 4-8 through belt transmission, the lower belt pulley 4-8 and a driven bevel gear 4-10 are respectively and fixedly connected to a side fixing shaft 4-11, the side fixing shaft 4-11 is fixedly connected to the right end of the side plate 1-2, and four connecting rods 4-9 are respectively and fixedly connected between the lower belt pulley 4-8 and the driven bevel gear 4-10. The rotating main bevel gear 2-13 drives the driven bevel gear 4-10 to rotate, and then the lower belt pulley 4-8, the upper belt pulley 4-7, the left rotating shaft 4-6 and the cam 4-5 are driven to rotate through the four connecting rods 4-9, the rotating cam 4-5 drives the driving block 4-4 and the sliding baffle 4-3 to move up and down in a reciprocating manner, and therefore vegetables transported in the vegetable conveying pipe 4-1 are periodically and intermittently poured into the vegetable dehydration extrusion cylinder 3-5-5.

The specific implementation mode is eight:

as shown in fig. 1 to 8, in the sixth embodiment, the squeezing hammers 2 to 9 are clearance-fitted into the vegetable dewatering squeezing barrels 3 to 5. The vegetables in the vegetable dehydration squeezing barrel 3-5-5 are squeezed by the squeezing hammer 2-9 to realize the dehydration of the vegetables.

The specific implementation method nine:

as shown in FIGS. 1 to 8, in the sixth embodiment, the water flow through holes 3-5-6 are communicated with the water flow drainage grooves 3-4. So as to lead the extruded water away.

The detailed implementation mode is ten:

as shown in fig. 1 to 8, in the sixth embodiment, the vegetable conveying pipe 4-1 is connected to a vegetable dewatering squeezing cylinder 3-5-5. The vegetables in the vegetable conveying pipe 4-1 are intermittently added into the vegetable dehydration squeezing cylinder 3-5-5.

The working principle of the invention is as follows: vegetables are conveyed in the vegetable conveying pipe 4-1 through gravity, the servo motor 2-1 is connected with electricity, the servo motor 2-1 drives the main gear 2-2 and the main hinge post 2-3 to rotate, and further drives the connecting rod 2-6 to reciprocate up and down through the hinge rod 2-4 and the auxiliary hinge post 2-5, so that the upper sliding fixing plate 2-7 and the extrusion hammer 2-9 slide in the two T-shaped sliding grooves 1-6 through the two T-shaped sliding blocks 2-8, and further drives the upper sliding fixing plate 2-7 and the extrusion hammer 2-9 to reciprocate up and down; the rotating main gear 2-2 simultaneously drives the lower gear 2-10 to rotate, so that the lower rotating shaft 2-11, the half fan driving gear 2-12 and the main bevel gear 2-13 rotate; the rotary half-fan driving gear 2-12 drives the bearing driving gear 3-2 and the bearing rotating shaft 3-1 to periodically and intermittently rotate, so that the rotating round seat 3-3, the water flow drainage groove 3-4 and the plurality of bearings 3-5 periodically and intermittently rotate; the rotating main bevel gear 2-13 drives the driven bevel gear 4-10 to rotate, and then the lower belt pulley 4-8, the upper belt pulley 4-7, the left rotating shaft 4-6 and the cam 4-5 are driven to rotate through the four connecting rods 4-9, the rotating cam 4-5 drives the driving block 4-4 and the sliding baffle 4-3 to move up and down in a reciprocating manner, and therefore vegetables transported in the vegetable conveying pipe 4-1 are periodically and intermittently poured into the vegetable dehydration extrusion cylinder 3-5-5. When the bearing driving gear 3-2 and the bearing rotating shaft 3-1 stop rotating, vegetables in the vegetable conveying pipe 4-1 are added into a vegetable dehydration extrusion cylinder 3-5-5, the extrusion hammer 2-9 moves downwards, the extrusion hammer 2-9 extrudes the vegetables in the vegetable dehydration extrusion cylinder 3-5-5 above the extrusion hammer, and the extruded water flows into the water flow drainage groove 3-4 through the filter plate 3-5-7 and the water flow through hole 3-5-6 and is discharged, so that the dehydration of the vegetables is realized; when the extruding hammer 2-9 is upwards displaced to be separated from the vegetable dewatering extruding cylinder 3-5-5 right above, the sliding baffle 4-3 upwards displaces to block the vegetable conveying pipe 4-1 to prevent vegetable conveying, the bearing driving gear 3-2 and the bearing rotating shaft 3-1 rotate simultaneously, the vegetable dewatering extruding cylinder 3-5-5 with vegetables is conveyed right above, the bearing driving gear 3-2 and the bearing rotating shaft 3-1 stop rotating, and the extruding hammer 2-9 and the sliding baffle 4-3 both downwards displace, so that continuous and automatic squeezing and dewatering of the conveyed vegetables are realized in a reciprocating mode, the efficiency of dewatering the batch of vegetables is high, the dewatering speed is high, and the dewatering quality of a large amount of vegetables is guaranteed.

