CN114431446A - Aniseed fruit processing is with device that completes - Google Patents

Abstract

The invention relates to the technical field of spice processing equipment, in particular to a de-enzyming device for processing star aniseed fruits. The green removing device comprises a green removing mechanism, wherein a feeding conveyor belt is arranged on one side of the green removing mechanism, a conveyor belt bracket is fixedly connected to the lower side of the feeding conveyor belt, a drying mechanism is arranged on one side of the green removing mechanism, which is far away from the feeding conveyor belt, and a discharging mechanism is arranged on one side of the drying mechanism, which is far away from the green removing mechanism; the water-removing device for processing the aniseed fruits, provided by the invention, can continuously remove the aniseed, the aniseed does not need to be taken out after water is poured after water is removed, water resources are greatly saved, heat generated during cooking is utilized at the same time, the spiral channel is driven to rotate, the aniseed is driven to rotate and dry, the aniseed is scattered when the aniseed is sent out after drying, and the utilization of energy is increased.

Description

Aniseed fruit processing is with device that completes

Technical Field

The invention relates to the technical field of spice processing equipment, in particular to a de-enzyming device for processing star aniseed fruits.

Background

The star anise is a famous flavoring spice and also used for medicine, and the peel, the seeds and the leaves contain aromatic oil and are important raw materials for manufacturing cosmetics, sweet wine, beer and food industry. After the leaves of the star anise are picked, the star anise needs to be processed and processed in time so as to avoid reducing the quality, firstly, the fruits and the leaves are spread out before processing, the fruits and the leaves cannot be stacked, and the problems that the fruits and the leaves are heated and mildewed due to rain and moisture are avoided, so that the picked star anise needs to be dried and processed generally. The existing de-enzyming and drying method comprises the steps of putting fresh star anises into a pot body without a cover and containing boiling water, stirring and de-enzyming for 10 minutes by using a wood stick, taking out the star anises when the fruit color changes from green to light yellow, spreading and drying the star anises on a sunning ground or a straw mat for 4-5 days in a solarization manner, and drying to obtain the finished product.

The existing device can only boil the aniseed every time, and the water is poured and then the aniseed is taken out, so that the water resource is greatly wasted.

Disclosure of Invention

The invention aims to solve the problems in the prior art, and provides the water-removing device for processing the aniseed fruits, which can continuously remove the water of the aniseed, and the aniseed does not need to be taken out after water is poured after the water is removed, so that water resources are greatly saved.

In order to achieve the purpose, the invention adopts the following technical scheme:

a fixation device for processing octagonal fruits comprises a fixation mechanism, wherein a feeding conveyor belt is arranged on one side of the fixation mechanism, a conveyor belt bracket is fixedly connected to the lower side of the feeding conveyor belt, a drying mechanism is arranged on one side, away from the feeding conveyor belt, of the fixation mechanism, and a discharging mechanism is arranged on one side, away from the fixation mechanism, of the drying mechanism;

the feeding conveyor belt conveys the inside of the octagonal de-enzyming mechanism;

the de-enzyming mechanism receives the aniseed on the feeding conveyor belt and stirs and cooks the aniseed, and the de-enzyming mechanism sends the cooked aniseed into the drying mechanism;

the drying mechanism receives the aniseed in the water-removing mechanism and dries the aniseed through hot air in the water-removing mechanism, and the drying mechanism sends the dried aniseed into the discharging mechanism;

and the discharging mechanism receives the aniseed in the drying mechanism and sends the aniseed out after scattering the aniseed.

Preferably, the feeding conveyer belt is electrodynamic type control, and can stop working when the mechanism that completes works, feeding conveyer belt fixed connection is in the mechanism that completes, it is equipped with a water inlet and keeps off the water of the mechanism that completes in and can automatic water supply when the mechanism that completes is equipped with to complete.

