CN114770632B

CN114770632B - Rhodiola root slicing process and device for processing

Info

Publication number: CN114770632B
Application number: CN202210632793.3A
Authority: CN
Inventors: 王福清
Original assignee: Tibet Tianhong Technology Co ltd
Current assignee: Tibet Tianhong Technology Co ltd
Priority date: 2022-06-07
Filing date: 2022-06-07
Publication date: 2023-09-26
Anticipated expiration: 2042-06-07
Also published as: CN114770632A

Abstract

The application discloses a rhodiola root slicing device for processing, which comprises: an inclined plate; the plurality of baffle plates are vertically arranged on the surface of the inclined plate at intervals, and form a plurality of sliding channels along the length direction of the inclined plate, each sliding channel at least comprises a stay zone and a cutting zone, the stay zone is positioned at the upstream of the cutting zone, and the stay zone is provided with first air suction holes; the vacuum pump is arranged below the inclined plate and is respectively communicated with the first air suction holes of the stay areas of the sliding channels through the air conveying pipes; the cutting mechanism comprises a fixed plate, a plurality of groups of cutters and a telescopic rod, the cutting mechanism is arranged above a cutting area, the plurality of groups of cutters are arranged on the lower surface of the fixed plate, each group of cutters comprises a plurality of cutters which are arranged at intervals in parallel, each group of cutters corresponds to one sliding channel, and the telescopic rod is connected with the upper surface of the fixed plate. The application also provides a rhodiola root slicing device for processing. Compared with manual slicing, the application can continuously slice the rhodiola root, has high efficiency and higher slicing quality.

Description

Rhodiola root slicing process and device for processing

Technical Field

The application relates to the technical field related to rhodiola root processing. More particularly, the application relates to a rhodiola root slicing process and a rhodiola root slicing device for processing.

Background

Rhodiola root has the effects of tonifying qi, activating blood, promoting blood circulation and relieving asthma. Usually, the rhodiola root needs to be sliced for use, the manual cutting efficiency is low, the cost is high, and the common cutting equipment cannot completely meet the requirements because the rhodiola root is not uniform in size. Therefore, a technical scheme capable of overcoming the defects to a certain extent is continuously designed.

Disclosure of Invention

The application aims to provide a rhodiola root slicing process and device for processing, which can continuously slice rhodiola root compared with manual slicing, and has high efficiency and higher slicing quality.

To achieve these objects and other advantages and in accordance with the purpose of the application, as embodied and broadly described herein, there is provided a rhodiola rosea slicing apparatus for processing, comprising: an inclined plate; the plurality of partition boards are vertically arranged on the surface of the inclined plate at intervals, a plurality of sliding channels are formed along the length direction of the inclined plate, the width dimensions of the sliding channels are matched with those of rhodiola root, the sliding channels at least comprise a stay area and a cutting area, the stay area is positioned at the upstream of the cutting area, and a first air suction hole is arranged in the stay area; the vacuum pump is arranged below the inclined plate and is respectively communicated with the first air suction holes of the residence areas of the sliding channels through air pipes; the cutting mechanism comprises a fixed plate, a plurality of groups of cutters and a telescopic rod, wherein the cutting mechanism is arranged above a cutting area, the cutters are arranged on the lower surface of the fixed plate, each group of cutters comprise a plurality of cutters which are arranged at intervals in parallel, each group of cutters corresponds to one sliding channel, and the telescopic rod is connected with the upper surface of the fixed plate and is used for driving the cutting mechanism to move towards the cutting area and executing cutting action on rhodiola root in the cutting area.

Further, the method further comprises the following steps: the base, the hang plate sets up the base upper surface, the inclination of hang plate is 20~30 ℃.

Further, the plurality of sliding channels are internally provided with infrared sensors, and the infrared sensors are arranged between the stay area and the cutting area and are used for detecting whether rhodiola roots move from the stay area to the cutting area.

Further, the first vent holes are further arranged in the staying area, the second air suction holes and the second vent holes are arranged in the cutting area, the second air suction holes are communicated with the vacuum pump through air pipes, and the first vent holes and the second vent holes are communicated to a blower through the air pipes.

