CN112567906A - Mulching film cutting and recycling device - Google Patents

Abstract

The invention relates to the field of waste plastic film recovery processing equipment, and discloses a mulching film cutting and recovery device which comprises a machine body, wherein the rear end surface of the machine body is fixedly connected with a left support body, the front end surface of the machine body is fixedly connected with a right support body, the lower end surfaces of the left support body and the right support body are fixedly connected with a film raising block, mulching film passing cavities which penetrate through the left support body and the right support body in the front and back direction and are provided with downward openings are arranged in the left support body and the right support body, sand and soil on the mulching film can be removed before the mulching film is recovered through a vibrating block which vibrates in a reciprocating manner, the subsequent winding operation is convenient, the mulching film is cut through high-temperature cutting after electrification, the recovery and winding of the mulching film are completed by matching with the rotation of a winding drum, the occurrence of the situation that crops are clamped by mulching film holes after the mulching, thereby achieving the effect of recovering mulching films of different crops.

Description

Mulching film cutting and recycling device

Technical Field

The invention relates to the related field of waste plastic film recovery processing equipment, in particular to a mulching film cutting and recovering device.

Background

The plastic film can be laid in order to play in order to protect soil, efficiency such as weed control to crops planting process kind mostly, can open the hole in order to plant the crop on the plastic film when the plastic film is laid, present plastic film is retrieved the direct rolling of plastic film through the coiling mechanism mostly when retrieving, but because crops pass through a period of growth, the volume of itself mostly can be greater than the hole opened in order to plant when laying, and then lead to the plastic film in the recovery process plant existence by the possibility of plastic film hole card-out, it also can cause the injury to the crop to pull the plastic film by force.

Disclosure of Invention

The invention aims to provide a mulching film cutting and recycling device which can overcome the defects in the prior art, so that the practicability of equipment is improved.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a mulching film cutting and recycling device which comprises a machine body, wherein a left support body is fixedly connected to the rear end surface of the machine body, a right support body is fixedly connected to the front end surface of the machine body, film raising blocks are fixedly connected to the lower end surfaces of the left support body and the right support body, mulching film passing cavities which penetrate through the left support body and the right support body in the front and back direction and are provided with downward openings are respectively arranged in the left support body and the right support body, a connecting body is fixedly connected between the left support body and the right support body, a bevel gear cavity is arranged in the left support body, a moving shaft sliding cavity is communicated with the rear end wall of the bevel gear cavity, a magnet cavity is communicated with the rear end wall of the moving shaft sliding cavity, a thread block sliding cavity which opens towards the left direction and is provided with a downward opening is arranged in the connecting body, and a, a spline cavity with a backward opening is arranged in the spline shaft, a movable gear shaft extending backwards and penetrating through the bevel gear cavity to the movable shaft sliding cavity is connected in a spline fit manner in the spline cavity, a spline spring is fixedly connected between the front end face of the movable gear shaft and the front end wall of the spline cavity, the tail end of the rear side of the movable gear shaft is fixedly connected with a movable magnet block positioned in the movable shaft sliding cavity, a connecting block is connected in a sliding fit manner in the magnet cavity, a suction magnet positioned in the magnet cavity is fixedly connected to the right end face of the connecting block, a suction spring is fixedly connected between the right end face of the suction magnet and the right end wall of the magnet cavity, a repulsion magnet positioned in the magnet cavity is fixedly connected to the left end face of the connecting block, a repulsion spring is fixedly connected between the left end face of the repulsion magnet and the left end wall of the magnet cavity, the movable gear shaft is fixedly connected with a forward rotation helical gear which is positioned in the helical gear cavity and on the front side of the reverse rotation helical gear, the spline shaft is connected with four thread blocks which are positioned in the thread block sliding cavity in a sliding fit mode, and the lower end face of each thread block is fixedly connected with a cutting body which is positioned on the left side of the machine body.

On the basis of the technical scheme, a containing cavity which extends rightwards and is provided with a backward opening is arranged in the cutting body, a rotating shaft which extends upwards into the containing cavity is fixedly connected in the lower end wall of the containing cavity, a probe rod which extends backwards to the outside is arranged in the containing cavity, a torsion spring which is positioned in the containing cavity is fixedly connected between the upper end surface of the probe rod and the lower end wall of the containing cavity, a rotating cavity with a downward opening is arranged in the containing cavity, the rotating cavity is connected with the rotating shaft in a rotating fit manner, the rear end wall of the rotating cavity is communicated with a lifting transmission cavity, a lifting cavity is arranged on the left side of the probe rod in a penetrating manner from top to bottom, a cutting needle is connected in a sliding fit manner in the lifting cavity, a lifting wheel which is positioned in the lifting transmission cavity is connected on the cutting needle in a threaded fit manner, and a rotating wheel fixing shaft which extends upwards through the lifting transmission cavity, the fixed shaft of the rotating wheel is fixedly connected with a rotating wheel which is positioned in the lifting transmission cavity and meshed with the rotating shaft, the upper end face of the rotating wheel is fixedly connected with a lifting output wheel which is positioned in the lifting transmission cavity and fixedly connected with the rotating wheel fixed shaft, and the lifting output wheel is in power fit connection with a lifting synchronous belt between the lifting wheels.

On the basis of the technical scheme, a belt wheel cavity is arranged in the machine body, two winding drum cavities with openings far away from the side direction of the belt wheel cavity are symmetrically arranged in the machine body around the belt wheel cavity as the center, a power output cavity is communicated with the front end wall of the belt wheel cavity, a driving motor positioned at the rear side of the power output cavity is arranged in the machine body, the front end surface of the driving motor is fixedly connected with an output wheel fixing shaft which extends forwards and penetrates through the power output cavity to the front end wall of the power output cavity, the power output wheel positioned in the power output cavity is fixedly connected to the output wheel fixing shaft, the rear end wall of the belt wheel cavity is connected with a winding drum shaft which rotates backwards and extends forwards into the winding drum cavity at the rear side and penetrates through the belt wheel cavity to the winding drum cavity at the front side in a matched manner, and a winding drum positioned in the winding drum cavity is fixedly, fixedly connected with is located on the reel shaft the double belt pulley of band pulley intracavity, the double belt pulley with power fit is connected with power transmission belt between the power take-off wheel, be equipped with left output chamber in the left supporter, be equipped with right output chamber in the right supporter, left side output chamber rear end wall normal running fit is connected with and extends forward and runs through left side output chamber the band pulley chamber with right side output chamber extremely the driving shaft in the right side output chamber front end wall, fixedly connected with is located on the driving shaft the left output wheel of left side output intracavity, fixedly connected with is located on the driving shaft the band pulley intracavity just is located the action wheel of double belt pulley downside, fixedly connected with is located on the driving shaft the right output wheel of right side output intracavity, the action wheel with power fit is connected with the action wheel drive belt between the double belt pulley.