Preferably, the fixation mechanism comprises a fixation shell, the fixation shell is fixedly connected to one side of the feeding conveyor belt facing the drying mechanism, the fixation shell is close to one side of the feeding conveyor belt and provided with a feeding hole at one side of the feeding conveyor belt far away from the conveyor belt support, one side of the feeding hole is fixedly connected with a feeding hydraulic rod, an air inlet is arranged at the upper side in the fixation shell, a heater is fixedly connected to one side of the fixation shell facing the air inlet, a water filtering plate is arranged at one side of the heater facing the air inlet, two sides of the water filtering plate, which do not face the feeding hydraulic rod, are fixedly connected with fixed baffles, at least two stirring shafts are arranged between the fixed baffles, a rotating groove is arranged at one side of each stirring shaft facing the fixed baffles, a stirring output shaft is rotatably connected in the groove, and a connecting gear is rotatably connected between the stirring output shafts and in the rotating groove of the fixed baffles, the connecting gear is meshed with the stirring output shafts, one side of one of the stirring output shafts, which is far away from the stirring shaft, is provided with a rotating motor, and the output shaft of the rotating motor is fixedly connected to the stirring output shafts; the outer side of the stirring shaft is fixedly connected with a plurality of stirring rods, one side of each fixing baffle, which is close to the feeding hydraulic rod and is far away from the stirring shaft, is rotatably connected with a second electric slide block, each second electric slide block is slidably connected in a second slide way, the second slide way is arranged on the water-removing shell, one side of each second slide way, which faces the second control hydraulic rod and is far away from the water filter plate, is fixedly connected with a second control hydraulic rod, a hydraulic pipe is fixedly connected between the second control hydraulic rod and the feeding hydraulic rod, one side of each second slide way, which is far away from the second control hydraulic rod, is fixedly connected with a second spring, one side of each second spring, which is far away from the second slide way, is fixedly connected with a second electric slide block, one side of each fixing baffle, which is far away from the feeding hydraulic rod and is facing one side of the second slide way, is fixedly rotatably connected with a first electric slide block, and each first electric slide block is slidably connected in the first slide way and is arranged on the water-removing shell, the side, facing the first electric sliding block, of the first slide way and close to the water filter plate is fixedly connected with a first control hydraulic rod, the side, far away from the first control hydraulic rod, of the first slide way is fixedly connected with a first spring, and the side, close to the first electric sliding block, of the first spring is fixedly connected with the first electric sliding block; a connector is arranged on one side of the water-removing shell, which is far away from the feeding hydraulic rod, and a discharging hydraulic rod is fixedly connected to one side of the connector; the second slide way is higher than the first slide way, and when the second electric slide block and the first electric slide block are lifted to the top, the discharging hydraulic rod of the water filtering plate can be inclined.

Preferably, the drying mechanism comprises a drying shell, the drying shell is fixedly connected with one side, away from the feeding conveyor belt, of the fixation shell, a first rotating shaft is arranged in the fixation shell, a moving plate is slidably connected to the outer side of the first rotating shaft, one side, away from the first rotating shaft, of the moving plate is fixedly connected with a spiral channel, the initial position of the spiral channel is located on the lower side of a connecting port where the discharging hydraulic rod is located, a rotating connecting shaft is fixedly connected to the lower side of the first rotating shaft in a jacking mode and rotatably connected into a rotating groove of the drying shell, one side, away from the rotating connecting shaft, of the first rotating shaft is fixedly connected with a second rotating shaft, the second rotating shaft is rotatably connected into the rotating groove of the drying shell, and the moving plate faces to two sides of the second rotating shaft and the rotating connecting shaft, and a vibrating component is arranged on the drying shell; the drying shell is close to one side of the fixation shell, an air inlet pipe is arranged at the upper side of the discharging hydraulic rod and is connected into the fixation shell, one side of the air inlet pipe close to the water-removing shell is fixedly connected with an air suction pump, one side of the rotary connecting shaft far away from the first rotary shaft is provided with a connecting pipe in the drying shell, the connecting pipe is connected with the air inlet pipe, the impeller is rotationally connected in the connecting pipe and is fixedly connected with the rotary connecting shaft, a heating connecting pipe is arranged on one side of the drying shell close to the discharging mechanism and is fixedly connected with the connecting pipe, a discharge inlet is arranged on one side of the heat exchange plate far away from the connecting pipe and opens the drying shell and the discharge mechanism, and one side of the drying shell, which is far away from the impeller, is provided with an exhaust port, and the exhaust port is communicated with the heating connecting pipe.

Preferably, the vibration component comprises a second fixed block, the second fixed block is fixedly connected to one side, close to the rotary connecting shaft, of the first rotating shaft, the second fixed block is positioned below one side, far away from the second rotating shaft, of the moving plate, and one side, facing the moving plate, of the second fixed block is fixedly connected with a return spring; the second rotation axis is towards the first fixed block of one side fixed connection of movable plate, first fixed block pushes down the hydraulic stem towards one side fixed connection of movable plate, the fixed swash plate of one side fixed connection that the helical path export was kept away from to first fixed block, one side that one side of first fixed block was kept away from to fixed swash plate and keep away from the movable plate is equipped with the swash plate hydraulic stem, swash plate hydraulic stem fixed connection is on drying the casing.

