CN112476606B

CN112476606B - Poria cocos diced meat sulfur-free processing device and method with high yield

Info

Publication number: CN112476606B
Application number: CN202011168655.1A
Authority: CN
Inventors: 彭国平; 吴娱
Original assignee: Jingzhou Kangyuan Lingye Technology Co ltd
Current assignee: Jingzhou Kangyuan Lingye Technology Co ltd
Priority date: 2020-10-28
Filing date: 2020-10-28
Publication date: 2022-06-03
Anticipated expiration: 2040-10-28
Also published as: CN112476606A

Abstract

The invention discloses a poria cocos diced meat sulfur-free processing device and method with high yield, and the poria cocos diced meat sulfur-free processing device comprises a processing track and a fixed transverse plate arranged on the processing track, wherein a preprocessing device and a cutting device are sequentially arranged on the processing track from left to right, the end part of the processing track is also provided with a feeding device, the preprocessing device comprises a material pushing device arranged in the processing track, and the preprocessing device comprises an end face cutter arranged above the material pushing device; a transverse cutter and a vertical cutter are arranged on the piston of the first telescopic rod towards the processing track. This scheme pushes away material, material feeding unit's setting through among the preprocessing device, can transport the indian bread to terminal surface cutter department through blevile of push one by one, cuts the terminal surface, cuts the indian bread to suitable size (cut usually to length, width, height are the integral multiple of prediction side's butyl size), can improve the yield of indian bread side's butyl greatly, reduces the indian bread loss, and the practicality is strong.

Description

Poria cocos diced meat sulfur-free processing device and method with high yield

Technical Field

The invention belongs to the technical field of poria cocos processing, and particularly belongs to a poria cocos diced meat sulfur-free processing device and method with high yield.

Background

Poria, also known as Poria cocos, pine tuckahoe and Poria cocos wolf, is a kind of polyporaceae, and mainly has the functions of promoting diuresis, excreting dampness, invigorating spleen and calming heart, and is a fungus. Ancient people called "four-season magical drug" because of its extensive efficacy, and no matter in four seasons, compatibility of Poria with various drugs can exert its unique efficacy regardless of cold, warm, wind and dampness.

At present, will process the indian bread to the square butyl form mostly, be convenient for subsequent processing, transportation and use, but current processingequipment only can directly carry out the cutting of square butyl form to the indian bread, because its surface is the arc, therefore when processing, the volume of blocking of single indian bread is difficult to obtain guaranteeing (be difficult to reach the result of blocking of preferred promptly, the condition that finished product indian bread still exists the arc surface or too much indian bread is amputated often can appear), subsequent processing has not only been influenced, the packing, and simultaneously, the finished product volume of square butyl form indian bread is lower, be not convenient for use.

Disclosure of Invention

The invention aims to: provided are a poria cocos dice sulfur-free processing device and method capable of improving yield of poria cocos dice.

The technical scheme adopted by the invention is as follows:

the poria cocos diced meat sulfur-free processing device with high yield comprises a processing track and a fixed transverse plate arranged on the processing track, wherein a preprocessing device and a cutting device are sequentially arranged on the processing track from left to right, a feeding device is further arranged at the end part of the processing track, the preprocessing device comprises a material pushing device arranged in the processing track, the preprocessing device comprises an end face cutter arranged above the material pushing device, and a driving assembly used for controlling the end face cutter is arranged on the fixed transverse plate; the cutting device comprises a first telescopic rod arranged on the fixed transverse plate, a transverse cutter and a vertical cutter are arranged on a piston of the first telescopic rod and face the machining track, a cutter edge matched with the transverse cutter and the vertical cutter is arranged above the machining track, and a horizontal cutting assembly is further arranged at one end, far away from the feeding device, of the machining track. Preprocessing device's setting, can cut the indian bread in advance to suitable size (cut to length, width, height are the integral multiple of prediction square dice size usually), thereby be convenient for subsequent processing, push away the material, material feeding unit's setting, then be used for transporting the indian bread to terminal surface cutter department through material pushing device one by one, cut the terminal surface, it is horizontal, vertical cutter and horizontal cutting subassembly's setting, then be used for cutting the indian bread to the square dice form, so that subsequent use, above, can improve the yield of indian bread square dice greatly, reduce the indian bread loss, therefore, the clothes hanger is strong in practicability.