Further, an electromagnetic valve is arranged on the air pipe, the electromagnetic valve corresponding to the first air suction hole is used for controlling the first air suction hole of each stay area to suck or not suck, the electromagnetic valve corresponding to the first air vent is used for controlling the first air vent of each stay area to blow or not blow, when rhodiola rosea roots move from the stay area to the cutting area, the first air suction hole is controlled to suck, and when rhodiola rosea roots do not move from the stay area to the cutting area within a preset time period, the first air vent is controlled to blow.

Further, the electromagnetic valve corresponding to the second air suction hole is used for controlling the second air suction hole of each cutting area to suck or not suck, the electromagnetic valve corresponding to the second air vent is used for controlling the second air vent of each cutting area to blow or not blow, the second air suction hole is controlled to suck before the cutting mechanism executes the cutting action, and the second air vent is controlled to blow after the cutting mechanism executes the cutting action.

Further, the method further comprises the following steps: and the conveying belt is flush with the upper end of the inclined plate and is used for conveying rhodiola root to the inclined plate.

According to another aspect of the application, the application also provides a rhodiola root slicing process for processing, and the rhodiola root slicing process is used for slicing rhodiola root.

The application at least comprises the following beneficial effects:

the rhodiola root slicing device for processing comprises an inclined plate, a plurality of partition plates, a vacuum pump and a cutting mechanism, wherein the partition plates form a plurality of sliding channels for the rhodiola root to slide downwards on the inclined plate, the sliding channels comprise a stay area and a cutting area, the vacuum pump provides suction for the stay area through a first suction hole so that the rhodiola root stays in the stay area, and the cutting mechanism is used for slicing the rhodiola root sliding into the cutting area to obtain a flaky rhodiola root; compared with manual slicing, the application can continuously slice the rhodiola root, the efficiency is relatively higher, a plurality of cutters slice the rhodiola root equidistantly, and the sliding channel limits the placing direction of the rhodiola root, so the slicing quality is higher.

Additional advantages, objects, and features of the application will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the application.

Drawings

FIG. 1 is a schematic diagram of the structure of the present application;

FIG. 2 is a schematic view of the structure of the inclined plate of the present application;

the device comprises a base 1, a bracket 2, an inclined plate 3, a partition plate 4, a cutting mechanism 5, a vacuum pump 6, a blower 7, an air pipe 8, an infrared sensor 9, a conveying belt 10, a first suction hole 301, a stay area 401, a cutting area 402, a fixed plate 501, a plurality of groups of cutters 502 and telescopic rods 503.

Detailed Description

The present application is described in further detail below with reference to the drawings to enable those skilled in the art to practice the application by referring to the description.

It will be understood that terms, such as "having," "including," and "comprising," as used herein, do not preclude the presence or addition of one or more other elements or groups thereof.

As shown in fig. 1 and 2, an embodiment of the present application provides a rhodiola root slicing device for processing, comprising: an inclined plate 3; a plurality of partition boards 4, wherein a plurality of partition boards 4 are vertically arranged on the surface of the inclined plate 3 at intervals, a plurality of sliding channels are formed along the length direction of the inclined plate 3, the width dimensions of the sliding channels are matched with those of rhodiola root, the sliding channels at least comprise a stay area 401 and a cutting area 402, the stay area 401 is positioned at the upstream of the cutting area 402, and the stay area 401 is provided with a first air suction hole 301; a vacuum pump 6 disposed below the inclined plate 3 and respectively communicating with the first suction holes 301 of the residence zones 401 of the plurality of sliding passages through gas pipes 8; the cutting mechanism 5 comprises a fixed plate 501, a plurality of groups of cutters 502 and a telescopic rod 503, wherein the cutting mechanism 5 is arranged above the cutting area 402, a plurality of groups of cutters 502 are arranged on the lower surface of the fixed plate 501, each group of cutters 502 comprises a plurality of cutters 502 which are arranged at intervals in parallel, each group of cutters 502 corresponds to one sliding channel, and the telescopic rod 503 is connected with the upper surface of the fixed plate 501 and is used for driving the cutting mechanism 5 to move towards the cutting area 402 and executing cutting action on rhodiola rosea roots in the cutting area 402;

