CN110959391A

CN110959391A - Forage cutting equipment based on mechanical transmission

Info

Publication number: CN110959391A
Application number: CN201911241016.0A
Authority: CN
Inventors: 方军
Original assignee: Anhui Yunshou Data Technology Co Ltd
Current assignee: Wuhu Qianguan Kangyang Agricultural Technology Co.,Ltd.
Priority date: 2019-12-06
Filing date: 2019-12-06
Publication date: 2020-04-07
Anticipated expiration: 2039-12-06
Also published as: CN110959391B

Abstract

The invention relates to the technical field of forage cutting equipment, in particular to forage cutting equipment based on mechanical transmission; a servo motor is adopted as a drive, a first rotating shaft is driven to rotate through the transmission of a transmission wheel, the first rotating shaft drives a second rotating shaft to rotate through the transmission of the transmission wheel, and the forage falling to the blanking section and the bottom end is pushed leftwards by matching with a helical blade; the cutting structure periodically moves up and down to cut the forage; due to the fact that forage on the right side is pushed, the chopped forage gradually moves to the left end and is discharged from the discharge hole, and the situation that discharging is inconvenient is avoided; the baffle plate is driven to move by utilizing the left and right movement of the movable plate, so that intermittent blanking of the blanking section is realized; the stay cord is matched with a spring to drive the placing plate to move left and right by utilizing the up-and-down movement of the U-shaped piece, so that the material receiving basket can uniformly receive materials; the material receiving basket adopts a placing mode, so that the material can be conveniently taken, replaced and cleaned.

Description

Forage cutting equipment based on mechanical transmission

Technical Field

The invention relates to the technical field of forage cutting equipment, in particular to forage cutting equipment based on mechanical transmission.

Background

The breeding industry is a production department for obtaining animal products such as meat, eggs, milk, wool, cashmere, skin, silk and medicinal materials by utilizing the physiological functions of animals such as livestock and poultry which are domesticated by human beings or wild animals such as deer, musk, fox, mink, otter, quail and the like and converting the plant energy such as pasture, feed and the like into animal energy through artificial feeding and breeding. Is an extremely important link for exchanging substances between human beings and the nature. The aquaculture industry is one of the major components of agriculture. The farming industry refers to the production sector of raising livestock to obtain animal products or work animals by grazing, housing or a combination of both. It includes livestock raising, poultry raising, economic animal domestication, etc.

The animal husbandry mainly used for house feeding in the farming area is called farming area breeding. Currently, farming industry in agricultural areas is still a main part of the farming industry in China. In grassland and desert areas, the breeding industry mainly using grazing is called the pasture area breeding industry. The pasture breeding industry is the pasture farming industry which directly grazes the livestock by utilizing the pasture or uses the pasture as a forage grass to mow the livestock.

Most livestock in the breeding industry are herbivores, and thus the forage used is a grass material with a high specific gravity. But the forage is longer due to the production of the forage, and the forage needs to be cut when being fed, so that the palatability is improved, the forage is easy to contact with digestive juice in a digestive system, the digestibility is improved, and the nutritional ingredients of the forage are better absorbed.

The traditional manual cutting mode has high labor intensity and low production efficiency, and can not meet the requirements of the existing cultivation production, so that forage cutting machinery appears in succession.

The Chinese patent with the patent number of CN201810412646.9 discloses a livestock forage cutting device for livestock breeding, which comprises a bearing frame, wherein a driving motor is fixedly installed at the top in the bearing frame in an inverted mode, an output shaft of the driving motor is coaxially and fixedly installed with a driving shaft, a driving belt wheel is fixedly installed on the surface of the driving shaft in a sleeved mode, a rotating shaft penetrating through a turntable is coaxially and fixedly installed on the output shaft of the rotating motor, and a plurality of cutting blades are fixedly installed on the surface of the rotating shaft; a driven bevel gear in meshed connection with the driving bevel gear is coaxially and fixedly installed at the left end of the transmission shaft, and an incomplete gear in meshed connection with the spur rack is fixedly installed on the surface of the transmission shaft in a sleeved mode; according to the invention, the rotating shaft drives the cutting blade to cut and crush forage in the crushing groove, and meanwhile, the turntable rotates along with the rotation, so that the cutting range of the cutting blade is enlarged, the vertical reciprocating motion of the lifting plate promotes the uniform dispersion of the forage, meanwhile, the full contact between the cutting blade and the forage is ensured, and the crushing efficiency of the forage is greatly improved. However, the device sets the crushing procedure in the crushing tank, and according to the description of the specification, the crushing tank adopts a relatively complex installation mode, the corresponding disassembly is relatively difficult, and the forage in the crushing tank is inconvenient to take out, namely the forage is inconvenient to discharge.