On the basis of the technical scheme, the left support body and the right support body are internally provided with an intersection cavity, the upper end wall of the intersection cavity is respectively communicated with a left output cavity and a right output cavity which extend upwards, the upper end wall of the intersection cavity is communicated with two vibration output cavities which are respectively positioned at the rear side of the left output cavity and the front side of the right output cavity, the upper end wall of the intersection cavity is communicated with two conveying cavities which are respectively positioned at the front side of the left output cavity and the rear side of the right output cavity, the upper end wall of the intersection cavity at the rear side is communicated with a steering driving cavity which is positioned at the rear side of the conveying cavity, the end wall of the conveying cavity far away from the belt wheel cavity side is rotatably and cooperatively connected with a main conveying wheel shaft which extends to the direction close to the belt wheel cavity side into the end wall of the conveying cavity close to the belt wheel cavity side, and a main conveying wheel positioned in the conveying cavity, the intersection cavity is far away from the side end wall of the belt wheel cavity and is connected with a multi-wheel fixed shaft which extends and penetrates through the intersection cavity to the intersection cavity in the direction close to the side end wall of the belt wheel cavity in a rotating fit manner, the multi-wheel fixed shaft is fixedly connected with a vibration output wheel which is positioned in the intersection cavity and corresponds to the vibration output cavity, a cam cavity positioned at the lower side of the conveying cavity is arranged in the diaphragm raising block, the vibration output cavity is close to the side end wall of the belt wheel cavity and is connected with a cam shaft which extends and penetrates through the vibration output cavity to the cam cavity in the direction far from the side of the belt wheel cavity in a rotating fit manner, the cam shaft is fixedly connected with a vibration driving wheel positioned in the vibration output cavity, a vibration wheel synchronous belt is connected between the vibration driving wheel and the vibration output wheel in a power fit manner, and a conveying auxiliary wheel which is positioned in the intersection cavity, the conveying main wheel shaft is fixedly connected with a conveying main wheel positioned in the conveying cavity, the conveying auxiliary wheel and the conveying main wheel are connected with a conveying belt in a power fit mode, the multi-wheel fixing shaft is fixedly connected with a driving wheel positioned in the intersection cavity and corresponding to the left output cavity and the right output cavity respectively, the driving wheel at the rear side and the left output wheel are connected with a left power belt in a power fit mode, and the driving wheel at the front side and the right output wheel are connected with a right power belt in a power fit mode.

On the basis of the technical scheme, the rear end surface of the rear side of the transmission auxiliary wheel is fixedly connected with an adjusting wheel which is positioned in the intersection cavity and corresponds to the steering driving cavity, a steering gear cavity which is positioned on the front side of the steering driving cavity and is positioned on the upper side of the helical gear cavity is arranged in the left support body, a steering driving shaft which extends forwards to penetrate through the steering driving cavity to the steering gear cavity is connected in a rotating fit manner on the rear end wall of the steering driving cavity, a steering driving wheel which is positioned in the steering driving cavity is fixedly connected on the steering driving shaft, a driving synchronous belt is connected between the steering driving wheel and the adjusting wheel in a power fit manner, a steering helical gear which is positioned in the steering gear cavity is fixedly connected on the steering driving shaft, and an output gear shaft which extends upwards to the steering gear cavity and downwards to the helical gear cavity is connected in a, the tail end of the upper side of the output gear shaft is fixedly connected with an output helical gear which is positioned in the steering gear cavity and is meshed with the steering gear cavity, and the tail end of the lower side of the output gear shaft is fixedly connected with a driving helical gear which is positioned in the helical gear cavity and can be meshed with the reverse helical gear and the forward helical gear.

On the basis of the technical scheme, fixedly connected with is located on the camshaft cam of cam intracavity, cam intracavity sliding fit be connected with the push pedal that the cam offseted, cam chamber upper end wall intercommunication is equipped with vibrating arm sliding chamber, vibrating arm sliding chamber upper end wall intercommunication is equipped with the ascending vibrating mass sliding chamber of opening, push pedal up end fixedly connected with runs through vibrating arm sliding chamber extremely vibrating mass sliding chamber in and with the push rod that vibrating arm sliding chamber sliding fit connects, the terminal fixedly connected with of push rod upside be located vibrating mass sliding chamber in and with the vibrating mass that vibrating mass sliding chamber sliding fit connects, under the vibrating mass terminal surface with fixedly connected with vibrating spring between the vibrating mass sliding chamber lower extreme wall.

On the basis of the technical scheme, a slider cavity is arranged in the thread block, a slider capable of being in threaded fit connection with the spline shaft is connected in the slider cavity in a sliding fit manner, a slider spring is fixedly connected between the left end face of the slider and the left end wall of the slider cavity, an adjusting button cavity with an upward opening is arranged in the cutting body, an adjusting button is connected in the adjusting button cavity in a sliding fit manner, an adjusting spring is fixedly connected between the lower end face of the adjusting button and the lower end wall of the adjusting button cavity, an adjusting pull rope is fixedly connected between the lower end face of the adjusting button and the left end face of the slider, a forward and reverse button cavity with a backward opening is arranged in the left supporting body, two pushing block sliding cavities which are arranged at equal intervals up and down are communicated with the front end wall of the forward and reverse button cavity, and, the push button fixing shaft is connected with a forward and reverse rotation button in a forward and reverse rotation button cavity in a rotating fit mode, the push block sliding cavity at the upper side is connected with a forward rotation push block capable of abutting against the forward and reverse rotation button in a sliding fit mode, a forward rotation spring is fixedly connected between the front end face of the forward rotation push block and the front end wall of the push block sliding cavity at the upper side, a forward rotation pull rope is fixedly connected between the front end face of the forward rotation push block and the right end face of the suction magnet, a reverse rotation push block capable of abutting against the forward and reverse rotation button is connected in the push block sliding cavity at the lower side in a sliding fit mode, a reverse rotation spring is fixedly connected between the front end face of the reverse rotation push block and the front end wall of the push block sliding cavity at the lower side, and.