in the above embodiment, the inclined plate 3 is the main body of the slicing device, the plurality of partition plates 4 are arranged on the upper surface of the inclined plate 3 and extend along the length direction, and a plurality of long and narrow sliding channels are formed on the inclined plate 3, and the sliding channels are arranged in a size capable of allowing rhodiola roots to slide downwards; the sliding channel comprises a stay area 401 positioned at the middle upper part and a cutting area 402 positioned at the lower part, wherein first air suction holes 301 are distributed on the surface of the inclined plate 3 corresponding to the stay area 401, the first air suction holes 301 are communicated with a vacuum pump 6, namely when the rhodiola root positioned in the stay area 401 needs to stay for more time, the vacuum pump 6 provides suction force to stay the rhodiola root in the stay area 401; the cutting mechanism 5 is arranged above the cutting area 402, a plurality of groups of cutters 502 are arranged on a fixed plate 501 of the cutting mechanism 5, the groups of cutters 502 are matched with sliding channels in the cutting area 402, the distance between the cutters 502 of each group of cutters 502 is adjusted according to the required slicing thickness, the cutters 502 are perpendicular to the inclined plate 3, the positions of each group of cutters 502 respectively correspond to each sliding channel, a telescopic rod 503 is connected with the fixed plate 501 and is used for moving the cutting mechanism 5 to the cutting area 402, and each group of cutters 502 slices the columnar rhodiola root in the corresponding sliding channel to obtain a slice rhodiola root slice;

when the rhodiola rosea slicing machine is used, rhodiola rosea roots are fed from the upper end of the inclined plate 3, slide downwards from the upper end and are separated by the plurality of baffle plates 4, so that the rhodiola rosea roots slide downwards approximately along the length direction, pass through the stay area 401 and the slicing area 402 in sequence, are sliced by the slicing mechanism 5 in the slicing area 402, when the rhodiola rosea roots exist in the slicing area 402, the stay area 401 enables the first air suction holes 301 to suck air by utilizing the vacuum pump 6, the friction force of the rhodiola rosea roots is increased, the rhodiola rosea roots are detained in the stay area 401, and after slicing is finished, the air suction is stopped, so that the rhodiola rosea roots slide downwards to the slicing area 402 to be sliced by the slicing mechanism 5; the lower end of the inclined plate 3 is provided with a collecting basket for collecting rhodiola root slices;

it can be seen that, compared with manual slicing, the embodiment can continuously and orderly slice the rhodiola root, the efficiency is high, the rhodiola root is sliced equidistantly by the plurality of cutters 502, and the arrangement direction of the rhodiola root is limited by the sliding channel, so that the slicing quality is higher.

In other embodiments, further comprising: the base 1, inclined plate 3 sets up the base 1 upper surface, the inclination of inclined plate 3 is 20~30 ℃, and base 1 is used for with ground fastening, inclined plate 3 passes through support 2 setting on base 1, and inclination can be confirmed according to the test, can make the rhodiola root smooth and easy gliding can.

In other embodiments, the plurality of sliding channels are respectively provided with an infrared sensor 9, and the infrared sensors 9 are disposed between the stay area 401 and the cutting area 402, and are used for detecting whether the rhodiola root moves from the stay area 401 to the cutting area 402, and judging whether the rhodiola root slides from the stay area 401 to the cutting area 402 by using whether the rhodiola root blocks infrared rays.