Preferably, discharge mechanism includes ejection of compact casing, ejection of compact casing fixed connection is kept away from one side and the ejection of compact inlet port of the casing that completes and is linked through stoving casing and ejection of compact casing at the stoving casing, the distance between a plurality of dead levers of fixed connection and the dead lever in the ejection of compact casing can make and fall down as an anise, keep away from one side fixed connection ejection of compact swash plate of ejection of compact inlet port in the ejection of compact casing, one side that the stoving casing was kept away from to the ejection of compact swash plate is equipped with discharge gate and discharge gate fixed connection on ejection of compact casing, the minimum towards the discharge gate of ejection of compact swash plate.

Has the advantages that:

the de-enzyming device for processing the aniseed fruits, provided by the invention, can be used for de-enzyming the aniseed through the de-enzyming mechanism, fully stirring the aniseed during de-enzyming, sending the de-enzymed aniseed onto the spiral channel of the drying mechanism, and avoiding pouring water in the de-enzyming mechanism, simultaneously driving the spiral channel to rotate through the air suction pump to drive the aniseed to ascend and dry the aniseed in the drying mechanism by using heat generated during de-enzyming in the de-enzyming mechanism, driving the spiral channel to vibrate during rotation of the spiral channel to ensure better drying, driving the aniseed to enter the discharging shell through the spiral channel and scattering the aniseed through the fixing rod, and simultaneously keeping the aniseed in the discharging shell dry.

The water-removing device for processing the aniseed fruits, provided by the invention, can continuously remove the aniseed, the aniseed does not need to be taken out after water is poured after water is removed, water resources are greatly saved, heat generated during cooking is utilized at the same time, the spiral channel is driven to rotate, the aniseed is driven to rotate and dry, the aniseed is scattered when the aniseed is sent out after drying, and the utilization of energy is increased.

Drawings

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

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

FIG. 3 is a sectional view taken along line A-A of FIG. 2;

FIG. 4 is a sectional view taken along line B-B of FIG. 3;

FIG. 5 is a sectional view taken along line E-E in FIG. 4;

FIG. 6 is a sectional view taken along line D-D of FIG. 3;

FIG. 7 is a sectional view taken along line C-C of FIG. 6;

FIG. 8 is an enlarged view of a portion of FIG. 3 at W;

FIG. 9 is an enlarged view of a portion of FIG. 3 at Q;

fig. 10 is a sectional view taken in the direction F-F in fig. 9.

In the figure, a water-removing mechanism 10, a drying mechanism 11, a discharging mechanism 12, an exhaust port 13, a feeding conveyor belt 14, a conveyor belt bracket 15, a feeding port 16, a feeding hydraulic rod 17, a discharging hydraulic rod 18, an air inlet 19, a water filtering plate 20, a water-removing shell 21, a stirring shaft 22, an air suction pump 23, an air inlet pipe 24, a connecting pipe 25, an impeller 26, a rotary connecting shaft 27, a first rotary shaft 28, a spiral channel 29, a moving plate 30, a first control hydraulic rod 31, a first electric slider 32, a first spring 33, a heating connecting pipe 34, a heat exchange plate 35, a drying shell 36, a discharging inlet port 37, a discharging shell 38, a fixed rod 39, a discharging inclined plate 40, a discharging port 41, a second fixed block 42, a reset spring 43, a first fixed block 44, a second rotary shaft 45, a pressing hydraulic rod 46, an inclined plate 47, a fixed inclined plate 48, a second spring 49, a second slide 50, a first slide 51, a lower slide way 50, a second fixed slide way 44, a second fixed block 44, a second electric slide way, a second electric control device, a water heater, the device comprises a heater 52, a vibration component 53, a stirring rod 54, a rotating motor 55, a stirring output shaft 56, a fixed baffle 57, a second electric slider 58, a second control hydraulic rod 59 and a connecting gear 60.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

In the description of the present invention, it should be noted that the terms "inside", "below", and the like refer to orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention conventionally place when used, and are used only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

With reference to fig. 1-10, a water-removing device for processing octagonal fruits comprises a water-removing mechanism 10, wherein a feeding conveyor belt 14 is arranged on one side of the water-removing mechanism 10, a conveyor belt bracket 15 is fixedly connected to the lower side of the feeding conveyor belt 14, a drying mechanism 11 is arranged on one side of the water-removing mechanism 10 away from the feeding conveyor belt 14, and a discharging mechanism 12 is arranged on one side of the drying mechanism 11 away from the water-removing mechanism 10;

the feeding conveyor belt 14 transports the octagonal channel water-removing mechanism 10;

the water-removing mechanism 10 is used for receiving the aniseed on the feeding conveyor belt 14 and stirring and boiling the aniseed, and the water-removing mechanism 10 sends the boiled aniseed into the drying mechanism 11;

the drying mechanism 11 is used for receiving the aniseed in the water-removing mechanism 10, drying the aniseed through hot air in the water-removing mechanism 10, and sending the dried aniseed into the discharging mechanism 12 through the drying mechanism 11;

and the discharging mechanism 12 is used for receiving the aniseed in the drying mechanism 11, scattering the aniseed and then sending the aniseed out, and the discharging mechanism 12 is used for discharging the aniseed.