Preferably, the feeding device comprises a second telescopic rod arranged at the end part of the processing track, and a feeding hole is further formed in one end, close to the second telescopic rod, of the processing track. The setting of second telescopic link and feed inlet then can push away the indian bread to processing department one by one, and the follow-up processing of being convenient for can set up the conveyer belt feeding in feed inlet department during the in-service use, the continuity of being convenient for operation.

Preferably, the pushing device comprises a third telescopic rod arranged at the bottom end of the processing track, a pushing plate is arranged on a piston of the third telescopic rod, a feeding hole matched with the pushing plate is formed in the side wall of the top end of the processing track, a clamping device is further arranged above the processing track and comprises a fourth telescopic rod and a fifth telescopic rod which are symmetrically arranged, clamping blocks which are in sliding connection with the outer wall of the processing track are arranged on the pistons of the fourth telescopic rod and the fifth telescopic rod, an infrared distance measuring head is further arranged on each clamping block of the piston of the fourth telescopic rod, and the infrared distance measuring head faces towards the clamping block of the piston of the fifth telescopic rod. The setting in third telescopic link, scraping wings and material loading hole then is used for pushing away the indifferently between two clamping blocks with the indifferent tuckahoe to this fixes the tuckahoe, and the length dimension of tuckahoe can then be detected after the clamping tuckahoe to the setting of infrared ray range finding head, thereby is convenient for the terminal surface cutter to carry out the cutting of suitable size to the tuckahoe.

It is worth mentioning that in the cutting process, after the size of the poria cocos is detected, the size can be compared with the preset size, assuming that the preset size is Y and the detected size is X, the size for unilateral excision of the poria cocos can be calculated through a formula of (X-Z X Y)/2, wherein Z is the largest integer, so that the size after excision can be ensured to be the size of the poria cocos capable of obtaining the largest finished product amount, wherein if X is just a multiple of Y, Z is X/Y-1, and a cuboid/cube with the length, width and height being multiples of the preset size can be obtained through three times of cutting.

Preferably, the material pushing plate is hinged with a material blocking plate, a material blocking groove is arranged on the inner wall of the processing track, a hinge column is arranged in the material blocking groove in a sliding mode, and the other end of the material blocking plate is hinged with the hinge column; the middle position of the material pushing plate is further provided with a micro motor, a reversing plate which is rotatably connected with the material pushing plate is arranged on a rotating shaft of the micro motor, and the reversing plate is rotatably connected with the material pushing plate. Striker plate, fender silo, articulated post set up, when the scraping wings is released, can avoid the indian bread to slide to scraping wings below, influence follow-up processing, when the scraping wings is down to the bottom, the striker plate then can automatic re-setting, avoids influencing normal material loading, plays the effect of preventing staying.

Preferably, the driving assembly comprises a driving screw rod horizontally arranged, a driving motor in transmission connection with the driving screw rod is further arranged on the fixed transverse plate, threads at two ends of the driving screw rod are reversely arranged, two screw rod blocks are symmetrically arranged on the driving screw rod, the screw rod blocks are matched with the driving screw rod, a sixth telescopic rod is arranged on each screw rod block, and the end face cutter is fixedly connected with a piston end of the sixth telescopic rod. The arrangement of the driving screw with the two opposite ends, the driving motor, the screw blocks and the end face cutter can control the two screw blocks to synchronously approach/keep away from so as to cut the two ends of the poria cocos, ensure that the cambered surface of the poria cocos is removed as far as possible, and improve the stability of the quality of finished products.

Preferably, a cutting plate is arranged on the first telescopic rod, a transverse cutting block and a vertical cutting block are arranged on the cutting plate, the transverse cutter is arranged on the transverse cutting block in a sliding mode along the left-right direction, and the vertical cutter is arranged on the vertical cutting block in a sliding mode along the front-back direction. The setting of the horizontal cutter, the vertical cutter that two cutting pieces and slip set up is convenient for adjust the cutting size, simultaneously, can be with cuboid/square indian bread cutting to the cuboid that the cross-section is the square.