In other embodiments, the residence area 401 is further provided with a first ventilation hole, the cutting area 402 is provided with a second suction hole and a second ventilation hole, the second suction hole is communicated with the vacuum pump 6 through a gas pipe 8, and the first ventilation hole and the second ventilation hole are communicated with a blower 7 through the gas pipe 8; as shown in fig. 2, the first ventilation holes, the first air suction holes 301, the second ventilation holes and the second air suction holes are distributed in multiple rows, the first ventilation hole rows and the first air suction holes 301 are distributed alternately, the second ventilation hole rows and the second air suction holes are distributed alternately, only the first air suction holes 301 are marked in fig. 2, the first ventilation holes, the second air suction holes and the second ventilation holes are all the same as the first air suction holes 301 in fig. 2, the stay area or the cutting area in fig. 2, the odd rows are the air suction holes, and the even rows are the ventilation holes; by arranging a plurality of air chambers 302 at the bottom of the inclined plate 3, wherein the air chambers 302 are in a cube shape, interfaces which are convenient for connecting the air pipes 8 are arranged on the air chambers 302, and the air chambers 302 are connected together so as to be integrally arranged on the lower surface of the inclined plate 3, and each air chamber 302 is communicated with a row of first vent holes, first air suction holes 301, second vent holes or second air suction holes; the first vent hole is communicated with the blower 7 and is used for blowing air, when the rhodiola root is blocked by the sliding channel, the rhodiola root is promoted to slide downwards by the bottom blowing air, or when the sliding speed is too slow due to the too large friction force of the rhodiola root, the friction force is reduced by the bottom blowing air; the second suction hole is communicated with the vacuum pump 6 and is used for stopping the rhodiola root in the cutting area 402, so that the cutting mechanism 5 can cut the rhodiola root, and the rhodiola root is prevented from being cut in time due to too high sliding speed; the second ventilation hole is communicated with the blower 7, and after cutting is completed, the second ventilation hole blows air, so that the rhodiola rosea slice quickly slides away from the cutting area 402, and the next slicing action is facilitated.

In other embodiments, the air pipe 8 is provided with a solenoid valve 801, the solenoid valve 801 corresponding to the first air suction hole 301 is used for controlling the first air suction hole 301 of each residence zone 401 to suck or not suck air, the solenoid valve 801 corresponding to the first air vent is used for controlling the first air vent of each residence zone 401 to blow or not blow air, when rhodiola rosea roots are moved from the residence zone 401 to the cutting zone 402, the first air suction hole 301 is controlled to suck air, and when rhodiola rosea roots are not moved from the residence zone 401 to the cutting zone 402 within a preset time period, the first air vent is controlled to blow air; the electromagnetic valve 801 is arranged on the air pipe 8 and is used for controlling whether the air blowing hole blows and whether the air suction hole sucks air, and intelligently controlling the slicing process through the processor, when the infrared sensor 9 detects that the rhodiola root moves to the cutting area 402, the rhodiola root exists in the cutting area 402, when the rhodiola root exists in the cutting area 402 of each sliding channel, the cutting mechanism 5 slices the rhodiola root, and the first air suction hole 301 is utilized to suck air, so that the rhodiola root in the staying area 401 stays in the staying area 401 for a short time, and the rhodiola root is prevented from entering the cutting area 402 to influence slicing; and the rhodiola root is not detected within a preset time period, the rhodiola root is blocked in the stay area 401, or cannot slide to the cutting area 402 in time because of overlarge friction force, and at the moment, the first vent holes blow to promote the rhodiola root to slide down to the cutting area 402.

In other embodiments, the solenoid valve 801 corresponding to the second suction hole is used to control the suction or non-suction of the second suction hole of each cutting area 402, the solenoid valve 801 corresponding to the second ventilation hole is used to control the blowing or non-blowing of the second ventilation hole of each cutting area 402, the suction of the second suction hole is controlled before the cutting mechanism 5 performs the cutting action, and the blowing of the second ventilation hole is controlled after the cutting mechanism 5 performs the cutting action; the embodiment further combines the processor to intelligently control the slicing process, after the rhodiola root enters the cutting area 402, the second air suction hole sucks air, the rhodiola root is retained in the cutting area 402, the slicing mechanism 5 is convenient to slice, after the slicing is completed, the second air suction hole stops sucking air, the second air suction hole blows air, and the rhodiola root slice is promoted to slide away from the cutting area 402 rapidly.

In other embodiments, further comprising: the conveyer belt 10 is flush with the upper end of the inclined plate 3 and is also arranged on the base 1 through the bracket 2 and is used for conveying rhodiola root to the inclined plate 3, and the conveyer belt 10 conveys the rhodiola root to the upper end of the inclined plate 3 so as to enable the rhodiola root to slide downwards; alternatively, the roots of rhodiola rosea on the conveyor belt 10 should be spaced a distance that approximately matches the distance between the dwell zone and the cut zone to avoid clogging at the upper end of the inclined plate 3.