Furthermore, the feeding conveyor belt 14 is controlled by an electric mode and stops working when the water-removing mechanism 10 works, the feeding conveyor belt 14 is fixedly connected to the water-removing mechanism 10, and a water inlet is formed in the water-removing mechanism 10 and can automatically supply water when water in the water-removing mechanism 10 is blocked.

Further, the enzyme deactivating mechanism 10 comprises an enzyme deactivating housing 21, the enzyme deactivating housing 21 is fixedly connected to one side of the feeding conveyor belt 14 facing the drying mechanism 11, one side of the enzyme deactivating housing 21 close to the feeding conveyor belt 14 and one side of the feeding conveyor belt 14 far away from the conveyor belt support 15 are provided with a feeding port 16, one side of the feeding port 16 is fixedly connected with a feeding liquid pressure rod 17, the upper side in the enzyme deactivating housing 21 is provided with an air inlet 19, one side of the enzyme deactivating housing 21 facing the air inlet 19 is fixedly connected with a heater 52, one side of the heater 52 facing the air inlet 19 is provided with a water filtering plate 20, two sides of the water filtering plate 20 not facing the feeding liquid pressure rod 17 are fixedly connected with fixed baffles 57, at least two stirring shafts 22 are arranged between the fixed baffles 57, one side of each stirring shaft 22 facing the fixed baffles 57 is provided with a rotating groove and is rotatably connected with a stirring output shaft 56, a connecting gear 60 is rotatably connected between the stirring output shafts 56 and in the rotating groove of the fixed baffles 57, the connecting gear 60 is meshed with the stirring output shafts 56, one side of one of the stirring output shafts 56, which is far away from the stirring shaft 22, is provided with a rotating motor 55, and the output shaft of the rotating motor 55 is fixedly connected to the stirring output shaft 56; a plurality of stirring rods 54 are fixedly connected to the outer side of the stirring shaft 22, one side of each fixed baffle 57, which is close to the feeding hydraulic rod 17 and is far away from the stirring shaft 22, is rotatably connected with a second electric slide block 58, each second electric slide block 58 is slidably connected in a second slide way 50, the second slide way 50 is arranged on the enzyme-deactivating shell 21, one side, which faces to a second control hydraulic rod 59 and is far away from the water filtering plate 20, of each second slide way 50 is fixedly connected with the second control hydraulic rod 59, a hydraulic pipe is fixedly connected between the second control hydraulic rod 59 and the feeding hydraulic rod 17, one side, which is far away from the second control hydraulic rod 59, in each second slide way 50 is fixedly connected with a second spring 49, one side, which is far away from the second slide way 50, of each fixed baffle 57, which is far away from the feeding hydraulic rod 17 and is fixedly and rotatably connected with a first electric slide block 32, each first electric slide block 32 is slidably connected into the first slide way 51, the first slide way 51 is arranged on the water-removing shell 21, one side of the first slide way 51, which faces the first electric slide block 32 and is close to the water filter plate 20, is fixedly connected with the first control hydraulic rod 31, one side of the first slide way 51, which is far away from the first control hydraulic rod 31, is fixedly connected with the first spring 33, and one side of the first spring 33, which is close to the first electric slide block 32, is fixedly connected with the first electric slide block 32; a connector is arranged on one side of the water-removing shell 21 far away from the feeding hydraulic rod 17, a discharging hydraulic rod 18 is fixedly connected to one side of the connector, the discharging hydraulic rod 18 is connected with the first control hydraulic rod 31 through a hydraulic pipe, and the connector where the discharging hydraulic rod 18 is located can be communicated into the drying mechanism 11; the second slide way 50 is higher than the first slide way 51, and when the second electric slide block 58 and the first electric slide block 32 are lifted to the uppermost position, the water filtering plate 20 can incline at the phase discharging hydraulic rod 18.