The invention has the beneficial effects that: through reciprocating vibration's vibrating mass, can clear away the sand on the plastic film before the plastic film is retrieved, the follow-up rolling operation of being convenient for, high temperature cuts to the plastic film through the circular telegram after, the cooperation reel rotates and accomplishes the recovery rolling to the plastic film, can avoid the crop to take place by the condition that the plastic film hole blocked after the plastic film is separated, the probe rod can respond to the crop and dodge, avoid cutting the needle damage crop, the cutting needle position can be adjusted according to the plastic film hole difference in position, thereby reach the effect of retrieving different crop plastic films.

Drawings

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

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of the overall structure of a mulching film cutting and recycling device of the present invention.

Fig. 2 is a schematic sectional view at a-a in fig. 1.

Fig. 3 is a schematic sectional view at B-B in fig. 1.

Fig. 4 is a schematic sectional view at C-C in fig. 1.

Fig. 5 is a schematic cross-sectional view at D-D in fig. 1.

Fig. 6 is a schematic sectional view at E-E in fig. 1.

Fig. 7 is a schematic sectional view at F-F in fig. 4.

Fig. 8 is an enlarged schematic view of the structure at G in fig. 4.

Fig. 9 is an enlarged schematic view of the structure at H in fig. 4.

Fig. 10 is a schematic sectional view at I-I in fig. 8.

Fig. 11 is a schematic sectional view at J-J in fig. 2.

Detailed Description

The invention will now be described in detail with reference to fig. 1-11, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Combine fig. 1-11 a mulching film cutting recovery unit, including organism 26, organism 26 rear end face fixedly connected with left supporter 20, 13 front end face fixedly connected with right supporter 27, left side supporter 20 with right supporter 27 is the equal fixedly connected with of terminal surface plays membrane piece 18 down, left side supporter 20 with it runs through and the decurrent plastic film of opening passes through chamber 10 all around being equipped with in the right supporter 27, left side supporter 20 with fixedly connected with connector 37 between the right supporter 27, be equipped with bevel gear chamber 102 in the left side supporter 20, bevel gear chamber 102 rear end wall intercommunication is equipped with removal axle sliding chamber 104, removal axle sliding chamber 104 rear end wall intercommunication is equipped with magnet chamber 100, be equipped with opening left and the decurrent screw thread piece sliding chamber 39 of opening in the connector 37, bevel gear chamber 102 front end wall normal running fit is connected with and extends forward and runs through screw piece sliding chamber 39 to screw piece sliding chamber 39 front end wall An inner spline shaft 41, a spline cavity 106 with a backward opening is arranged in the spline shaft 41, a spline spring 105 is fixedly connected between the front end face of the movable gear shaft 97 and the front end wall of the spline cavity 106 and extends backwards to penetrate through the bevel gear cavity 102 to the movable gear shaft 97 in the movable shaft sliding cavity 104 in a matched manner in the spline cavity 106, a movable magnet block 91 positioned in the movable shaft sliding cavity 104 is fixedly connected to the rear end of the movable gear shaft 97 in a matched manner, a connecting block 84 is connected in the magnet cavity 100 in a matched manner, a suction magnet 85 positioned in the magnet cavity 100 is fixedly connected to the right end face of the connecting block 84, a suction spring 86 is fixedly connected between the right end face of the suction magnet 85 and the right end wall of the magnet cavity 100, a repulsion magnet 98 positioned in the magnet cavity 100 is fixedly connected to the left end face of the connecting block 84, a repulsion magnet 99 is fixedly connected between the left end face of the repulsion magnet, the movable gear shaft 97 is fixedly connected with a reverse helical gear 101 located in the helical gear cavity 102, the movable gear shaft 97 is fixedly connected with a forward helical gear 103 located in the helical gear cavity 102 and located in front of the reverse helical gear 101, the spline shaft 41 is connected with four threaded blocks 38 located in the threaded block sliding cavities 39 in a sliding fit manner, and the lower end face of each threaded block 38 is fixedly connected with a cutting body 40 located on the left side of the machine body 26.

In addition, in an embodiment, a containing cavity 80 extending rightwards and having a backward opening is arranged in the cutting body 40, a rotating shaft 83 in the containing cavity 80 is upwards connected to the inner end wall of the lower end wall of the containing cavity 80, a probe 81 extending backwards to the outside is arranged in the containing cavity 80, the upper end surface of the probe 81 is fixedly connected with a torsion spring 79 positioned in the containing cavity 80 and between the lower end walls of the containing cavity 80, a rotating cavity 78 with a downward opening is arranged in the containing cavity, the rotating cavity 78 is connected with the rotating shaft 83 in a rotating fit manner, a lifting transmission cavity 75 is communicated with the rear end wall of the rotating cavity 78, a lifting cavity 109 penetrates through the left side of the probe 81 from top to bottom, a cutting needle 73 is connected to the lifting cavity 109 in a sliding fit manner, a lifting wheel 74 positioned in the lifting transmission cavity 75 is connected to the cutting needle 73 in a threaded fit manner, and a lifting transmission cavity 75 is connected to the lower end wall of the lifting transmission cavity 75 in a The interior rotation of lift transmission chamber 75 upper end wall takes turns fixed axle 110, rotate on the wheel fixed axle 110 fixedly connected with be located in lift transmission chamber 75 and with the rotation wheel 82 of axis of rotation 83 meshing, it is located to rotate wheel 82 up end fixedly connected with lift output wheel 77 that takes turns fixed axle 110 fixed connection just with rotating in the lift transmission chamber 75, lift output wheel 77 with power fit is connected with lift hold-in range 76 between the lift wheel 74.