Disclosure of Invention

Technical problem to be solved

The invention aims to overcome the defects in the prior art and provides forage cutting equipment based on mechanical transmission.

(II) technical scheme

A forage cutting device based on mechanical transmission comprises a bracket and a cutting drum;

the support comprises a base, a vertical plate, a first support plate and a second support plate, wherein the vertical plate is fixedly connected to the left end of the base, the left side of the vertical plate is connected with the first support plate and the second support plate which are horizontal, and the first support plate and the second support plate are arranged at intervals up and down;

the cutting cylinder comprises a feed hopper at the upper part, a blanking section at the middle section and a cutting section at the lower part; the left side wall of the blanking section is connected with the right ends of the first support plate and the second support plate; the cutting section is horizontally arranged and positioned below the second support plate, the right end of the cutting section is communicated with the bottom end of the blanking section, and the bottom of the left end of the cutting section is provided with a discharge hole; the left part of the cutting section is provided with a cutting structure driven by a reciprocating assembly, and the cutting structure periodically moves up and down;

a servo motor is arranged on the first support plate, the output end of the servo motor horizontally extends out and is connected with a first driving wheel, a second driving wheel is arranged above the first driving wheel, and the first driving wheel and the second driving wheel are in transmission connection through a first transmission belt; the second driving wheel is arranged on the first rotating shaft, and the right end of the first rotating shaft penetrates through the cutting drum and is provided with a third driving wheel; a section of the first rotating shaft, which is positioned in the cutting cylinder, is uniformly provided with stirring rods; the cutting section right part is provided with the pivot No. two, is provided with helical blade in the pivot No. two, and No. two pivot right-hand members stretch out the cutting section and are provided with the drive wheel No. four, and No. three drive wheels and No. four drive wheels are connected through the drive of No. two drive belts.

Preferably, the cutting structure comprises a roller, a wheel fork, a pressure plate, a mounting rod, a second spring and a cutting knife; the roller is arranged on the pressure plate through a wheel fork, the bottom of the pressure plate is connected with an installation rod, and the bottom end of the installation rod extends into the cutting section and is provided with a cutting knife; the outer walls of the pressing plate and the cutting section are also connected with a second spring; the cutting structures are uniformly provided with a plurality of groups along the cutting section.

Preferably, the reciprocating assembly is arranged between the first support plate and the second support plate and comprises a U-shaped piece, a movable rod, a movable plate, a wedge block and an inclined plate, the left part of the second support plate is connected with the inclined plate which inclines downwards to the right through a support rod, the wedge block is overlapped on the right side of the inclined plate in a sliding mode, and the wedge block is connected with the horizontally arranged movable rod; the U-shaped part is inverted, and the right end of the movable rod penetrates through two support legs of the U-shaped part and is provided with a first sliding block; the left side of the movable plate is provided with a first sliding rail, and the first sliding block is connected with the first sliding rail in a sliding manner; the bottom of the movable plate is provided with a plurality of bulges, and the bulges are in rolling contact with the rollers; the top of the movable plate is connected with a second sliding block, the first supporting plate is correspondingly provided with a horizontal second sliding rail, and the second sliding block is connected with the second sliding rail in a sliding mode.

Preferably, the lifting assembly comprises a crank, a sleeve, a first rod and a second rod; a pivot left end is rotated with the riser and is connected, is provided with the crank in the pivot, and the crank is provided with the sleeve, and the sleeve is connected with a pole downwards, and a pole bottom is articulated to have No. two poles, and No. two poles pass a branch and connect the U-shaped spare.

Preferably, the right side of the movable plate is further connected with a baffle through a first connecting rod, and the baffle is inserted into the blanking section from the left side of the blanking section.