The embodiment of the application also provides a rhodiola root slicing process for processing, which uses the rhodiola root slicing process for processing to slice the rhodiola root, specifically, the rhodiola root is fed from the upper end of the inclined plate 3, slides down from the upper end and is separated by a plurality of baffle plates 4, so that each rhodiola root slides down along the length direction, sequentially passes through a stay area 401 and a cutting area 402, is sliced by a cutting mechanism 5 in the cutting area 402, when the rhodiola root already exists in the cutting area 402, the stay area 401 uses a vacuum pump 6 to enable the first air suction hole 301 to suck air, the friction force of the rhodiola root is increased, the rhodiola root is detained in the stay area 401, and after the slicing is completed, the air suction is stopped, so that the rhodiola root slides down to the cutting area 402.

The number of equipment and the scale of processing described herein are intended to simplify the description of the present application. The application, modification and variation of the rhodiola rosea slicing device for processing according to the present application will be apparent to those skilled in the art.

Although embodiments of the present application have been disclosed above, it is not limited to the details and embodiments shown and described, it is well suited to various fields of use for which the application would be readily apparent to those skilled in the art, and accordingly, the application is not limited to the specific details and illustrations shown and described herein, without departing from the general concepts defined in the claims and their equivalents.

Claims

1. The rhodiola root slicing device for processing is characterized by comprising:

an inclined plate;

the plurality of partition boards are vertically arranged on the surface of the inclined plate at intervals, a plurality of sliding channels are formed along the length direction of the inclined plate, the width dimensions of the sliding channels are matched with those of rhodiola root, the sliding channels at least comprise a stay area and a cutting area, the stay area is positioned at the upstream of the cutting area, and a first air suction hole is arranged in the stay area;

the vacuum pump is arranged below the inclined plate and is respectively communicated with the first air suction holes of the residence areas of the sliding channels through air pipes;

the cutting mechanism comprises a fixed plate, a plurality of groups of cutters and a telescopic rod, wherein the cutting mechanism is arranged above the cutting area, the plurality of groups of cutters are arranged on the lower surface of the fixed plate, each group of cutters comprises a plurality of cutters which are arranged at intervals in parallel, each group of cutters corresponds to one sliding channel, and the telescopic rod is connected with the upper surface of the fixed plate and is used for driving the cutting mechanism to move towards the cutting area and executing cutting action on rhodiola root in the cutting area;

further comprises:

the inclined plate is arranged on the upper surface of the base, and the inclination angle of the inclined plate is 20-30 ℃;

an infrared sensor is arranged in the sliding channels, and the infrared sensor is arranged between the stay area and the cutting area and is used for detecting whether rhodiola rosea roots move from the stay area to the cutting area;

the cutting area is provided with a first air suction hole and a first air vent, the first air vent and the first air vent are communicated with a vacuum pump through an air pipe, and the first air vent are communicated with a blower through the air pipe;

the air pipe is provided with an electromagnetic valve, the electromagnetic valve corresponding to the first air suction hole is used for controlling the first air suction hole of each stay zone to suck or not suck, the electromagnetic valve corresponding to the first air vent is used for controlling the first air vent of each stay zone to blow or not blow, when rhodiola rosea roots move from the stay zone to the cutting zone, the first air suction hole is controlled to suck, and when rhodiola rosea roots do not move from the stay zone to the cutting zone within a preset time period, the first air vent is controlled to blow;

the electromagnetic valve corresponding to the second air suction hole is used for controlling the second air suction hole of each cutting area to suck or not suck, the electromagnetic valve corresponding to the second air vent is used for controlling the second air vent of each cutting area to blow or not blow, the second air suction hole is controlled to suck before the cutting mechanism executes the cutting action, and the second air vent is controlled to blow after the cutting mechanism executes the cutting action.

2. The rhodiola rosea slicing apparatus for processing according to claim 1, further comprising:

and the conveying belt is flush with the upper end of the inclined plate and is used for conveying rhodiola root to the inclined plate.

3. The rhodiola rosea slicing process for processing is characterized in that the rhodiola rosea root is sliced by using the rhodiola rosea slicing device for processing according to any one of claims 1-2.