CN112456182A

CN112456182A - Pinellia ternata cooling device based on automatic material distribution mechanism

Info

Publication number: CN112456182A
Application number: CN202011418117.3A
Authority: CN
Inventors: 金玉英; 宋群; 陶林
Original assignee: Bijie Productivity Promotion Center
Current assignee: Bijie Productivity Promotion Center
Priority date: 2020-12-07
Filing date: 2020-12-07
Publication date: 2021-03-09

Abstract

The invention discloses a pinellia ternate cooling device based on an automatic material distribution mechanism, which comprises a rack and a cooling plate; a hopper used for enabling the stem blocks to fall in a waterfall manner is arranged on the rack, and the stem blocks falling in the waterfall manner fall on the cooling plate; and the rack is provided with a conveying mechanism for driving the cooling board to move in the horizontal direction. The pinellia ternate cooling device based on the automatic material distribution mechanism can automatically and uniformly lay the stem blocks on the cooling plate, manual scattered laying of the stem blocks is not needed, the processing speed is high, the labor capacity is small, the laying uniformity of the stem blocks is good, the quality consistency of the stem blocks is guaranteed, and the quality of the whole stem blocks is improved.

Description

Pinellia ternata cooling device based on automatic material distribution mechanism

Technical Field

The invention relates to the technical field of pinellia ternate processing equipment, in particular to a pinellia ternate cooling device based on an automatic material distribution mechanism.

Background

Pinellia ternata has the effects of antiemetic, emetic, blood pressure reduction, blood coagulation, early pregnancy resistance and the like, and has already been applied for more than one thousand years in China. The pinellia ternata is mostly planted by tubers, when the tubers are adopted for propagation, the pinellia ternata is stored after being harvested, and the stored pinellia ternata is taken out for planting before being planted. But the tuber is easy to mildew and infect bacteria in the storage process, so that the virus infection of the bred pinellia tuber plants is serious. The traditional wet sand storage method is the reason that the tuber blocks of the pinellia are easy to mildew due to high moisture content and high humidity. Chinese patent publication No. CN103120078A discloses a method for storing pinellia ternate, which comprises the step of exposing dug pinellia ternate to sunlight to dry the pinellia ternate by 60-70%. However, when the clothes are spread for cooling, the clothes need to be spread by manpower, the labor intensity is high, and the efficiency is low. And the flatness is difficult to ensure by manual flattening, and particularly, the quality of the small stem blocks is uneven after the stem blocks are aired.

Disclosure of Invention

In order to solve the technical problem, the invention provides a pinellia ternate cooling device based on an automatic material distribution mechanism.

The invention is realized by the following technical scheme.

The pinellia ternate spreading and cooling device based on the automatic material distribution mechanism comprises a rack and a spreading and cooling plate; a hopper used for enabling the stem blocks to fall in a waterfall manner is arranged on the rack, and the stem blocks falling in the waterfall manner fall on the cooling plate; and the rack is provided with a conveying mechanism for driving the cooling board to move in the horizontal direction.

Preferably, the pinellia ternata spreading and cooling device based on the automatic material distribution mechanism is characterized in that a support frame is mounted on the machine frame; the hopper is fixed on the support frame; a discharge hole is formed in the hopper; the discharge port is a long strip shape which enables the stem block to fall in a waterfall type.

Preferably, the pinellia ternata spreading and cooling device based on the automatic material distribution mechanism is characterized in that the spreading and cooling plate is rectangular; a guard plate is arranged at the edge of the cooling plate; the long edge of the cooling plate is parallel to the moving direction of the conveying mechanism; the short edge of the cooling plate is parallel to the strip-shaped discharge hole; the hopper is positioned above the cooling plate, and the projection of the discharge port of the hopper in the vertical direction is completely fallen on the motion path of the cooling plate; the conveying mechanism is a conveying belt.

Preferably, the pinellia ternate cooling device based on the automatic material distribution mechanism further comprises a pushing mechanism for pushing the cooling plate to the conveying mechanism and a platen for placing the cooling plate; the pushing mechanism, the conveying mechanism and the bedplate are sequentially arranged along the movement direction of the conveying mechanism.

Preferably, the pinellia ternate cooling device based on the automatic material distribution mechanism comprises a pushing platform and a first pushing cylinder; the first pushing cylinder is arranged on one side, away from the conveying mechanism, of the pushing platform; the pushing direction of the first pushing cylinder and the conveying direction of the conveying mechanism are arranged in parallel.