Preferably, still including connecing the material subassembly, connect the material subassembly including connecing the charging basket, connect the charging basket to correspond the discharge gate setting in the discharge gate below.

Preferably, the material receiving assembly further comprises a placing plate, a third sliding block, a third sliding rail, a first spring and a pull rope, the third sliding rail is arranged on the base, the third sliding block is arranged at the bottom of the placing plate, and the third sliding block is connected with the third sliding rail in a sliding manner; the material receiving basket is placed on the placing plate; the right end of the base is provided with a third support plate, and the right end of the placing plate is connected with the third support plate through a first spring; the left end of the placing plate is connected with a pull rope, and the pull rope penetrates through the second support plate and is connected with the U-shaped piece.

Preferably, the wire guiding device further comprises a wire guiding assembly, wherein the wire guiding assembly comprises a first wire guiding wheel, a second wire guiding wheel and a third wire guiding wheel, the second wire guiding wheel and the third wire guiding wheel are arranged on the vertical plate at intervals up and down, the third wire guiding wheel is arranged on the bottom surface of the second support plate, and the left end of the pull rope sequentially bypasses the third wire guiding wheel, the second wire guiding wheel and the first wire guiding wheel and is changed from the horizontal direction to the vertical direction; the support legs of the U-shaped part are connected through a second connecting rod, and the pull rope vertically penetrates through the second support plate and is connected with the second connecting rod.

Preferably, the first slide rail and the second slide rail are i-shaped slide rails, and the first slide block and the second slide block are corresponding C-shaped slide blocks.

Preferably, the bottom of the cutting section is provided with a movable door, one end of the movable door is hinged to the cutting section bottom plate, and the other end of the movable door is buckled with the cutting section bottom plate and is locked and fixed through a bolt.

(III) advantageous effects

The invention provides forage cutting equipment based on mechanical transmission, which has the following advantages:

1, a servo motor is adopted as a drive, a first rotating shaft is driven to rotate through the transmission of a driving wheel, the first rotating shaft drives a second rotating shaft to rotate through the transmission of the driving wheel, and the first rotating shaft is matched with a helical blade to push forage falling to a blanking section and the bottom leftwards; the cutting structure periodically moves up and down to cut the forage; because forage propulsion on the right side, the forage that cuts up moves to the left end gradually and discharges from the discharge gate, has avoided the inconvenient condition of row material.

2, the crank throw is driven to move along with the rotation of the first rotating shaft, so that the sleeve drives the second rod to move up and down through the first rod; the U-shaped piece also moves up and down along with the U-shaped piece, and the movable rod moves left when ascending and moves right when descending due to the action of the wedge-shaped block at the left end and the inclined plate; and the movable rod acts with the movable plate through the slide block slide rail, and the movable plate is limited and guided by the slide block slide rail at the top to move left and right, so that the protrusion acts with the cutting structure, the up-and-down movement of the cutting structure is realized, and the cutting is performed.

3, in addition, the baffle is driven to move by utilizing the left and right movement of the movable plate, so that intermittent blanking of the blanking section is realized; the stay cord is matched with a spring to drive the placing plate to move left and right by utilizing the up-and-down movement of the U-shaped piece, so that the material receiving basket can uniformly receive materials; the material receiving basket adopts a placing mode, so that the material can be conveniently taken, replaced and cleaned.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only for the present invention and protect some embodiments, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a block diagram of the present invention;

FIG. 2 is a block diagram of a pull assembly;

FIG. 3 is a block diagram of a cutting drum;

FIG. 4 is a block diagram of the shuttle assembly;

FIG. 5 is a structural diagram of a first slide rail and a first slide block;

fig. 6 is a structural diagram of the receiving assembly.