Preferably, the processing track below still is provided with the material conveyer belt that draws, it is provided with a plurality of material strakes to draw the equidistance interval on the material conveyer belt, draw the material strake to include along a plurality of material poles that perpendicular processing track transported direction parallel arrangement, be provided with on the processing track bottom lateral wall with draw material strake complex material guiding groove, draw the material conveyer belt be applicable to through draw the material strake with raw materials propelling movement extremely cut hole below. The arrangement of the material guiding strakes is used for transporting the poria cocos after the end face is removed, the poria cocos can be guaranteed to be conveyed to the position right below the cutting hole by controlling the stepping of the material guiding conveyor belts through the material guiding strakes arranged at equal intervals, meanwhile, the position of one end face of the tuckahoe is limited through the material guiding strake so as to ensure the transverse cutting size, and when in actual use, the bottom end of the processing track is obliquely arranged, the tuckahoe can be tightly attached to the processing track, the vertical cutting size of the tuckahoe is limited, the horizontal height size of the tuckahoe is limited by the bottom end of the processing track, can guarantee that the cutting size reaches the predetermined value, further improve the yield, in addition, a plurality of guide bars of parallel arrangement can also avoid the indian bread to drop under the circumstances that promotes the indian bread (what the guide groove corresponds also is a plurality of parallel arrangement, can not make the indian bread directly fall), guarantee the stability of transportation.

Preferably, the horizontal cutting subassembly sets up including sliding horizontal sliding plate on the processing track, the last horizontal cutter that is provided with of horizontal sliding plate, processing track top still be provided with horizontal threaded rod and with the horizontal motor that horizontal threaded rod transmission is connected, the cooperation is provided with the regulating block on the horizontal threaded rod, horizontal sliding plate upwards extends the processing track lateral wall with regulating block fixed connection. The horizontal cutter, the horizontal threaded rod and the horizontal motor are arranged, so that the left position and the right position of the horizontal cutter can be indirectly controlled by controlling the horizontal position of the adjusting block through the horizontal motor, and the cutting effect is further ensured.

Preferably, one side of the processing track, which is far away from the feeding device, is also provided with a feed opening, and a material receiving chamber is communicated and arranged below the feed opening. The arrangement of the feed opening and the material receiving chamber is used for collecting the cut poria cocos, and the cut poria cocos can be directly introduced to the next working procedure by adopting conveying devices such as a conveying belt and the like during actual use.

In addition, the invention also discloses a poria cocos diced meat sulfur-free processing method with high yield, which comprises the following steps of processing by using the processing device:

step 1: the feeding port is used for feeding the poria cocos to the material pushing plate through the second telescopic rod:

step 2: controlling a third telescopic rod to push the material pushing plate to a position between the two clamping devices;

and step 3: clamping and fixing the poria cocos through a fourth telescopic rod and a fifth telescopic rod, and detecting the size of the poria cocos through an infrared distance measuring head;

and 4, step 4: calculating the unilateral cutting length of the poria cocos by the formula of (X-Z X Y)/2, and cutting the obtained size by an end face cutter, wherein:

x is the detection size of the infrared ranging head; y is a preset dicing size; z is the maximum integer;

and 5: by retracting and extending the third telescopic rod, the supporting surface of the poria cocos is changed for the first time, and meanwhile, secondary cutting is carried out through the steps 3-4 again;

step 6: changing the supporting surface of the poria cocos for the second time by rotating the reversing plate through the micro motor, simultaneously carrying out three times of cutting through the steps 3-4 again to obtain an intermediate product, withdrawing the third telescopic rod after the cutting is finished, and pushing the intermediate product to the position of the material guiding groove through the second telescopic rod;

and 7: the intermediate products are pushed step by step one by step through the material guiding strakes on the material guiding conveying belt, and the intermediate products are cut in the horizontal direction, the vertical direction and the horizontal direction in sequence in the step process until the intermediate products are completely diced, and the finished products automatically fall into the material receiving chamber.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. according to the invention, through the arrangement of the material pushing and feeding devices in the pretreatment device, the poria cocos can be conveyed to the end face cutter one by one through the material pushing device, the end face is cut, and the poria cocos is cut to a proper size in advance (usually, the poria cocos is cut to a length, a width and a height which are integral multiples of the size of the expected square block), so that the yield of the poria cocos square block can be greatly improved, the loss of the poria cocos is reduced, and the practicability is high.