Preferably, the platen of the pinellia ternata spreading and cooling device based on the automatic material distribution mechanism is rectangular; and a second pushing cylinder for pushing the cooling plate conveyed out by the conveying mechanism to one side of the bedplate is arranged on the bedplate.

Preferably, the pinellia ternata spreading and cooling device based on the automatic material distribution mechanism is characterized in that the pushing platform, the conveying belt and the bedplate are provided with limiting columns; the pushing platform, the conveying belt and the limiting columns on the bedplate are arranged in two rows; the distance between the conveying belt and the two rows of limiting columns on the bedplate is the same as the width of the cooling plate; the distance between the two rows of limiting columns on the bedplate is the same as the length of the cooling plate.

Preferably, the pinellia ternate cooling device based on the automatic material distribution mechanism comprises an inner rod and a sleeve; the inner rod is fixed on the pushing platform, the conveying belt or the bedplate; the sleeve is rotatably sleeved outside the inner rod through a bearing.

Preferably, the pinellia ternata spreading and cooling device based on the automatic material distribution mechanism is characterized in that the spreading and cooling plate is a sieve plate capable of screening and removing impurities from the tuber; and impurity discharging holes are formed in the conveying belt.

Preferably, the pinellia ternata spreading and cooling device based on the automatic material distribution mechanism is characterized in that a support leg is arranged on the rack; the support body is provided with a vibration spring; and the frame is also provided with a vibration exciter.

The invention has the beneficial effects that:

the pinellia ternate cooling device based on the automatic material distribution mechanism can automatically and uniformly lay the stem blocks on the cooling plate, manual scattered laying of the stem blocks is not needed, the processing speed is high, the labor capacity is small, the laying uniformity of the stem blocks is good, the quality consistency of the stem blocks is guaranteed, and the quality of the whole stem blocks is improved.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of the hopper of the present invention.

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

FIG. 4 is a schematic view of the structure of the cooling plank of the present invention.

Fig. 5 is a schematic view of the structure at the platen of the present invention.

FIG. 6 is a schematic structural view of a spacing post according to the present invention.

Detailed Description

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

Example 1, referring to the attached drawings, a pinellia ternate cooling device based on an automatic material distribution mechanism comprises a frame 1 and a cooling plate 2; a hopper 11 for enabling the stem blocks to fall in a waterfall manner is arranged on the rack 1, and the stem blocks falling in the waterfall manner fall on the cooling plate 2; the rack 1 is provided with a conveying mechanism 12 for driving the cooling board 2 to move in the horizontal direction;

the frame 1 is arranged and used for mounting and supporting the hopper 11, the conveying mechanism 12 and the like; the hopper 11 is used for conveying the stem blocks onto the cooling board 2, and the stem blocks can be scattered in the width direction and fall on the cooling board 2 as the stem blocks fall from the hopper 11 in a waterfall shape; the conveying mechanism 12 is arranged to drive the cooling board 2 to move in the horizontal direction, so that the stems fall down from the cooling board 2 and move in the horizontal direction, the stems can be scattered in the length direction and fall on the cooling board 2, the stems can be uniformly fallen on the cooling board 2 in the length direction and the width direction, namely the stems are uniformly paved on the cooling board 2, automatic distribution of the stems on the cooling board 2 is realized, manual scattering and paving of the stems are not needed, the processing speed is high, the labor capacity is small, the uniformity of laying of the stems is good, the uniformity of the quality of the stems is guaranteed, and the quality of the whole stems is improved;

Preferably, the frame 1 is provided with a support frame 13; the hopper 11 is fixed on the support frame 13; a discharge hole 111 is formed in the hopper 11; the discharge port 111 is a long strip shape which enables the stem blocks to fall in a waterfall manner;

a support frame 13 is arranged on the frame 1 and used for mounting and supporting the hopper 11; the hopper 11 is provided with a discharge hole 111 for discharging the stem blocks in the hopper; the discharge port 111 is designed to be long, so that the width of the stem block is large when the stem block falls, and the stem block can be dispersed and tiled in the width direction.