In the drawings, the components represented by the respective reference numerals are listed below:

1-a base, 101-a vertical plate, 102-a support plate, 1021-a support seat, 103-a support plate and 104-a support plate;

2-cutting cylinder, 201-feeding hopper, 202-blanking section, 203-cutting section, 2031-movable door, 2032-bolt, 2033-handle and 204-discharging port;

3-pulling component, 301-crank, 302-sleeve, 303-rod I, 304-rod II;

4-a servo motor, 401-a first transmission wheel, 402-a first transmission belt, 403-a second transmission wheel, 404-a helical blade, 405-a first rotating shaft, 406-a stirring rod, 407-a third transmission wheel, 408-a second transmission belt, 409-a fourth transmission wheel and 410-a second rotating shaft;

5-reciprocating component, 501-U-shaped piece, 502-movable rod, 503-sloping plate, 504-supporting rod, 505-first sliding block, 506-first sliding rail, 507-movable plate, 508-protrusion, 509-second sliding block, 510-second sliding rail, 511-first connecting rod, 512-baffle, 513-second connecting rod, 514-pulling rope and 515-wedge block;

601-a first wire guide wheel, 602-a second wire guide wheel and 603-a third wire guide wheel;

701-receiving basket, 702-placing plate, 703-third slide block, 704-third slide rail and 705-first spring;

801-roller, 802-wheel fork, 803-pressing plate, 804-mounting rod, 805-spring II and 806-cutting knife.

Detailed Description

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 only a part of the embodiments of the present invention, and not all of the embodiments. 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

A forage cutting device based on mechanical transmission comprises a bracket and a cutting drum 2;

the support comprises a base 1, a vertical plate 101, a first support plate 102 and a second support plate 103, wherein the vertical plate 101 is fixedly connected to the left end of the base 1, the left side of the vertical plate 101 is connected with the first support plate 102 and the second support plate 103 which are horizontal, and the first support plate 102 and the second support plate 103 are arranged at intervals up and down;

the cutting cylinder 2 comprises an upper feed hopper 201, a middle blanking section 202 and a lower cutting section 203; the left side wall of the blanking section 202 is connected with the right ends of the first support plate 102 and the second support plate 103; the cutting section 203 is horizontally arranged and positioned below the second support plate 103, the right end of the cutting section is communicated with the bottom end of the blanking section 202, and the bottom of the left end of the cutting section is provided with a discharge hole 204; the left part of the cutting section 203 is provided with a cutting structure driven by the reciprocating assembly 5, and the cutting structure periodically moves up and down;

the first support plate 102 is provided with a servo motor 4, the output end of the servo motor 4 horizontally extends out and is connected with a first driving wheel 401, a second driving wheel 403 is arranged above the first driving wheel 401, and the first driving wheel 401 and the second driving wheel 403 are in transmission connection through a first transmission belt 402; the second driving wheel 403 is arranged on the first rotating shaft 405, and the right end of the first rotating shaft 405 penetrates through the cutting cylinder 2 and is provided with a third driving wheel 407; a section of the first rotating shaft 405 positioned in the cutting cylinder 2 is uniformly provided with stirring rods 406; the second rotating shaft 410 is arranged at the right part of the cutting section 203, the helical blade 404 is arranged on the second rotating shaft 410, the right end of the second rotating shaft 410 extends out of the cutting section 203 and is provided with a fourth driving wheel 409, and the third driving wheel 407 and the fourth driving wheel 409 are in transmission connection through a second transmission belt 408.

Specifically, the servo motor 4 is started, and the first rotating shaft 405 starts to rotate due to transmission of the transmission wheel; forage is fed from a feed hopper 201, and a stirring rod 406 rotates along with a first rotating shaft 405 to pre-break the forage; the first rotating shaft 405 drives the second rotating shaft 410 to rotate through transmission of the transmission wheel, and the forage falling to the bottom end of the blanking section 202 is pushed leftwards by matching with the helical blade 404; the cutting structure periodically moves up and down to cut the forage; as the forage advances to the right, the forage being chopped gradually moves to the left and is discharged from the discharge outlet 204.