In addition, in one embodiment, a pulley cavity 22 is disposed in the machine body 26, two reel cavities 15 opening in the direction away from the pulley cavity 22 are symmetrically disposed in the machine body 26 in the front-back direction with the pulley cavity 22 as the center, a power output cavity 113 is disposed in the front end wall of the pulley cavity 22 in communication with the front end wall of the pulley cavity, a driving motor 21 disposed at the rear side of the power output cavity 113 is disposed in the machine body 26, an output wheel fixing shaft 114 extending forward through the power output cavity 113 to the front end wall of the power output cavity 113 is fixedly connected to the front end surface of the driving motor 21, a power output wheel 111 disposed in the power output cavity 113 is fixedly connected to the output wheel fixing shaft 114, a reel shaft 25 extending backward into the reel cavity 15 at the rear side and extending forward through the pulley cavity 22 to the reel cavity 15 at the front side is rotatably connected to the rear end wall of the pulley cavity 22 in a matching manner, the winding drum is characterized in that a winding drum 14 located in the winding drum cavity 15 is fixedly connected to the winding drum shaft 25, a double belt pulley 23 located in the belt pulley cavity 22 is fixedly connected to the winding drum shaft 25, a power transmission belt 112 is connected between the double belt pulley 23 and the power output wheel 111 in a power fit manner, a left output cavity 29 is arranged in the left support body 20, a right output cavity 32 is arranged in the right support body 27, a driving shaft 35 which extends forwards through the left output cavity 29, the belt pulley cavity 22 and the right output cavity 32 to the front end wall of the right output cavity 32 is connected to the rear end wall of the left output cavity 29 in a rotating fit manner, a left output wheel 28 located in the left output cavity 29 is fixedly connected to the driving shaft 35, a driving wheel 34 located in the belt pulley cavity 22 and located on the lower side of the double belt pulley 23 is fixedly connected to the driving shaft 35, a right output wheel 36 located in the right output cavity 32 is fixedly connected to the driving shaft 35, a driving wheel transmission belt 31 is connected between the driving wheel 34 and the double belt wheel 23 in a power fit manner.

In addition, in one embodiment, a junction cavity 115 is provided in each of the left support body 20 and the right support body 27, an upper end wall of the junction cavity 115 is respectively provided with a left output cavity 29 and a right output cavity 32 which extend upwards in a communicating manner, an upper end wall of the junction cavity 115 is provided with two vibration output cavities 53 which are respectively positioned at the rear side of the left output cavity 29 and the front side of the right output cavity 32 in a communicating manner, an upper end wall of the junction cavity 115 is provided with two transfer cavities 19 which are respectively positioned at the front side of the left output cavity 29 and the rear side of the right output cavity 32 in a communicating manner, an upper end wall of the junction cavity 115 at the rear side is provided with a steering driving cavity 89 which is positioned at the rear side of the transfer cavity 19, the transfer cavity 19 is far away from the side end wall of the pulley cavity 22 and is connected with a main transfer pulley shaft 17 which extends towards the side of the pulley cavity 22 and into the end wall of the transfer cavity 19 close to, the main transmission wheel shaft 17 is fixedly connected with a main transmission wheel 16 positioned in the transmission cavity 19, the intersection cavity 115 is connected with a multi-wheel fixed shaft 11 which is far away from the side end wall of the pulley cavity 22 in a rotating fit manner and extends through the intersection cavity 115 in the direction close to the pulley cavity 22 to the intersection cavity 115 in the direction close to the side end wall of the pulley cavity 22, the multi-wheel fixed shaft 11 is fixedly connected with a vibration output wheel 46 which is positioned in the intersection cavity 115 and corresponds to the vibration output cavity 53, a cam cavity 56 positioned at the lower side of the transmission cavity 19 is arranged in the film raising block 18, the vibration output cavity 53 is connected with a cam shaft 57 which is close to the side end wall of the pulley cavity 22 in a rotating fit manner and extends through the vibration output cavity 53 in the direction far away from the pulley cavity 22 to the cam cavity 56, and the cam shaft 57 is fixedly connected with a vibration driving wheel 54 positioned in the vibration output cavity 53, vibration drive wheel 54 with power fit is connected with vibration wheel hold-in range 45 between vibration output wheel 46, fixedly connected with is located on the many rounds of fixed axles 11 in intersect chamber 115 and with the corresponding conveying auxiliary wheel 43 in conveying chamber 19, fixedly connected with is located on the conveying main wheel axle 17 conveying main wheel 16 in conveying chamber 19, conveying auxiliary wheel 43 with power fit is connected with conveyer belt 12 between the conveying main wheel 16, fixedly connected with is located on the many rounds of fixed axles 11 intersect chamber 115 and respectively with left output chamber 29 with the corresponding drive wheel 44 in right output chamber 32, the rear side drive wheel 44 with power fit is connected with left power belt 30 between the left output wheel 28, the front side drive wheel 44 with power fit is connected with right power belt 33 between the right output wheel 36.

In addition, in an embodiment, the rear end surface of the rear side of the transmission auxiliary wheel 43 is fixedly connected with an adjusting wheel 42 which is located in the intersection cavity 115 and corresponds to the steering driving cavity 89, a steering gear cavity 93 which is located in the front side of the steering driving cavity 89 and is located on the upper side of the bevel gear cavity 102 is arranged in the left supporting body 20, a steering driving shaft 87 which extends forwards through the steering driving cavity 89 to the steering gear cavity 93 is connected in a rotationally matched manner in the rear end wall of the steering driving cavity 89, a steering driving wheel 88 which is located in the steering driving cavity 89 is fixedly connected to the steering driving shaft 87, a driving synchronous belt 90 is connected between the steering driving wheel 88 and the adjusting wheel 42 in a power matched manner, a steering bevel gear 92 which is located in the steering gear cavity 93 is fixedly connected to the steering driving shaft 87, and a steering gear 92 which extends upwards to the steering gear cavity 93 and downwards to the bevel gear is connected in a rotationally matched and connected An output gear shaft 95 in a gear cavity 102, wherein the tail end of the upper side of the output gear shaft 95 is fixedly connected with an output bevel gear 94 which is positioned in the steering gear cavity 93 and is meshed with the steering gear cavity 93, and the tail end of the lower side of the output gear shaft 95 is fixedly connected with a driving bevel gear 96 which is positioned in the bevel gear cavity 102 and can be meshed with the reverse bevel gear 101 and the forward bevel gear 103.