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

Claims

1. The utility model provides a vegetable dehydrator, includes base (1), squeezes driver (2), squeezes carrier (3) and intermittent type conveyer (4) in succession, its characterized in that: the front end of the squeezing driver (2) is fixedly connected to the base (1), the upper end of the squeezing driver (2) is connected to the inside of the base (1) in a sliding mode, the rear end of the squeezing driver (2) is connected with the continuous squeezing carrier (3) through meshing transmission, the continuous squeezing carrier (3) is connected to the base (1) in a rotating mode, the lower end of the squeezing driver (2) is connected with the intermittent conveyor (4) through meshing transmission, and the intermittent conveyor (4) is communicated with the squeezing driver (2);

the base (1) comprises a bottom plate (1-1), side plates (1-2), a front plate (1-3), an upper plate (1-4), two sliding seats (1-5), two T-shaped sliding chutes (1-6), a feeding pipe fixing hole (1-7), a baffle sliding chute (1-8), a left fixing plate (1-9), a rear fixing plate (1-10), a front fixing plate (1-11) and a rotating round hole (1-12), wherein the side plates (1-2) and the front plate (1-3) are respectively and fixedly connected to the left end and the front end of the bottom plate (1-1), the upper plate (1-4) is fixedly connected to the side plates (1-2) and the front plate (1-3), the upper ends of the two sliding seats (1-5) are fixedly connected to the lower end of the upper plate (1-4), the two T-shaped sliding chutes (1-6) are respectively arranged at the inner ends of the two sliding seats (1-5), the feeding pipe fixing holes (1-7) are arranged on the side plates (1-2) in a left-right penetrating manner, the baffle sliding chutes (1-8) are arranged at the right ends of the side plates (1-2), the baffle sliding chutes (1-8) are communicated with the feeding pipe fixing holes (1-7), the left fixing plate (1-9), the rear fixing plate (1-10) and the front fixing plate (1-11) are all fixedly connected to the bottom plate (1-1), and the rotating round holes (1-12) are arranged on the front fixing plate (1-11) in a front-back penetrating manner;

the squeezing driver (2) comprises a servo motor (2-1), a main gear (2-2), a main hinged column (2-3), a hinged rod (2-4), a slave hinged column (2-5), a connecting rod (2-6), an upper sliding fixing plate (2-7), a squeezing hammer (2-9) and two T-shaped sliding blocks (2-8), wherein the servo motor (2-1) is fixedly connected to a front plate (1-3), the main gear (2-2) is fixedly connected to a transmission shaft of the servo motor (2-1), the main hinged column (2-3) is fixedly connected to the eccentric position of the rear end of the main gear (2-2), two ends of the hinged rod (2-4) are respectively hinged to the main hinged column (2-3) and the slave hinged column (2-5), and the slave hinged column (2-5) is fixedly connected to the lower end of the connecting rod (2-6), the upper end of the connecting rod (2-6) is fixedly connected with the front end of the upper sliding fixing plate (2-7), the two T-shaped sliding blocks (2-8) are respectively and fixedly connected with the left end and the right end of the upper sliding fixing plate (2-7), the two T-shaped sliding blocks (2-8) are respectively and slidably connected into the two T-shaped sliding chutes (1-6), and the extrusion hammer (2-9) is fixedly connected with the rear side of the lower end of the upper sliding fixing plate (2-7);

the squeezing driver (2) further comprises a lower gear (2-10), a lower rotating shaft (2-11), a half fan driving gear (2-12) and a main bevel gear (2-13), the upper end of the lower gear (2-10) is in meshing transmission with the main gear (2-2), the lower gear (2-10) and the main bevel gear (2-13) are fixedly connected onto the lower rotating shaft (2-11), the half fan driving gear (2-12) is fixedly connected to the rear end of the lower rotating shaft (2-11), and the lower rotating shaft (2-11) is rotatably connected into the front plate (1-3) and the rotating circular hole (1-12);