Example 2

The cutting structure comprises a roller 801, a wheel fork 802, a pressure plate 803, a mounting rod 804, a second spring 805 and a cutting knife 806; the roller 801 is arranged on the pressing plate 803 through a wheel fork 802, the bottom of the pressing plate 803 is connected with an installation rod 804, and the bottom end of the installation rod 804 extends into the cutting section 203 and is provided with a cutting knife 806; the outer walls of the pressing plate 803 and the cutting section 203 are also connected with a second spring 805; the cutting structures are uniformly arranged in groups along the cutting segment 203;

the reciprocating assembly 5 is arranged between the first support plate 102 and the second support plate 103 and comprises a U-shaped piece 501, a movable rod 502, a movable plate 507, a wedge block 515 and an inclined plate 503, the left part of the second support plate 103 is connected with the inclined plate 503 inclined downwards to the right through a support rod 504, the wedge block 515 is in sliding lap joint on the right side of the inclined plate 503, and the wedge block 515 is connected with the movable rod 502 arranged horizontally; the U-shaped member 501 is inverted, and the right end of the movable rod 507 passes through two support legs of the U-shaped member 501 and is provided with a first sliding block 505; a first slide rail 506 is arranged on the left side of the movable plate 505, and the first slide block 505 is connected with the first slide rail 506 in a sliding manner; a plurality of protrusions 508 are processed at the bottom of the movable plate 507, and the protrusions 508 are in rolling contact with the rollers 801; the top of the movable plate 507 is connected with a second slider 509, the first support plate 102 is correspondingly provided with a second horizontal slide rail 510, and the second slider 509 is slidably connected with the second slide rail 510. In order to ensure the working stability of the movable plate 507, the first slide rail 506 and the second slide rail 510 are i-shaped slide rails, and the first slider 505 and the second slider 509 are C-shaped sliders, which are engaged with each other to avoid disengagement and achieve sliding connection.

The lifting assembly 3 comprises a crank 301, a sleeve 302, a first rod 303 and a second rod 304; the left end of a first rotating shaft 405 is rotatably connected with the vertical plate 101, a crank 301 is arranged on the first rotating shaft 405, the crank 301 is provided with a sleeve 302, the sleeve 302 is connected with a first rod 303 downwards, the bottom end of the first rod 303 is hinged with a second rod 304, and the second rod 304 penetrates through the first supporting rod 102 and is connected with a U-shaped part 501;

considering the length of the first rotating shaft 405, the support 1021 can be arranged on the first support plate 102, and the first rotating shaft 405 penetrates through and rotates to be connected with the support 1021, so that the stability of the first rotating shaft 405 is ensured.

Specifically, when the first rotating shaft 405 rotates, the crank 301 moves along with the first rotating shaft, so that the sleeve 303 drives the second rod 304 to move up and down through the first rod 303; the U-shaped part 501 also moves up and down, and due to the action of the left end wedge block 515 and the inclined plate 503, the movable rod 501 moves left while ascending, and moves right while descending; and because the movable rod 502 acts with the movable plate 507 through the slider slide rail, and the movable plate 507 is restricted and guided by the slider slide rail at the top so as to move left and right, the protrusion 508 acts with the cutting structure, so that the up-and-down movement of the cutting structure is realized, and the cutting is performed.

Example 3

the right side of the movable plate 507 is further connected with a baffle 512 through a first connecting rod 511, the baffle 512 is inserted into the blanking section 202 from the left side of the blanking section 202, and thus the baffle 512 moves left and right along with the movable plate 507, so that the blanking section 502 is blocked, and the intermittent blanking of forage is realized.

Still including connecing material subassembly 7, connect material subassembly 7 to include and connect material basket 701, connect material basket 701 to correspond discharge gate 204 and set up in discharge gate 204 below for receive kibbling forage.

Example 4

The material receiving assembly 7 further comprises a placing plate 702, a third sliding block 703, a third sliding rail 704, a first spring 705 and a pull rope 514, the third sliding rail 704 is mounted on the base 1, the third sliding block 703 is arranged at the bottom of the placing plate 702, and the third sliding block 703 is slidably connected with the third sliding rail 704; the right end of the base 1 is fixedly connected with a third support plate 104, and the right end of the placing plate 702 is connected with the third support plate 104 through a first spring 705; the left end of the placing plate 702 is connected with a pulling rope 514, and the pulling rope 514 passes through the second support plate 103 and is connected with the U-shaped piece 501.