In addition, in an embodiment, fixedly connected with is located on the camshaft 57 cam 55 in cam chamber 56, cam chamber 56 sliding fit is connected with push pedal 47 that cam 55 offsets, cam chamber 56 upper end wall intercommunication is equipped with vibrating arm sliding chamber 52, vibrating arm sliding chamber 52 upper end wall intercommunication is equipped with the ascending vibrating mass sliding chamber 49 of opening, push pedal 47 up end fixedly connected with runs through vibrating arm sliding chamber 52 extremely in vibrating mass sliding chamber 49 and with the push rod 48 that vibrating arm sliding chamber 52 sliding fit is connected, the terminal fixedly connected with in push rod 48 upside is located in vibrating mass sliding chamber 49 and with vibrating mass 51 that vibrating mass sliding chamber 49 sliding fit is connected, vibrating mass 51 down the terminal surface with fixedly connected with vibrating spring 50 between the vibrating mass sliding chamber 49 lower extreme wall.

In addition, in one embodiment, a slider cavity 60 is arranged in the screw block 38, a slider 62 capable of being in threaded fit connection with the spline shaft 41 is connected in the slider cavity 60 in a sliding fit manner, a slider spring 61 is fixedly connected between the left end surface of the slider 62 and the left end wall of the slider cavity 60, an adjusting key cavity 58 with an upward opening is arranged in the cutter body 40, an adjusting key 59 is connected in the adjusting key cavity 58 in a sliding fit manner, an adjusting spring 64 is fixedly connected between the lower end surface of the adjusting key 59 and the lower end wall of the adjusting key cavity 58, an adjusting pull rope 63 is fixedly connected between the lower end surface of the adjusting key 59 and the left end surface of the slider 62, a forward and reverse key cavity 68 with a backward opening is arranged in the left support body 20, two push block sliding cavities 72 which are arranged at equal distance up and down are communicated with the front end wall of the forward and reverse key cavity 68, and a key, the key fixing shaft 67 is connected with a forward and reverse rotation key 66 positioned in the forward and reverse rotation key cavity 68 in a rotating fit manner, the push block sliding cavity 72 on the upper side is connected with a forward rotation push block 69 capable of abutting against the forward and reverse rotation key 66 in a sliding fit manner, a forward rotation spring 70 is fixedly connected between the front end surface of the forward rotation push block 69 and the front end wall of the push block sliding cavity 72 on the upper side, a forward rotation pull rope 107 is fixedly connected between the front end surface of the forward rotation push block 69 and the right end surface of the attraction magnet 85, a reverse rotation push block 65 capable of abutting against the forward and reverse rotation key 66 is connected in the push block sliding cavity 72 on the lower side in a sliding fit manner, a reverse rotation spring 71 is fixedly connected between the front end surface of the reverse rotation push block 65 and the front end wall of the push block sliding cavity 72 on the lower side, and a reverse rotation pull.

The fixing and connecting method in this embodiment includes, but is not limited to, bolting, welding, and the like.

As shown in fig. 1-11, the device of the present invention is in an initial state, 50 in a relaxed state, 64 in a relaxed state, 61 in a compressed state, 70 in a relaxed state, 65 in a relaxed state, 86 in a relaxed state, 99 in a relaxed state, and 79 in a relaxed state;

sequence of mechanical actions of the whole device:

when the mulching film passing cavity 10 is started, the driving motor 21 is started to drive the output wheel fixing shaft 114 to rotate, the output wheel fixing shaft 114 rotates to drive the power output wheel 111 to rotate, the power output wheel 111 rotates to drive the double belt wheel 23 to rotate through the power transmission belt 112, the double belt wheel 23 rotates to drive the winding drum 25 to drive, the winding drum 25 rotates to drive the winding drum 14 to rotate, the double belt wheel 23 rotates to drive the driving wheel 34 to rotate through the driving wheel transmission belt 31, the driving wheel 34 rotates to drive the driving shaft 35 to rotate, the driving shaft 35 rotates to drive the left output wheel 28 and the right output wheel 36 to rotate, the left output wheel 28 and the right output wheel 36 rotate to drive the driving wheel 44 to rotate through the left power belt 30 and the right power belt 33 respectively, the driving wheel 44 rotates to drive the multi-wheel fixed shaft 11 to rotate, and the multi-wheel fixed shaft 11 rotates to drive the transmission auxiliary wheel 43 and the vibration output wheel 46 to rotate;

the transmission auxiliary wheel 43 rotates to drive the transmission main wheel 16 to rotate through the transmission belt 12, the transmission main wheel 16 rotates to drive the transmission main wheel shaft 17 to rotate, mulching film transmission is achieved, mulching films are transmitted to be abutted against the winding drum 14, at the moment, the winding drum 14 rotates to drive the mulching films to roll, mulching film winding is achieved, meanwhile, the vibration output wheel 46 rotates to drive the vibration driving wheel 54 to rotate through the vibration wheel synchronous belt 45, the vibration driving wheel 54 rotates to drive the cam shaft 57 to rotate, the cam shaft 57 rotates to drive the cam 55 to rotate, the cam 55 rotates to push the push plate 47 to move up and down due to the change of the rotating radius, the push plate 47 moves up and down to push the vibration block 51 to overcome the pulling force of the vibration spring 50 to move up and;

meanwhile, the rear multi-wheel fixed shaft 11 rotates to drive the adjusting wheel 42 to rotate, the adjusting wheel 42 rotates to drive the steering driving wheel 88 to rotate through the driving synchronous belt 90, the steering driving wheel 88 rotates to drive the steering driving shaft 87 to rotate, the steering driving shaft 87 rotates to drive the steering helical gear 92 to rotate, the steering helical gear 92 rotates to drive the output helical gear 94 to rotate through meshing, the output helical gear 94 rotates to drive the output gear shaft 95 to rotate, the output gear shaft 95 rotates to drive the driving helical gear 96 to rotate, the upper end face of the forward and reverse push button 66 is pushed forwards, the forward and reverse push button 66 rotates around the button fixed shaft 67, the forward and reverse push button 66 rotates to push the forward push block 69 to slide forwards along the upper push block sliding cavity 72 against the thrust of the forward push spring 70, and the reverse push block 65 pushes the forward and reverse push button 66 to slide backwards, at this time, the forward rotation pull rope 107 is in a relaxed state, the reverse rotation pull rope 108 is in a tensioned state, so that the attraction magnet 85 loses the pulling force of the forward rotation pull rope 107 and slides leftward under the pushing force of the attraction spring 86, the repulsion magnet 98 slides leftward under the pulling force of the reverse rotation pull rope 108 against the pushing force of the repulsion spring 99, at this time, the attraction magnet 85 slides leftward to correspond to the moving magnet block 91 and attracts the moving magnet block 91 to slide backward, the moving magnet block 91 slides backward to drive the moving gear shaft 97 to slide backward against the pulling force of the spline spring 105, the moving gear shaft 97 slides backward to drive the reverse rotation helical gear 101 and the forward rotation helical gear 103 to slide backward, at this time, the forward rotation helical gear 103 slides backward to be engaged with the driving helical gear 96, the driving helical gear 96 rotates to drive the forward rotation 103 to rotate through engagement, the forward rotation helical, the movable gear shaft 97 rotates forward to drive the spline shaft 41 to rotate through spline fit, and at the moment, the spline shaft 41 idles;