2. According to the poria cocos cutting device, the third telescopic rod, the material pushing plate and the feeding hole are arranged to push poria cocos between the two clamping blocks individually so as to fix the poria cocos, and the length size of the poria cocos can be detected after the poria cocos is clamped by the infrared distance measuring head, so that the poria cocos can be cut by the end face cutter in a proper size conveniently.

3. According to the invention, through the arrangement of the material baffle plate, the material baffle groove and the hinge column, when the material pushing plate is pushed out, the situation that poria cocos slides below the material pushing plate to influence subsequent processing can be avoided, and when the material pushing plate descends to the bottom end, the material baffle plate can automatically reset to avoid influencing normal feeding, so that the foolproof effect is realized.

4. According to the invention, through the arrangement of the driving screw with two reverse ends, the driving motor, the screw blocks and the end face cutter, the synchronous approaching/synchronous departing actions of the two screw blocks can be controlled, so that the two ends of the poria cocos are cut, the cambered surface of the poria cocos is removed as far as possible, and the stability of the quality of a finished product is improved.

5. According to the poria cocos cutting machine, the poria cocos can be guaranteed to be conveyed to the position under the cutting hole by controlling the stepping of the guiding conveying belt through the guiding row plates arranged at equal intervals, meanwhile, the position of one end face of the poria cocos is limited through the guiding row plates, so that the transverse cutting size is guaranteed.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

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

Fig. 2 is an enlarged schematic view of region a in fig. 1.

Fig. 3 is an enlarged schematic view of the region B in fig. 1.

The mark in the figure is: 1-processing track, 2-fixing transverse plate, 3-end face cutter, 4-first telescopic rod, 5-transverse cutter, 6-vertical cutter, 7-cutting edge, 8-second telescopic rod, 9-feeding hole, 10-third telescopic rod, 11-material pushing plate, 12-feeding hole, 13-fourth telescopic rod, 14-fifth telescopic rod, 15-clamping block, 16-infrared distance measuring head, 17-material blocking plate, 18-material blocking groove, 19-hinged column, 20-micro motor, 21-reversing plate, 22-driving screw, 23-driving motor, 24-screw block, 25-sixth telescopic rod, 26-cutting plate, 27-transverse cutting block, 28-vertical cutting block, 29-material collecting chamber, 30-a material guiding conveyor belt, 31-a material guiding column plate, 32-a material guiding groove, 33-a horizontal sliding plate, 34-a horizontal cutter, 35-a horizontal threaded rod, 36-a horizontal motor, 37-an adjusting block and 38-a discharging opening.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.

It is noted that relational terms such as "first" and "second," and the like, may be 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.