The wire guiding device further comprises a wire guiding assembly, wherein the wire guiding assembly comprises a first wire guiding wheel 601, a second wire guiding wheel 602 and a third wire guiding wheel 603, the second wire guiding wheel 602 and the third wire guiding wheel 603 are vertically and alternately arranged on the vertical plate 101, the third wire guiding wheel 603 is arranged on the bottom surface of the second support plate 103, and the left end of the pull rope 514 sequentially bypasses the third wire guiding wheel 603, the second wire guiding wheel 602 and the first wire guiding wheel 601 and is changed from the horizontal direction to the vertical direction; the legs of the U-shaped member 501 are connected through a second connecting rod 513, and a pull rope 514 vertically penetrates through the second support plate 103 and is connected with the second connecting rod 513;

specifically, the U-shaped piece 501 moves up and down, and the pull rope 514 is matched with the first spring 705 to drive the placing plate 702 to move left and right, so that uniform material receiving is realized; the receiving basket 701 is placed in a manner of being convenient to take, replace and clear materials.

Considering the possible residue of the cutting segment 203, a movable door 2031 is arranged on the cutting segment 203, the movable door 2031 is provided with a handle 2033, specifically, the movable door 2031 is arranged at the bottom of the cutting segment 203, one end of the movable door 2031 is hinged with the bottom plate of the cutting segment 203, and the other end is fastened with the bottom plate of the cutting segment 203 and is locked and fixed by a bolt 2032. Thus, during cutting, bottom support is ensured; after the cutting is completed, the machine is stopped, the bolt 2032 is unscrewed, and the movable door 2031 is opened to clean the material.

It should be noted that the electrical components are all provided with power supplies, and the control method is the prior art, and is generally described herein for avoiding the redundancy of the description.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims

1. Forage cutting equipment based on mechanical transmission is characterized by comprising a bracket and a cutting drum (104);

the support comprises a base (1), a vertical plate (101), a first support plate (102) and a second support plate (103), wherein the vertical plate (101) is fixedly connected to the left end of the base (1), the left side of the vertical plate (101) is connected with the first support plate (102) and the second support plate (103) which are horizontal, and the first support plate (102) and the second support plate (103) are arranged at intervals up and down;

the cutting cylinder (104) comprises an upper feed hopper (201), a middle blanking section (202) and a lower cutting section (203); the left side wall of the blanking section (202) is connected with the right ends of a first support plate (102) and a second support plate (103); the cutting section (203) is horizontally arranged and positioned below the second support plate (103), the right end of the cutting section is communicated with the bottom end of the blanking section (202), and the bottom of the left end of the cutting section is provided with a discharge hole (204); the left part of the cutting section (203) is provided with a cutting structure driven by a reciprocating assembly (5), and the cutting structure periodically moves up and down;

the first support plate (102) is provided with a servo motor (4), the output end of the servo motor (4) horizontally extends out and is connected with a first driving wheel (401), a second driving wheel (403) is arranged above the first driving wheel (401), and the first driving wheel (401) is in transmission connection with the second driving wheel (403) through a first transmission belt (402); the second driving wheel (403) is arranged on the first rotating shaft (405), and the right end of the first rotating shaft (405) penetrates through the cutting drum (104) and is provided with a third driving wheel (407); a section of the first rotating shaft (405) positioned in the cutting cylinder (104) is uniformly provided with stirring rods (406); the right part of the cutting section (203) is provided with a second rotating shaft (410), the second rotating shaft (410) is provided with a helical blade (404), the right end of the second rotating shaft (410) extends out of the cutting section (203) and is provided with a fourth driving wheel (409), and the third driving wheel (407) and the fourth driving wheel (409) are in transmission connection through a second transmission belt (408).

2. A fodder cutting device based on mechanical transmission, characterized in that the cutting structure comprises a roller (801), a wheel fork (802), a pressure plate (803), a mounting rod (804), a second spring (805) and a cutter (806); the roller (801) is installed on the pressing plate (803) through a wheel fork (802), the bottom of the pressing plate (803) is connected with an installation rod (804), and the bottom end of the installation rod (804) extends into the cutting section (203) and is provided with a cutting knife (806); the outer walls of the pressing plate (803) and the cutting section (203) are also connected with a second spring (805); the cutting structures are evenly arranged in groups along the cutting section (203).