Further, the drying mechanism 11 includes a drying housing 36, the drying housing 36 is fixedly connected to one side of the de-enzyming housing 21 away from the feeding conveyor belt 14, a first rotating shaft 28 is arranged in the de-enzyming housing 21, a moving plate 30 is slidably connected to the outer side of the first rotating shaft 28, one side of the moving plate 30 away from the first rotating shaft 28 is fixedly connected to a spiral channel 29, the initial position of the spiral channel 29 is located at the lower side of a connecting port where the discharging hydraulic rod 18 is located, a rotating connecting shaft 27 is fixedly connected to the lower side of the first rotating shaft 28, the rotating connecting shaft 27 is rotatably connected to a rotating groove of the drying housing 36, one side of the first rotating shaft 28 away from the rotating connecting shaft 27 is fixedly connected to a second rotating shaft 45, the second rotating shaft 45 is rotatably connected to the rotating groove of the drying housing 36, the moving plate 30 faces to the second rotating shaft 45 and two sides of the rotating connecting shaft 27, and a vibration component 53 is arranged on the drying housing 36; one side of the drying shell 36 close to the enzyme deactivating shell 21 is provided with an air inlet pipe 24 on the upper side of the discharging hydraulic rod 18, the air inlet pipe 24 is connected into the enzyme deactivating shell 21, one side of the air inlet pipe 24 close to the enzyme deactivating shell 21 is fixedly connected with an air suction pump 23, one side of the rotary connecting shaft 27 far away from the first rotary shaft 28 is provided with a connecting pipe 25 in the drying shell 36, the connecting pipe 25 is connected with the air inlet pipe 24, the impeller 26 is rotatably connected in the connecting pipe 25 and fixedly connected with the impeller 26 and the rotary connecting shaft 27, one side of the drying shell 36 close to the discharging mechanism 12 is provided with a heating connecting pipe 34 and fixedly connected with the heating connecting pipe 34, the outer side of the heating connecting pipe 34 is fixedly connected with a heat exchange plate 35, one side of the heat exchange plate 35 far away from the connecting pipe 25 is provided with a discharging inlet 37 and the discharging inlet 37 is communicated with the drying shell 36 and the discharging mechanism 12, one side of the drying shell 36 far away from the impeller 26 is provided with an air outlet 13 and the heating connecting pipe 34 is communicated with the heating connecting pipe 34.

Further, the vibration component 53 includes a second fixed block 42, the second fixed block 42 is fixedly connected to a side of the first rotating shaft 28 close to the rotating connecting shaft 27, the second fixed block 42 is located below a side of the moving plate 30 far away from the second rotating shaft 45, and a return spring 43 is fixedly connected to a side of the second fixed block 42 facing the moving plate 30; the side of the second rotating shaft 45 facing the moving plate 30 is fixedly connected with a first fixed block 44, the side of the first fixed block 44 facing the moving plate 30 is fixedly connected with a downward-pressing hydraulic rod 46, the side of the first fixed block 44 far away from the outlet of the spiral channel 29 is fixedly connected with a fixed inclined plate 48, the side of the fixed inclined plate 48 far away from the first fixed block 44 and far away from the moving plate 30 is provided with an inclined plate hydraulic rod 47, and the inclined plate hydraulic rod 47 is fixedly connected to the drying casing 36.

Further, discharge mechanism 12 includes ejection of compact casing 38, ejection of compact casing 38 fixed connection is drying casing 36 and is kept away from one side of the casing 21 that completes and ejection of compact inlet port 37 connects through drying casing 36 and ejection of compact casing 38, distance between a plurality of dead levers 39 of fixed connection and the dead lever 39 in ejection of compact casing 38 can make and fall when an octagon, one side fixed connection ejection of compact swash plate 40 of keeping away from ejection of compact inlet port 37 in ejection of compact casing 38, one side that ejection of compact swash plate 40 kept away from drying casing 36 is equipped with discharge gate 41 and discharge gate 41 fixed connection on ejection of compact casing 38, discharge swash plate 40 is the lowest towards discharge gate 41.

The working principle is that workers firstly start the machine, then pour water into the water-removing shell 21, the water reaches the lower side of the feed inlet 16 at most, the heater 52 works to boil the water, the workers place raw aniseed on the feed conveyor belt 14, the feed conveyor belt 14 drives the raw aniseed to reach the upper side of the water filter plate 20 through the feed inlet 16, at the moment, the water filter plate 20 is at the lower side, the feed liquid pressure rod 17 is in an open state, the rotary motor 55 works, the rotary motor 55 drives the stirring output shaft 56 to rotate, the stirring output shaft 56 drives the connecting gear 60 to rotate, the stirring output shaft 56 with the rotary motor 55 drives all the stirring shafts 22 to rotate, the stirring shafts 22 drive the stirring rods 54 to stir the aniseed on the water filter plate 20, and when the rotary motor 55 works, the feed conveyor belt 14 stops working.