the adjusting button 59 is pressed downwards, the adjusting button 59 slides downwards against the thrust of the adjusting spring 64, the adjusting button 59 slides downwards to enable the adjusting pull rope 63 to be in a loose state, the slide block 62 losing the tension of the adjusting pull rope 63 slides forwards under the thrust of the slide block spring 61 to be abutted against the spline shaft 41, so that the thread block 38 and the spline shaft 41 form threaded fit, the spline shaft 41 rotates to drive the thread block 38 to slide forwards through threaded fit, if the lower end face of the forward and reverse rotation button 66 is pressed forwards, the forward and reverse rotation button 66 rotates backwards around the button fixing shaft 67, the forward and reverse rotation button 66 rotates backwards to push the reverse rotation push block 65 to slide forwards against the thrust of the reverse rotation spring 71, meanwhile, the forward rotation push block 69 pushes the forward and reverse rotation button 66 to slide backwards under the thrust of the forward rotation spring 70, and the forward rotation push block 69 slides backwards to enable the forward rotation pull rope 107, the reverse rotation pushing block 65 slides forward to make the reverse rotation pulling rope 108 in a relaxed state, at this time, the repulsion magnet 98 losing the pulling force of the reverse rotation pulling rope 108 slides rightward under the pushing force of the repulsion spring 99, at the same time, the attraction magnet 85 overcomes the pushing force of the attraction spring 86 and slides rightward under the pulling force of the forward rotation pulling rope 107, at this time, the repulsion magnet 98 slides rightward to correspond to the moving magnet block 91, the repulsion magnet 98 repels the moving magnet block 91 and slides forward, the moving magnet block 91 slides forward to push the moving gear shaft 97 to slide upward against the pushing force of the spline spring 105, so that the forward rotation helical gear 103 is disengaged from the driving helical gear 96, the reverse rotation helical gear 101 is engaged with the driving helical gear 96, at this time, the driving helical gear 96 rotates to drive the reverse rotation helical gear 101, the reverse rotation helical gear 101 rotates to, when two cutting bodies 40 are to be abutted, the probe 81 of the right cutting body 40 is firstly abutted against the left cutting body 40 and is pushed by the left cutting body 40 to rotate around a rotating shaft 83, the probe 81 rotates to drive the cutting needle 73 to rotate, meanwhile, the probe 81 rotates around the rotating shaft 83 to rotate so that the rotating wheel 82 meshed with the rotating shaft 83 rotates, the rotating wheel 82 rotates to drive the lifting output wheel 77 to rotate through the rotating wheel fixing shaft 110, the lifting output wheel 77 rotates to drive the lifting wheel 74 to rotate through the lifting synchronous belt 76, the lifting wheel 74 rotates to drive the cutting needle 73 to slide upwards through threaded fit until the cutting needle is separated from the mulching film, meanwhile, the probe 81 rotates to drive the torsion spring 79 to rotate to realize power storage, when the probe 81 loses abutment, the probe 81 losing thrust reversely rotates under the torsion action of the torsion spring 79, the probe 81 rotates reversely to enable the rotating wheel 82 to rotate reversely, the rotating wheel 82 rotates reversely to drive the lifting output wheel 77 to rotate reversely through the rotating wheel fixing shaft 110, the lifting output wheel 77 rotates reversely to drive the lifting wheel 74 to rotate reversely through the transmission main wheel 16, so that the cutting needle 73 slides downwards to abut against the mulching film and puncture the mulching film, at the moment, the hand for pressing the adjusting button 59 is released, the adjusting button 59 slides upwards to reset under the thrust action of the adjusting spring 64, the adjusting button 59 resets to enable the adjusting pull rope 63 to be in a tensioning state, at the moment, the slide block 62 slides leftwards to reset and is separated from the spline shaft 41 under the tension action of the adjusting pull rope 63 by overcoming the thrust of the slide block spring 61, at the moment, the spline shaft 41 rotates freely with the thread block 38, the thread block 38 is static, the adjustment of the cutting body 40 is realized, the number of the cutting bodies 40 is adjusted according to the actual situation, and the, sliding the unnecessary cutter 40 to the left side until the unnecessary cutter 40 is pressed against the left cutter 40, so that the cutting needle 73 provided by the unnecessary cutter can be retracted to finish the adjustment;

when the adjustment is completed, the forward and reverse rotation key 66 is reset to reset the reverse rotation push block 65 and the forward rotation push block 69, the reverse rotation push block 65 and the forward rotation push block 69 are reset to reset the attraction magnet 85 and the repulsion magnet 98 to separate from the movable magnet block 91, at the moment, the movable magnet block 91 is not stressed, the movable gear shaft 97 pushes the movable magnet block 91 to slide to reset through the thrust of the spline spring 105, the movable magnet block 91 resets to drive the movable gear shaft 97 to reset, the movable gear shaft 97 resets to drive the reverse rotation bevel gear 101 and the forward rotation bevel gear 103 to reset, the reverse rotation bevel gear 101 resets to separate from the driving bevel gear 96, the forward rotation bevel gear 103 resets to separate from the driving bevel gear 96, at the moment, the driving bevel gear 96 idles;

at the moment, the machine body 26 moves forward to drive the left support body 20 and the right support body 27 to move forward, the left support body 20 and the right support body 27 move forward to drive the film raising block 18 and the forward moving connecting body 37 to move forward, the film raising block 18 moves forward to dig out the mulching film continuously, sandy soil is processed through the vibrating block 51, meanwhile, the connecting body 37 moves forward to drive the electrified cutting needle 73 to move forward, the cutting needle 73 is electrified to cut off the mulching film at high temperature, when the probe 81 moves to abut against the crops, the crops push the probe 81 to rotate rightwards, at the moment, the probe 81 rotates to drive the cutting needle 73 to rotate rightwards and slide upwards to disengage from the mulching film, at the same time, the cutting needle 73 is separated from the crops to avoid injuring the crops, meanwhile, the torque spring 79 stores force, when the probe 81 slides over the crops, the probe 81 rotates reversely under the torque of the torque spring 79 to drive the cutting needle 73 to reset, and simultaneously, the cutting needle 73 abuts against the mulching film, and continuing to move forward to finish cutting.