3. The forage cutting equipment based on mechanical transmission as claimed in claim 2, wherein the reciprocating assembly (5) is arranged between a first support plate (102) and a second support plate (103), and comprises a U-shaped piece (501), a movable rod (502), a movable plate (507), a wedge block (515) and a sloping plate (503), wherein the left part of the second support plate (103) is connected with the sloping plate (503) which inclines downwards to the right through a support rod (504), the right side of the sloping plate is slidably overlapped with the wedge block (515), and the wedge block (515) is connected with the horizontally arranged movable rod (502); the U-shaped part (501) is inverted, and the right end of the movable rod (502) penetrates through two support legs of the U-shaped part (501) and is provided with a first sliding block (505); a first sliding rail (506) is arranged on the left side of the movable plate (507), and a first sliding block (505) is connected with the first sliding rail (506) in a sliding manner; a plurality of protrusions (508) are arranged at the bottom of the movable plate (507), and the protrusions (508) are in rolling contact with the rollers (801); no. two sliders (509) are connected to the top of the movable plate (507), a horizontal No. two sliding rails (510) are correspondingly arranged on the first support plate (102), and the No. two sliders (509) are slidably connected with the No. two sliding rails (510).

4. A fodder cutting apparatus based on mechanical transmission, characterized by further comprising a pulling assembly (3), said pulling assembly (3) comprising a bell crank (301), a sleeve (302), a first rod (303) and a second rod (304); the left end of the first rotating shaft (405) is rotatably connected with the vertical plate (101), a crank (301) is arranged on the first rotating shaft (405), the crank (301) is provided with a sleeve (302), the sleeve (302) is downwards connected with a first rod (303), the bottom end of the first rod (303) is hinged with a second rod (304), and the second rod (304) penetrates through a first supporting rod (504) and is connected with a U-shaped piece (501).

5. A fodder cutting apparatus based on mechanical transmission, characterized in that the right side of the movable plate (507) is connected with a baffle (512) through a first connecting rod (511), the baffle (512) is inserted into the blanking section (202) from the left side of the blanking section (202).

6. A fodder cutting device based on mechanical transmission, characterized in that, it also includes receiving assembly, the receiving assembly includes receiving basket (701), receiving basket (701) corresponds discharge gate (204) and sets up below discharge gate (204).

7. The forage cutting equipment based on mechanical transmission according to claim 6, wherein the receiving assembly further comprises a placing plate (702), a third sliding block (703), a third sliding rail (704), a first spring (705) and a pull rope (514), the third sliding rail (704) is arranged on the base (1), the third sliding block (703) is arranged at the bottom of the placing plate (702), and the third sliding block (703) is slidably connected with the third sliding rail (704); the receiving basket (701) is placed on a placing plate (702); the right end of the base (1) is provided with a third support plate (104), and the right end of the placing plate (702) is connected with the third support plate (104) through a first spring (705); the left end of the placing plate (702) is connected with a pull rope (514), and the pull rope (514) penetrates through the second support plate (103) and is connected with the U-shaped piece (501).

8. The forage cutting equipment based on mechanical transmission as claimed in claim 7, further comprising a wire guiding assembly, wherein the wire guiding assembly comprises a first wire guiding wheel (601), a second wire guiding wheel (602) and a third wire guiding wheel (603), the second wire guiding wheel (602) and the third wire guiding wheel (603) are arranged on the vertical plate (101) at intervals up and down, the third wire guiding wheel (603) is arranged on the bottom surface of the second supporting plate (103), and the left end of the pull rope (514) sequentially bypasses the third wire guiding wheel (603), the second wire guiding wheel (602) and the first wire guiding wheel (601) and is changed from the horizontal direction to the vertical direction; the support legs of the U-shaped piece (501) are connected through a second connecting rod (513), and the pull rope (514) vertically penetrates through the second support plate (103) and is connected with the second connecting rod (513).

9. A fodder cutting device based on mechanical transmission, according to claim 8, characterized in that the first and second sliding rails (506, 510) are I-shaped sliding rails, and the first and second sliding blocks (505, 509) are corresponding C-shaped sliding blocks.

10. A forage cutting apparatus based on mechanical transmission according to claim 9, wherein the bottom of the cutting section (203) is provided with a movable door (2031), one end of the movable door (2031) is hinged with the bottom plate of the cutting section (203), and the other end is buckled with the bottom plate of the cutting section (203) and locked and fixed by a bolt (2032).