Preferably, the cooling plate 2 is rectangular; a guard plate 21 is arranged at the edge of the cooling plate 2; the long edge of the cooling plate 2 is parallel to the moving direction of the conveying mechanism 12; the short edge of the cooling plate 2 is arranged in parallel with the strip-shaped discharge hole 111; the hopper 11 is positioned above the cooling plate 2, and the projection of the discharge port 111 of the hopper 11 in the vertical direction is completely fallen on the motion path of the cooling plate 2; the conveying mechanism 12 is a conveying belt;

the stem blocks fall on the horizontally moving cooling plate 2 through the arrangement of the moving direction of the conveying mechanism 12 and the position of the hopper 11, so that the stem blocks are dispersed and spread in the length direction.

Preferably, the pinellia ternate cooling device further comprises a pushing mechanism 3 for pushing the cooling plate 2 onto the conveying mechanism 12 and a table plate 4 for placing the cooling plate 2; the pushing mechanism 3, the conveying mechanism 12 and the bedplate 4 are sequentially arranged along the movement direction of the conveying mechanism 12;

the pushing mechanism 3 is used for pushing the cooling plate 2 to the conveying mechanism 12; the bedplate 4 is used for spreading the stems on the cooling plate 2 and then placing the cooling plate 2 on the bedplate 4 for cooling.

Preferably, the pushing mechanism 3 comprises a pushing platform 31 and a first pushing cylinder 32; the first pushing cylinder 32 is arranged on one side of the pushing platform 31 far away from the conveying mechanism 12; the pushing direction of the first pushing cylinder 32 is parallel to the conveying direction of the conveying mechanism 12;

during the use, stand cold board 2 and place on push platform 31, control first promotion cylinder 32 and extend, carry out the stem piece cloth on pushing mechanism 12 with the push of stand cold board 2 propelling movement on push platform 31.

Preferably, the platen 4 is rectangular; a second pushing cylinder 41 for pushing the spread cooling plate 2 conveyed out by the conveying mechanism 12 to one side of the bedplate 4 is arranged on the bedplate 4;

after the stems are tiled on the cooling board 2, the cooling board 2 is conveyed to the bedplate 4 from the conveying mechanism 12, and after the cooling board 2 is conveyed to the bedplate 4, the second pushing cylinder 41 pushes the cooling board 2 to one side of the bedplate 4 for cooling, so that the influence on conveying the next cooling board 2 to the bedplate 4 is avoided.

Preferably, in order to avoid a directional deviation of the cooling plate 2 when moving on the pushing mechanism 3, the conveying mechanism 12 and the platen 4; the pushing platform 31, the conveying belt and the bedplate 4 are all provided with limiting columns 5; the pushing platform 31, the conveying belt and the limiting columns 5 on the bedplate 4 are arranged in two rows; the distance between the conveyer belt and the two rows of limiting columns 5 on the bedplate 4 is the same as the width of the spread cooling plate 2; the distance between the two rows of limiting columns 5 on the bedplate 4 is the same as the length of the spread cooling plate 2;

the limiting columns 5 are arranged to play a limiting and guiding role, so that the position deviation of the cooling plate 2 during movement is avoided, and normal processing and production are guaranteed.

Preferably, the limit post 5 comprises an inner rod 51 and a sleeve 52; the inner rod 51 is fixed on the pushing platform 31 and the conveying belt or the bedplate 4; the sleeve 52 is rotatably sleeved outside the inner rod 51 through a bearing 53;

the limiting post 5 adopts a rotary combined structure of the inner rod 51 and the sleeve 52, so that the cooling board 2 is in rotary connection with the limiting post 5 during movement, and the friction force between the cooling board 2 and the limiting post 5 is greatly reduced; avoid spacing inefficacy, simultaneously, also avoid spreading out cold board 2 wearing and tearing.

Preferably, the cooling plate 2 is a sieve plate capable of screening and removing impurities from the stems; the conveying belt is provided with a sundry outlet 121;

the cooling plate 2 is designed into a sieve plate structure, and can screen and remove impurities from the stems while distributing the material, so that the impurities in the stems are removed, and the quality of the stems is ensured; due to the arrangement of the impurity outlet holes 121, impurities in the stem blocks fall down from the impurity outlet holes 121 after being screened out by the cooling plate 2, so that the impurities are convenient to collect.