As shown in fig. 1-3, a poria cocos diced meat sulfur-free processing device with a high yield comprises a processing track 1 and a fixed transverse plate 2 arranged on the processing track 1, wherein a preprocessing device and a cutting device are sequentially arranged on the processing track 1 from left to right, a second telescopic rod 8 is further arranged at the end part of the processing track 1, a feeding hole 9 is further formed in one end, close to the second telescopic rod 8, of the processing track 1, the preprocessing device comprises a material pushing device arranged in the processing track 1, the preprocessing device comprises an end face cutter 3 arranged above the material pushing device, and a driving assembly for controlling the end face cutter 3 is arranged on the fixed transverse plate 2; the cutting device comprises a first telescopic rod 4 arranged on the fixed transverse plate 2, a transverse cutter 5 and a vertical cutter 6 are arranged on a piston of the first telescopic rod 4 and face the processing track 1, a cutter opening 7 matched with the transverse cutter 5 and the vertical cutter 6 is arranged above the processing track 1, and a horizontal cutting assembly is further arranged at one end, far away from the feeding device, of the processing track 1; the pushing device comprises a third telescopic rod 10 arranged at the bottom end of the processing track 1, a pushing plate 11 is arranged on a piston of the third telescopic rod 10, a feeding hole 12 matched with the pushing plate 11 is formed in the side wall of the top end of the processing track 1, a clamping device is further arranged above the processing track 1 and comprises a fourth telescopic rod 13 and a fifth telescopic rod 14 which are symmetrically arranged, clamping blocks 15 connected with the outer wall of the processing track 1 in a sliding mode are arranged on the pistons of the fourth telescopic rod 13 and the fifth telescopic rod 14, an infrared distance measuring head 16 is further arranged on the clamping block 15 of the piston of the fourth telescopic rod 13, and the infrared distance measuring head 16 is arranged towards the clamping block 15 of the piston of the fifth telescopic rod 14; a material blocking plate 17 is hinged to the material pushing plate 11, a material blocking groove 18 is arranged on the inner wall of the processing track 1, a hinge column 19 is arranged in the material blocking groove 18 in a sliding mode, and the other end of the material blocking plate 17 is hinged to the hinge column 19; a micro motor 20 is further arranged in the middle of the material pushing plate 11, a reversing plate 21 rotatably connected with the material pushing plate 11 is arranged on a rotating shaft of the micro motor 20, and the reversing plate 21 is rotatably connected with the material pushing plate 11; the driving assembly comprises a driving screw 22 which is horizontally arranged, a driving motor 23 which is in transmission connection with the driving screw 22 is further arranged on the fixed transverse plate 2, threads at two ends of the driving screw 22 are reversely arranged, two screw blocks 24 are symmetrically arranged on the driving screw 22, the screw blocks 24 are matched with the driving screw 22, a sixth telescopic rod 25 is arranged on the screw blocks 24, and the end face cutter 3 is fixedly connected with a piston end of the sixth telescopic rod 25; a cutting plate 26 is arranged on the first telescopic rod 4, a transverse cutting block 27 and a vertical cutting block 28 are arranged on the cutting plate 26, the transverse cutter 5 is arranged on the transverse cutting block 27 in a left-right sliding mode, and the vertical cutter 6 is arranged on the vertical cutting block 28 in a front-back sliding mode; a material guiding conveyor belt 30 is further arranged below the machining track 1, a plurality of material guiding strakes 31 are arranged on the material guiding conveyor belt 30 at equal intervals, each material guiding strake 31 comprises a plurality of material guiding rods which are arranged in parallel along the conveying direction vertical to the machining track 1, a material guiding groove 32 matched with the material guiding strakes 31 is arranged on the side wall of the bottom end of the machining track 1, and the material guiding conveyor belt 30 is suitable for pushing raw materials below the cutting holes through the material guiding strakes 31; the horizontal cutting assembly comprises a horizontal sliding plate 33 which is arranged on the processing track 1 in a sliding mode, a horizontal cutter 34 is arranged on the horizontal sliding plate 33, a horizontal threaded rod 35 and a horizontal motor 36 which is in transmission connection with the horizontal threaded rod 35 are further arranged above the processing track 1, an adjusting block 37 is arranged on the horizontal threaded rod 35 in a matching mode, and the horizontal sliding plate 33 extends upwards through the side wall of the processing track 1 and is fixedly connected with the adjusting block 37; one side of the processing track 1, which is far away from the feeding device, is further provided with a feed opening 38, and a material receiving chamber 29 is communicated below the feed opening 38.

In addition, the invention also discloses a poria cocos diced meat sulfur-free processing method with high yield, which comprises the step of processing by using the processing device.