When the time for boiling the aniseed on the water filter plate 20 is up, the second electric slider 58 and the first electric slider 32 move upwards in the second slideway 50 and the first slideway 51, the second electric slider 58 and the first electric slider 32 drive the fixed baffle 57 to move upwards, the fixed baffle 57 drives the water filter plate 20 to move upwards, the fixed baffle 57 drives the stirring shaft 22 and the stirring rod 54 to move upwards, the water filter plate 20 scoops the aniseed in water, water leaks downwards through the water filter plate 20, the second electric slider 58 pushes the second control hydraulic rod 59 while moving upwards, the second control hydraulic rod 59 closes the feed port 16 through the hydraulic pipe control feed liquid pressure rod 17, the first control hydraulic rod 31 is loosened when the first electric slider 32 moves upwards, the first control hydraulic rod 31 controls the discharge liquid pressure rod 18 to open the channel in the water removing shell 21 and the channel in the drying shell 36 through the hydraulic pipe, simultaneously because the second slide 50 is different with the height of first slide 51, can drive drainage plate 20 towards the slope of play liquid pressure pole 18 department, rotating electrical machines 55 work, it is rotatory to drive (mixing) shaft 22, (mixing) shaft 22 drives the puddler 54 rotatory, puddler 54 sends the aniseed on drainage plate 20 to spiral way 29 bottom side, second spring 49 and first spring 33 can have a effect of vibrations to drainage plate 20 simultaneously, make the aniseed on drainage plate 20 enter into spiral way 29 in the stoving casing 36 fast, after the aniseed on drainage plate 20 has sent, second electric slider 58 and 62 reset, drive drainage plate 20 and reset, ejection of compact hydraulic stem 18 closes feeding liquid pressure pole 17 simultaneously and opens, make next aniseed on drainage plate 20, simultaneously when the water in drainage plate 20 is few water, the water pipe can automatic water supply.

When the heater 52 heats water, the air suction pump 23 operates to discharge hot air into the connecting pipe 25 through the stirring rod 54, the impeller 26 is driven to rotate, the impeller 26 drives the rotating connecting shaft 27 to rotate, the rotating connecting shaft 27 drives the first rotating shaft 28 and the second rotating shaft 45 to rotate, the first rotating shaft 28 drives the moving plate 30 to rotate, the moving plate 30 drives the spiral channel 29 to rotate, the spiral channel 29 drives the octagon to move towards the discharge inlet 37, meanwhile, the hot air of the connecting pipe 25 enters the heating connecting pipe 34, the heating connecting pipe 34 heats the heat exchanging plate 35, the heat exchanging plate 35 dries the octagon on the spiral channel 29, the hot air in the heating connecting pipe 34 is finally discharged through the exhaust port 13, the air suction pump 23 continuously heats the air in the heating connecting pipe 34, meanwhile, when the first rotating shaft 28 rotates, the first rotating shaft 28 drives the second rotating shaft 45 to rotate, the second rotating shaft 45 drives the first fixing block 44 to rotate, the first fixing block 44 drives the fixed inclined plate 48 to rotate, when the fixed inclined plate 48 rotates once, the fixed inclined plate 48 can extrude the inclined plate hydraulic rod 47, the inclined plate hydraulic rod 47 controls the downward pressing hydraulic rod 46 to extend out through the hydraulic pipe, the downward pressing hydraulic rod 46 extrudes the moving plate 30, when the fixed inclined plate 48 passes through the inclined plate hydraulic rod 47, the reset spring 43 drives the moving plate 30 to vibrate, the moving plate 30 drives the spiral channel 29 to vibrate, the spiral channel 29 drives the octagonal vibration on the upper side to enable the movable plate to be dried better, meanwhile, the fixed inclined plate 48 and the inclined plate hydraulic rod 47 are designed to be inclined planes, the movable plate is enabled to be more stable when rotating, and meanwhile, compared with a lug, the design of the inclined plate hydraulic rod 47 is wear, and the use is not influenced at all points.

Star anise on the spiral way 29 will fall ejection of compact casing 38 through ejection of compact inlet port 37 at last in, can will be crowded star anise separately in the same place when dead lever 39 and not say that heat transfer plate 35 also can dry in ejection of compact casing 38, make star anise keep dry, star anise can fall on ejection of compact swash plate 40, discharge through discharge gate 41 at last, the staff as long as put the container and connect just in discharge gate 41 department.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (6)