Preferably, in order to improve the screening and impurity removing effects of the cooling plate 2, the frame 1 is provided with supporting legs 14; a vibration spring 141 is arranged on the supporting body 14; the frame 1 is also provided with a vibration exciter 15.

It is noted that, in this document, relational terms such as first and second, and the like, if any, are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Claims

1. Pinellia ternate cooling device based on automatic material distribution mechanism, its characterized in that: comprises a frame (1) and a cooling plate (2); a hopper (11) for enabling the stem blocks to fall in a waterfall manner is arranged on the rack (1), and the stem blocks falling in the waterfall manner fall on the cooling plate (2); the machine frame (1) is provided with a conveying mechanism (12) for driving the cooling board (2) to move in the horizontal direction.

2. The pinellia ternata spreading and cooling device based on the automatic material distribution mechanism as claimed in claim 1, wherein: a support frame (13) is arranged on the frame (1); the hopper (11) is fixed on the support frame (13); a discharge hole (111) is formed in the hopper (11); the discharge hole (111) is a long strip shape which enables the stem block to fall in a waterfall type.

3. The pinellia ternata spreading and cooling device based on the automatic material distribution mechanism as claimed in claim 2, wherein: the cooling plate (2) is rectangular; a guard plate (21) is arranged at the edge of the cooling plate (2); the long edge of the cooling plate (2) is arranged in parallel with the moving direction of the conveying mechanism (12); the short edge of the cooling plate (2) is parallel to the strip-shaped discharge hole (111); the hopper (11) is positioned above the cooling plate (2), and the projection of the discharge hole (111) of the hopper (11) in the vertical direction is completely fallen on the motion path of the cooling plate (2); the conveying mechanism (12) is a conveying belt.

4. The pinellia ternata spreading and cooling device based on the automatic material distribution mechanism as claimed in claim 3, wherein: the pinellia ternate cooling device further comprises a pushing mechanism (3) used for pushing the cooling plate (2) to the conveying mechanism (12) and a bedplate (4) used for placing the cooling plate (2); the pushing mechanism (3), the conveying mechanism (12) and the bedplate (4) are sequentially arranged along the movement direction of the conveying mechanism (12).

5. The pinellia ternata spreading and cooling device based on the automatic material distribution mechanism as claimed in claim 4, wherein: the pushing mechanism (3) comprises a pushing platform (31) and a first pushing cylinder (32); the first pushing cylinder (32) is arranged on one side, far away from the conveying mechanism (12), of the pushing platform (31); the pushing direction of the first pushing cylinder (32) and the conveying direction of the conveying mechanism (12) are arranged in parallel.

6. The pinellia ternata spreading and cooling device based on the automatic material distribution mechanism as claimed in claim 5, wherein: the bedplate (4) is rectangular; and a second pushing cylinder (41) used for pushing the spread cooling plate (2) conveyed out by the conveying mechanism (12) to one side of the bedplate (4) is arranged on the bedplate (4).

7. The pinellia ternata spreading and cooling device based on the automatic material distribution mechanism as claimed in claim 6, wherein: limiting columns (5) are arranged on the pushing platform (31), the conveying belt and the bedplate (4); the pushing platform (31), the conveying belt and the limiting columns (5) on the bedplate (4) are arranged in two rows; the distance between the conveyer belt and the two rows of limiting columns (5) on the bedplate (4) is the same as the width of the cooling plate (2); the distance between the two rows of limiting columns (5) on the bedplate (4) is the same as the length of the cooling plate (2).

8. The pinellia ternata spreading and cooling device based on the automatic material distribution mechanism as claimed in claim 7, wherein: the limiting column (5) comprises an inner rod (51) and a sleeve (52); the inner rod (51) is fixed on the pushing platform (31) and the conveying belt or the bedplate (4); the sleeve (52) is rotatably sleeved outside the inner rod (51) through a bearing (53).

9. The pinellia ternata spreading and cooling device based on the automatic material distribution mechanism as claimed in claim 3, wherein: the cooling plate (2) is a sieve plate which can screen and remove impurities from the stem blocks; the conveying belt is provided with impurity discharging holes (121).

10. The pinellia ternata spreading and cooling device based on the automatic material distribution mechanism as claimed in claim 9, wherein: the frame (1) is provided with supporting legs (14); a vibration spring (141) is arranged on the supporting body (14); and a vibration exciter (15) is also arranged on the frame (1).