The processing method of the device specifically comprises the following steps of pushing poria cocos into the processing track 1 from a feeding port, then extending the second telescopic rod 8, pushing the single poria cocos entering the feeding port to the position above the material pushing plate 11, then extending the third telescopic rod 10, simultaneously sliding the hinged columns 19 in the material blocking grooves 18 along the material blocking grooves 18 under the action of tensile force, enabling the material blocking plates 17 to ascend, avoiding the poria cocos from being accidentally clamped at the bottom end of the material pushing plate 11, when the material pushing plate 11 is pushed to a limit position (the poria cocos is positioned between two clamping plates), synchronously extending the fourth and fifth telescopic rods 14, fixing the poria cocos through the clamping plates, uploading the length size after the infrared distance measuring head 16 detects the distance between the two clamping blocks 15, calculating the size of the poria cocos to be cut through a formula (X-Z Y)/2 through a computer (or a system program) and the like, and then controlling the driving motor 23, the driving screw 22 is driven to rotate, after the driving screw is operated to a specified position, the end face cutter 3 is driven to move downwards through the sixth telescopic rod 25, single end face cutting is carried out on the poria cocos, then the fourth telescopic rod 14 and the fifth telescopic rod 14 are retracted, the poria cocos can roll to the cut end face downwards firstly due to the arc-shaped surface, then the actions are stopped, after the poria cocos rolls and is positioned (in the process, the third telescopic rod 10 is controlled to slightly retract and reset to ensure that the poria cocos rolls to the cut end face to be contacted with the material pushing plate 11, meanwhile, the poria cocos is prevented from rolling away from a working area), the fourth telescopic rod 14 and the fifth telescopic rod 14 are controlled to extend out again, after the poria cocos is fixed again through the clamping block 15, the other end face is cut in the same mode, after the cutting is finished, the fourth telescopic rod 14 and the fifth telescopic rod 14 are retracted for two times, at the time, the reversing plate 21 is controlled to rotate 90 degrees through the micro-motor 20, the cut end face faces the clamping block 15, the fourth telescopic rod 14 and the fifth telescopic rod 14 extends out again for clamping, cutting the last two end surfaces, after three times of cutting, obtaining the square poria cocos with the length, width and height being preset size multiples, then withdrawing the third telescopic rod 10, pushing the next poria cocos into the material pushing plate 11 by the second telescopic rod 8, simultaneously pushing the square poria cocos out, repeating the steps until the square poria cocos is pushed to the position of the material guiding groove 32, controlling the material guiding conveying belt 30 to step, conveying the poria cocos to the positions below the transverse cutter 5 and the vertical cutter 6 in sequence through the material guiding column plate 31, cutting the poria cocos through the stretching and withdrawing of the first telescopic rod 4 in the process, controlling the horizontal motion of the adjusting block 37 through the horizontal motor 36 when the poria cocos is about to be conveyed away from the material guiding conveying belt 30, horizontally cutting the poria cocos through the horizontal cutter 34 by taking the material guiding column plate 31 as the bottom surface, then reversely moving the horizontal motor 36, controlling the horizontal cutter 34 to withdraw, and when the material guiding conveying belt 30 moves next time, the poria cocos wolf with the square blocks obtained after three times of cutting is automatically pushed into the material receiving chamber 29 through the material outlet 38, the processing of the square blocks of single poria cocos is completed, and the process of the poria cocos with the square blocks is continuously carried out through repeated processes.

Therefore, through the processing of the equipment, the automation degree is high, the yield of the cubes is guaranteed, and the equipment is suitable for popularization and use.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims

1. The utility model provides a poria cocos side butyl sulfur-free processingequipment that yield is high, is in including processing track (1) and setting fixed diaphragm (2) on processing track (1), by left to right preprocessing device and cutting device have set gradually on processing track (1), the tip of processing track (1) still is provided with material feeding unit, its characterized in that:

the pretreatment device comprises a material pushing device arranged in the processing track (1), the pretreatment device comprises an end face cutter (3) arranged above the material pushing device, and a driving assembly used for controlling the end face cutter (3) is arranged on the fixed transverse plate (2);

the cutting device comprises a first telescopic rod (4) arranged on the fixed transverse plate (2), a transverse cutter (5) and a vertical cutter (6) are arranged on a piston of the first telescopic rod (4) and face the machining track (1), a cutter edge (7) matched with the transverse cutter (5) and the vertical cutter (6) is arranged above the machining track (1), and a horizontal cutting assembly is further arranged at one end, far away from the feeding device, of the machining track (1);

the feeding device comprises a second telescopic rod (8) arranged at the end part of the processing track (1), and a feeding hole (9) is also formed in one end, close to the second telescopic rod (8), of the processing track (1);

the pushing device comprises a third telescopic rod (10) arranged at the bottom end of the processing track (1), a material pushing plate (11) is arranged on a piston of the third telescopic rod (10), a material loading hole (12) matched with the material pushing plate (11) is arranged on the side wall of the top end of the processing track (1), a clamping device is also arranged above the processing track (1), the clamping device comprises a fourth telescopic rod (13) and a fifth telescopic rod (14) which are symmetrically arranged, the pistons of the fourth telescopic rod (13) and the fifth telescopic rod (14) are provided with clamping blocks (15) which are in sliding connection with the outer wall of the processing track (1), an infrared distance measuring head (16) is also arranged on the clamping block (15) of the piston of the fourth telescopic rod (13), the infrared distance measuring head (16) is arranged towards the clamping block (15) of the piston of the fifth telescopic rod (14).