1. The de-enzyming device for processing the aniseed fruits comprises a de-enzyming mechanism (10), and is characterized in that a feeding conveyor belt (14) is arranged on one side of the de-enzyming mechanism (10), a conveyor belt bracket (15) is fixedly connected to the lower side of the feeding conveyor belt (14), a drying mechanism (11) is arranged on one side, away from the feeding conveyor belt (14), of the de-enzyming mechanism (10), and a discharging mechanism (12) is arranged on one side, away from the de-enzyming mechanism (10), of the drying mechanism (11);

the feeding conveyor belt (14) transports the inside of the octagonal track de-enzyming mechanism (10);

the de-enzyming mechanism (10) receives the aniseed on the feeding conveyor belt (14) and stirs and cooks the aniseed, and the de-enzyming mechanism (10) sends the cooked aniseed into the drying mechanism (11);

the drying mechanism (11) receives the aniseed in the water-removing mechanism (10), the aniseed is dried through hot air in the water-removing mechanism (10), and the dried aniseed is sent into the discharging mechanism (12) by the drying mechanism (11);

discharging mechanism (12), discharging mechanism (12) receive the octagon in drying mechanism (11) and send out after breaking up it.

2. The de-enzyming device for processing the aniseed fruit as claimed in claim 1, wherein the feeding conveyor belt (14) is controlled by an electric motor and stops working when the de-enzyming mechanism (10) works, the feeding conveyor belt (14) is fixedly connected to the de-enzyming mechanism (10), and the de-enzyming mechanism (10) is provided with a water inlet and can automatically replenish water when the water in the de-enzyming mechanism (10) is blocked.

3. The de-enzyming device for processing the octagonal fruits according to claim 1, wherein the de-enzyming mechanism (10) comprises a de-enzyming shell (21), the de-enzyming shell (21) is fixedly connected to one side of the feeding conveyor belt (14) facing the drying mechanism (11), the de-enzyming shell (21) is close to one side of the feeding conveyor belt (14) and is provided with a feeding hole (16) at one side of the feeding conveyor belt (14) far away from the conveyor belt bracket (15), one side of the feeding hole (16) is fixedly connected with the feeding hydraulic rod (17), an air inlet (19) is arranged at the upper side in the de-enzyming shell (21), a heater (52) is fixedly connected to one side of the de-enzyming shell (21) facing the air inlet (19), a water filtering plate (20) is arranged at one side of the heater (52) facing the air inlet (19), and fixed baffle plates (57) are fixedly connected to two sides of the water filtering plate (20) not facing the feeding hydraulic rod (17), at least two stirring shafts (22) are arranged between the fixed baffles (57), one side of each stirring shaft (22) facing the fixed baffles (57) is provided with a rotating groove, and a stirring output shaft (56) is rotationally connected in the rotating groove, a connecting gear (60) is rotationally connected between the stirring output shafts (56) and in the rotating groove of the fixed baffles (57), the connecting gear (60) is meshed with the stirring output shafts (56), one side of one of the stirring output shafts (56) far away from the stirring shafts (22) is provided with a rotating motor (55), and the output shaft of the rotating motor (55) is fixedly connected to the stirring output shaft (56); the outer side of the stirring shaft (22) is fixedly connected with a plurality of stirring rods (54), one side of each fixed baffle plate (57), which is close to the feeding hydraulic rod (17), and one side of each fixed baffle plate, which is far away from the stirring shaft (22), is rotatably connected with a second electric slider (58), each second electric slider (58) is slidably connected into a second slide way (50), the second slide way (50) is arranged on the de-enzyming shell (21), one side, which faces towards a second control hydraulic rod (59), of each second slide way (50) and is far away from the water filtering plate (20) is fixedly connected with a second control hydraulic rod (59), a hydraulic pipe is fixedly connected between the second control hydraulic rod (59) and the feeding hydraulic rod (17), one side, which is far away from the second control hydraulic rod (59), in each second slide way (50) is fixedly connected with a second spring (49), and one side, which is far away from the second slide way (50), of the second spring (49) is fixedly connected onto the second electric slider (58), each fixed baffle (57) is far away from one side of the feeding hydraulic rod (17) and towards one side of the second slide way (50) and is fixedly and rotatably connected with a first electric slide block (32), each first electric slide block (32) is slidably connected into a first slide way (51), the first slide way (51) is arranged on the green removing shell (21), one side, facing towards the first electric slide block (32), of the first slide way (51) and close to one side of the water filtering plate (20) is fixedly connected with a first control hydraulic rod (31), one side, far away from the first control hydraulic rod (31), of the first slide way (51) is fixedly connected with a first spring (33), and one side, close to the first electric slide block (32), of the first spring (33) is fixedly connected with the first electric slide block (32); a connector is arranged on one side, away from the feeding hydraulic rod (17), of the de-enzyming shell (21), a discharging hydraulic rod (18) is fixedly connected to one side of the connector, the discharging hydraulic rod (18) is connected with the first control hydraulic rod (31) through a hydraulic pipe, and the connector where the discharging hydraulic rod (18) is located can be communicated into the drying mechanism (11); the second slide way (50) is higher than the first slide way (51), and when the second electric slide block (58) and the first electric slide block (32) rise to the top, the position of the phase discharge hydraulic rod (18) of the water filtering plate (20) can be inclined.