The invention has the beneficial effects that: through reciprocating vibration's vibrating mass, can clear away the sand on the plastic film before the plastic film is retrieved, the follow-up rolling operation of being convenient for, high temperature cuts to the plastic film through the circular telegram after, the cooperation reel rotates and accomplishes the recovery rolling to the plastic film, can avoid the crop to take place by the condition that the plastic film hole blocked after the plastic film is separated, the probe rod can respond to the crop and dodge, avoid cutting the needle damage crop, the cutting needle position can be adjusted according to the plastic film hole difference in position, thereby reach the effect of retrieving different crop plastic films.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (7)

1. The utility model provides a plastic film cutting recovery unit, includes the organism, its characterized in that: the machine body rear end face is fixedly connected with a left support body, the front end face is fixedly connected with a right support body, the lower end faces of the left support body and the right support body are fixedly connected with a film raising block, mulching film passing cavities which penetrate through the left support body and the right support body in the front and back direction and are provided with downward openings are respectively arranged in the left support body and the right support body, a connecting body is fixedly connected between the left support body and the right support body, a bevel gear cavity is arranged in the left support body, the rear end wall of the bevel gear cavity is communicated with a movable shaft sliding cavity, the rear end wall of the movable shaft sliding cavity is communicated with a magnet cavity, a threaded block sliding cavity which is provided with a left opening and a downward opening is arranged in the connecting body, the front end wall of the bevel gear cavity is connected with a spline shaft which extends through the threaded block sliding cavity to, the spline cavity is internally connected with a movable gear shaft which extends backwards and penetrates through the helical gear cavity to the movable shaft sliding cavity in a spline matching manner, a spline spring is fixedly connected between the front end surface of the movable gear shaft and the front end wall of the spline cavity, the rear end of the movable gear shaft is fixedly connected with a movable magnet block positioned in the movable shaft sliding cavity, the magnet cavity is internally connected with a connecting block in a sliding manner, the right end surface of the connecting block is fixedly connected with a suction magnet positioned in the magnet cavity, a suction spring is fixedly connected between the right end surface of the suction magnet and the right end wall of the magnet cavity, the left end surface of the connecting block is fixedly connected with a repulsion magnet positioned in the magnet cavity, a repulsion spring is fixedly connected between the left end surface of the repulsion magnet and the left end wall of the magnet cavity, and the movable gear shaft is, the movable gear shaft is fixedly connected with a forward rotation helical gear which is positioned in the helical gear cavity and on the front side of the reverse rotation helical gear, the spline shaft is connected with four thread blocks which are positioned in the thread block sliding cavity in a sliding fit mode, and the lower end face of each thread block is fixedly connected with a cutting body which is positioned on the left side of the machine body.

2. The mulching film cutting and recycling device according to claim 1, wherein: a containing cavity extending rightwards and having a backward opening is arranged in the cutting body, a rotating shaft extending upwards into the containing cavity is fixedly connected in the lower end wall of the containing cavity, a probe rod extending backwards to the outside is arranged in the containing cavity, a torsion spring positioned in the containing cavity is fixedly connected between the upper end surface of the probe rod and the lower end wall of the containing cavity, a rotating cavity with a downward opening is arranged in the containing cavity, the rotating cavity is connected with the rotating shaft in a rotating matching manner, a lifting transmission cavity is communicated with the rear end wall of the rotating cavity, a lifting cavity is vertically penetrated in the left side of the probe rod, a cutting needle is connected in the lifting cavity in a sliding matching manner, a lifting wheel positioned in the lifting transmission cavity is connected on the cutting needle in a threaded matching manner, a rotating wheel fixing shaft extending upwards into the upper end wall of the lifting transmission cavity is connected in the lower end wall of the lifting transmission cavity in a, the fixed shaft of the rotating wheel is fixedly connected with a rotating wheel which is positioned in the lifting transmission cavity and meshed with the rotating shaft, the upper end face of the rotating wheel is fixedly connected with a lifting output wheel which is positioned in the lifting transmission cavity and fixedly connected with the rotating wheel fixed shaft, and the lifting output wheel is in power fit connection with a lifting synchronous belt between the lifting wheels.

3. The mulching film cutting and recycling device according to claim 1, wherein: the machine body is internally provided with a belt wheel cavity, the machine body is internally provided with two winding drum cavities which are symmetrically opened in the front and back direction and are far away from the side direction of the belt wheel cavity by taking the belt wheel cavity as the center, the front end wall of the belt wheel cavity is communicated with a power output cavity, the machine body is internally provided with a driving motor which is positioned at the rear side of the power output cavity, the front end surface of the driving motor is fixedly connected with an output wheel fixing shaft which extends forwards to penetrate through the power output cavity to the front end wall of the power output cavity, the output wheel fixing shaft is fixedly connected with a power output wheel positioned in the power output cavity, the rear end wall of the belt wheel cavity is rotatably matched and connected with a winding drum shaft which extends backwards to all winding drum cavities at the rear side and extends forwards to penetrate through the winding drum cavities at the front side, the winding drum shaft is fixedly connected with a winding drum positioned in the winding drum cavity, and, the double-belt wheel with power fit is connected with power transmission belt between the power take-off wheel, be equipped with left output chamber in the supporter of a left side, be equipped with right output chamber in the supporter of the right side, left side output chamber rear end wall normal running fit is connected with and extends forward and runs through left side output chamber the belt pulley chamber with right side output chamber extremely the driving shaft in the right side output chamber front end wall, fixedly connected with is located on the driving shaft the left output wheel of left side output intracavity, fixedly connected with is located on the driving shaft the belt pulley intracavity just is located the action wheel of double-belt wheel downside, fixedly connected with is located on the driving shaft the right output wheel of right side output intracavity, the action wheel with power fit is connected with the action wheel drive belt between the double-belt wheel.