the continuous squeezing bearing device (3) comprises a bearing rotating shaft (3-1), a bearing driving gear (3-2), a rotating round seat (3-3), a water flow diversion groove (3-4) and a plurality of bearing devices (3-5), wherein two ends of the bearing rotating shaft (3-1) are respectively and rotatably connected into a rear fixing plate (1-10) and a front fixing plate (1-11), the bearing driving gear (3-2) is fixedly connected onto the bearing rotating shaft (3-1), the lower end of the bearing driving gear (3-2) is in meshed transmission with a half-fan driving gear (2-12), the rotating round seat (3-3) is fixedly connected at the middle end of the bearing rotating shaft (3-1), the water flow diversion groove (3-4) is arranged at the middle end of the outer wall of the rotating round seat (3-3), a plurality of loaders (3-5) are uniformly and fixedly connected on the rotary round seat (3-3);

the plurality of carriers (3-5) are arranged, each carrier (3-5) comprises a fixed shaft (3-5-1), a fixed connecting plate (3-5-2), a fixed bearing plate (3-5-3), a fixed bottom shaft (3-5-4), a vegetable dehydration extrusion cylinder (3-5-5), a water through hole (3-5-6) and a filter plate (3-5-7), the fixed shaft (3-5-1) is fixedly connected in the rotary round seat (3-3), two fixed connecting plates (3-5-2) are respectively and fixedly connected at two ends of the fixed shaft (3-5-1), three fixed bearing plates (3-5-3) are respectively and fixedly connected between the two fixed connecting plates (3-5-2) from top to bottom, the fixed bottom shaft (3-5-4) is fixedly connected to the middle ends of the three fixed bearing plates (3-5-3), the vegetable dehydration extrusion cylinder (3-5-5) is fixedly connected to the upper end of the fixed bottom shaft (3-5-4), the water flowing through hole (3-5-6) vertically penetrates through the middle ends of the vegetable dehydration extrusion cylinder (3-5-5) and the fixed bottom shaft (3-5-4), and the filter plate (3-5-7) is fixedly connected to the upper side of the inner wall of the water flowing through hole (3-5-6);

the intermittent conveyor (4) comprises a vegetable conveying pipe (4-1), a lower opening (4-2), a sliding baffle plate (4-3), a driving block (4-4), a cam (4-5), a left rotating shaft (4-6), an upper belt pulley (4-7), a lower belt pulley (4-8), a connecting rod (4-9), a driven bevel gear (4-10) and a side fixing shaft (4-11), wherein the vegetable conveying pipe (4-1) is fixedly connected in a feeding pipe fixing hole (1-7), the lower opening (4-2) is arranged on the vegetable conveying pipe (4-1), the lower opening (4-2) is communicated with a baffle plate sliding groove (1-8), the sliding baffle plate (4-3) is slidably connected in the lower opening (4-2) and the baffle plate sliding groove (1-8), the right end of a sliding baffle (4-3) is fixedly connected with a driving block (4-4), the lower end of the driving block (4-4) is connected onto a cam (4-5) in a sliding mode, the cam (4-5) and an upper belt pulley (4-7) are fixedly connected onto a left rotating shaft (4-6), two ends of the left rotating shaft (4-6) are respectively connected into a side plate (1-2) and a left fixing plate (1-9) in a rotating mode, the upper belt pulley (4-7) is connected with a lower belt pulley (4-8) through belt transmission, the lower belt pulley (4-8) and a driven bevel gear (4-10) are fixedly connected onto a side fixing shaft (4-11), the side fixing shaft (4-11) is fixedly connected onto the right end of the side plate (1-2), and four connecting rods (4-9) are fixedly connected between the lower belt pulley (4-8) and the driven bevel gear (4-10).

2. The vegetable dehydrator of claim 1, wherein: the extrusion hammers (2-9) are in clearance fit in the vegetable dehydration extrusion cylinder (3-5-5).

3. A vegetable dehydrator according to claim 2, wherein: the water flow through holes (3-5-6) are communicated with the water flow drainage grooves (3-4).

4. A vegetable dehydrator according to claim 3, wherein: the vegetable conveying pipe (4-1) is communicated with a vegetable dehydration squeezing barrel (3-5-5).