4. The de-enzyming device for processing the octagonal fruits according to claim 1, wherein the drying mechanism (11) comprises a drying shell (36), the drying shell (36) is fixedly connected with one side, away from the feeding conveyor belt (14), of the de-enzyming shell (21), a first rotating shaft (28) is arranged in the de-enzyming shell (21), a moving plate (30) is slidably connected to the outer side of the first rotating shaft (28), one side, away from the first rotating shaft (28), of the moving plate (30) is fixedly connected with a spiral channel (29), the initial position of the spiral channel (29) is located on the lower side of a connecting port where the discharging hydraulic rod (18) is located, the lower side of the first rotating shaft (28) is fixedly connected with a rotating connecting shaft (27) in a pushing mode and the rotating connecting shaft (27) is rotatably connected in a rotating groove of the drying shell (36), one side, away from the rotating connecting shaft (27), of the first rotating shaft (28) is fixedly connected with a second rotating shaft (45) and the second rotating shaft (45) is rotatably connected The movable plate (30) is connected in a rotating groove of the drying shell (36), faces to two sides of the second rotating shaft (45) and the rotating connecting shaft (27), and a vibration component (53) is arranged on the drying shell (36); the drying shell (36) is close to one side of the fixation shell (21) and provided with an air inlet pipe (24) on the upper side of the discharge hydraulic rod (18), the air inlet pipe (24) is connected into the fixation shell (21), one side of the air inlet pipe (24) close to the fixation shell (21) is fixedly connected with an air suction pump (23), one side of a rotary connecting shaft (27) far away from a first rotating shaft (28) is provided with a connecting pipe (25) in the drying shell (36), the connecting pipe (25) is connected with the air inlet pipe (24), the connecting pipe (25) is rotatably connected with an impeller (26) and fixedly connected between the impeller (26) and the rotary connecting shaft (27), one side of the drying shell (36) close to the discharge mechanism (12) is provided with a heating connecting pipe (34) and fixedly connected with the heating connecting pipe (34) and the connecting pipe (25), and the outer side of the heating connecting pipe (34) is fixedly connected with a heat exchange plate (35), one side of the heat exchange plate (35) far away from the connecting pipe (25) is provided with a discharge inlet (37), the discharge inlet (37) opens the space between the drying shell (36) and the discharge mechanism (12), one side of the drying shell (36) far away from the impeller (26) is provided with an exhaust port (13), and the exhaust port (13) is communicated with the heating connecting pipe (34).

5. The de-enzyming device for processing the octagonal fruits according to claim 4, wherein the vibrating component (53) comprises a second fixed block (42), the second fixed block (42) is fixedly connected to one side of the first rotating shaft (28) close to the rotating connecting shaft (27), the second fixed block (42) is positioned on one side of the moving plate (30) far away from the second rotating shaft (45), a return spring (43) is fixedly connected to one side of the second fixed block (42) facing the moving plate (30), a first fixed block (44) is fixedly connected to one side of the second rotating shaft (45) facing the moving plate (30), a hydraulic rod (46) is fixedly connected to one side of the first fixed block (44) facing the moving plate (30), a fixed inclined plate (48) is fixedly connected to one side of the first fixed block (44) far away from the outlet of the spiral channel (29), an inclined plate hydraulic rod (47) is arranged on one side, far away from the first fixed block (44), of the fixed inclined plate (48) and one side, far away from the moving plate (30), of the fixed inclined plate (48), and the inclined plate hydraulic rod (47) is fixedly connected to the drying shell (36).

6. The de-enzyming device for processing the aniseed fruits according to claim 1, the discharging mechanism (12) comprises a discharging shell (38), the discharging shell (38) is fixedly connected to one side of the drying shell (36) far away from the enzyme-deactivating shell (21), and a discharging inlet (37) is connected to the drying shell (36) and the discharging shell (38), a plurality of fixing rods (39) are fixedly connected in the discharging shell (38), and the distance between the fixing rods (39) can ensure that when an octagon falls down, a discharging inclined plate (40) is fixedly connected with one side of the discharging shell (38) far away from the discharging inlet (37), one side of the discharging inclined plate (40) far away from the drying shell (36) is provided with a discharging hole (41), the discharging hole (41) is fixedly connected to the discharging shell (38), and the lowest surface of the discharging inclined plate (40) faces the discharging hole (41).

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