4. The mulching film cutting and recycling device according to claim 3, wherein: the left side supporter with all be equipped with the chamber of crossing in the right side supporter, the chamber upper end wall that crosses communicates respectively and is equipped with the left output chamber and the right output chamber that upwards extend, the chamber upper end wall intercommunication that crosses is equipped with two and is located respectively the vibration output chamber of left output chamber rear side with right output chamber front side, the chamber upper end wall intercommunication that crosses is equipped with two and is located respectively the conveying chamber of left output chamber front side with right output chamber rear side, the rear side the chamber upper end wall intercommunication that crosses is equipped with and is located the rear side the steering drive chamber of conveying chamber rear side, the conveying chamber is kept away from belt pulley chamber side end wall internal rotation cooperation is connected and is to being close to the belt pulley chamber side direction extends to the conveying chamber is close to the conveying main wheel axle in the belt pulley chamber side end wall, fixedly connected with is located on the conveying main wheel axle conveying intracavity conveying main wheel, the chamber that crosses and is kept away from belt pulley chamber side end wall internal rotation cooperation is connected and is had to be A plurality of wheels of fixed shafts which penetrate through the intersection cavity to the intersection cavity and are close to the end wall of the side of the belt wheel cavity, a vibration output wheel which is positioned in the intersection cavity and corresponds to the vibration output cavity is fixedly connected onto the plurality of wheels of fixed shafts, a cam cavity which is positioned on the lower side of the conveying cavity is arranged in the film raising block, a cam shaft which extends through the vibration output cavity to the cam cavity in the direction far away from the side of the belt wheel cavity is connected into the vibration output cavity in a rotating fit manner, a vibration driving wheel which is positioned in the vibration output cavity is fixedly connected onto the cam shaft, a vibration wheel synchronous belt is connected between the vibration driving wheel and the vibration output wheel in a power fit manner, a conveying auxiliary wheel which is positioned in the intersection cavity and corresponds to the conveying cavity is fixedly connected onto the plurality of wheels of fixed shafts, and a conveying main wheel which is positioned in the conveying cavity is, the conveying auxiliary wheel is connected with a conveying belt in a power fit mode between the conveying main wheels, the multi-wheel fixing shaft is fixedly connected with a left power belt, a front power belt and a right power belt, the conveying auxiliary wheel is connected with the conveying main wheels in a power fit mode, the multi-wheel fixing shaft is fixedly connected with the left power belt and the right power belt, the cross cavity is located in the cross cavity, the left power belt is connected with the left output cavity and the right output cavity, the driving wheel corresponds to the right output cavity, the rear side is connected with the.

5. The mulching film cutting and recycling device according to claim 4, wherein: the rear end face of the rear side of the transmission auxiliary wheel is fixedly connected with an adjusting wheel which is positioned in the intersection cavity and corresponds to the steering driving cavity, a steering gear cavity which is positioned on the front side of the steering driving cavity and is positioned on the upper side of the helical gear cavity is arranged in the left support body, a steering driving shaft which extends forwards to penetrate through the steering driving cavity to the steering gear cavity is connected to the rear end wall of the steering driving cavity in a rotating fit manner, a steering driving wheel which is positioned in the steering driving cavity is fixedly connected to the steering driving shaft, a driving synchronous belt is connected between the steering driving wheel and the adjusting wheel in a power fit manner, a steering helical gear which is positioned in the steering gear cavity is fixedly connected to the steering driving shaft, and an output gear shaft which extends upwards to the steering gear cavity and downwards to the helical gear cavity is connected to the lower, the tail end of the upper side of the output gear shaft is fixedly connected with an output helical gear which is positioned in the steering gear cavity and is meshed with the steering gear cavity, and the tail end of the lower side of the output gear shaft is fixedly connected with a driving helical gear which is positioned in the helical gear cavity and can be meshed with the reverse helical gear and the forward helical gear.

6. The mulching film cutting and recycling device according to claim 4, wherein: fixedly connected with is located on the camshaft cam of cam intracavity, cam intracavity sliding fit be connected with the push pedal that the cam offseted, cam chamber upper end wall intercommunication is equipped with vibrating arm sliding chamber, vibrating arm sliding chamber upper end wall intercommunication is equipped with the ascending vibrating mass sliding chamber of opening, push pedal up end fixedly connected with runs through vibrating arm sliding chamber extremely vibrating mass sliding chamber in and with the push rod that vibrating arm sliding chamber sliding fit connects, the terminal fixedly connected with of push rod upside be located vibrating mass sliding chamber in and with the vibrating mass that vibrating mass sliding chamber sliding fit connects, vibrating mass down the terminal surface with fixedly connected with vibrating spring between the vibrating mass sliding chamber lower extreme wall.

7. The mulching film cutting and recycling device according to claim 1, wherein: a slider cavity is arranged in the thread block, a slider capable of being in threaded fit connection with the spline shaft is connected in the slider cavity in a sliding fit manner, a slider spring is fixedly connected between the left end face of the slider and the left end wall of the slider cavity, an adjusting button cavity with an upward opening is arranged in the cutting body, an adjusting button is connected in the adjusting button cavity in a sliding fit manner, an adjusting spring is fixedly connected between the lower end face of the adjusting button and the lower end wall of the adjusting button cavity, an adjusting pull rope is fixedly connected between the lower end face of the adjusting button and the left end face of the slider, a forward and reverse button cavity with a backward opening is arranged in the left supporting body, two push block sliding cavities which are arranged at equal intervals up and down are communicated with the front end wall of the forward and reverse button cavity, a button fixing shaft is fixedly connected between the left and right end walls of the forward and reverse button, the upper side is connected with a forward rotation push block capable of abutting against a forward rotation button and a reverse rotation button in a sliding fit mode in the push block sliding cavity, a forward rotation spring is fixedly connected between the front end face of the forward rotation push block and the front end wall of the push block sliding cavity, a forward rotation pull rope is fixedly connected between the front end face of the forward rotation push block and the right end face of the suction magnet, a reverse rotation push block capable of abutting against the forward rotation button and the reverse rotation button is connected in the push block sliding cavity in a sliding fit mode at the lower side, a reverse rotation spring is fixedly connected between the front end face of the reverse rotation push block and the front end wall of the push block sliding cavity, and a reverse rotation pull rope is fixedly connected between the front.

Images