2. The poria cocos diced sulfur-free processing device with high yield according to claim 1, wherein a material baffle plate (17) is hinged on the material pushing plate (11), a material blocking groove (18) is arranged on the inner wall of the processing track (1), a hinge column (19) is slidably arranged in the material blocking groove (18), and the other end of the material baffle plate (17) is hinged with the hinge column (19); the middle position of the material pushing plate (11) is further provided with a micro motor (20), a reversing plate (21) rotatably connected with the material pushing plate (11) is arranged on a rotating shaft of the micro motor (20), and the reversing plate (21) is rotatably connected with the material pushing plate (11).

3. The poria cocos diced meat sulfur-free processing device with high yield according to claim 1, wherein the driving assembly comprises a horizontally arranged driving screw (22), the fixed transverse plate (2) is further provided with a driving motor (23) in transmission connection with the driving screw (22), threads at two ends of the driving screw (22) are reversely arranged, two screw blocks (24) are symmetrically arranged on the driving screw (22), the screw blocks (24) are matched with the driving screw (22), the screw blocks (24) are provided with a sixth telescopic rod (25), and the end face cutter (3) is fixedly connected with a piston end of the sixth telescopic rod (25).

4. The poria cocos dice sulphur-free processing device with high yield according to claim 1, wherein a cutting plate (26) is arranged on the first telescopic rod (4), a transverse cutting block (27) and a vertical cutting block (28) are arranged on the cutting plate (26), the transverse cutter (5) is arranged on the transverse cutting block (27) in a left-right sliding mode, and the vertical cutter (6) is arranged on the vertical cutting block (28) in a front-back sliding mode.

5. The poria cocos diced sulfur-free processing device with high yield according to claim 4, wherein a guiding conveyor belt (30) is further arranged below the processing track (1), a plurality of guiding strakes (31) are arranged on the guiding conveyor belt (30) at equal intervals, the guiding strakes (31) comprise a plurality of guiding rods which are arranged in parallel along the conveying direction of the vertical processing track (1), a guiding groove (32) matched with the guiding strakes (31) is arranged on the side wall of the bottom end of the processing track (1), and the guiding conveyor belt (30) is suitable for pushing raw materials below the cutting hole through the guiding strakes (31).

6. The poria cocos diced sulfur-free processing device with high yield according to claim 5, wherein the horizontal cutting assembly comprises a horizontal sliding plate (33) slidably arranged on the processing track (1), a horizontal cutter (34) is arranged on the horizontal sliding plate (33), a horizontal threaded rod (35) and a horizontal motor (36) in transmission connection with the horizontal threaded rod (35) are further arranged above the processing track (1), an adjusting block (37) is arranged on the horizontal threaded rod (35) in a matching manner, and the horizontal sliding plate (33) extends upwards through the side wall of the processing track (1) and is fixedly connected with the adjusting block (37).

7. The poria cocos dice sulfur-free processing device with the high yield according to claim 1, wherein a feed opening (38) is further formed in one side, away from the feeding device, of the processing rail (1), and a material receiving chamber (29) is communicated with the lower portion of the feed opening (38).

8. The sulfur-free processing method of the poria cocos diced meat with high yield is characterized by comprising the following steps of processing by using a sulfur-free processing device of the poria cocos diced meat with high yield:

and 3, step 3: clamping and fixing the poria cocos through the fourth telescopic rod and the fifth telescopic rod, and detecting the size of the poria cocos through the infrared distance measuring head;

and 6: changing the supporting surface of the poria cocos for the second time through rotation of the reversing plate by the micro motor, simultaneously carrying out three times of cutting in the steps 3-4 again to obtain an intermediate product, withdrawing the third telescopic rod after cutting is finished, and pushing the intermediate product to the position of the material guiding groove through the second telescopic rod;

and 7: the intermediate products are pushed step by step one by step through the material guiding strakes on the material guiding conveying belt, and the intermediate products are cut in the horizontal direction, the vertical direction and the horizontal direction in sequence in the step-by-step process until the intermediate products are completely diced, and the finished products automatically fall into the material receiving chamber.