CN115533184B

CN115533184B - Punching cutting device

Info

Publication number: CN115533184B
Application number: CN202211287035.9A
Authority: CN
Inventors: 杨冬霞
Original assignee: Harbin University
Current assignee: Harbin University
Priority date: 2022-10-20
Filing date: 2022-10-20
Publication date: 2023-05-09
Anticipated expiration: 2042-10-20
Also published as: CN115533184A

Abstract

The invention relates to punching cutting, in particular to a punching cutting device, which comprises a plurality of supporting units and a plurality of cutting units, wherein the supporting units form a supporting module, the supporting units can form a horizontal plane, an inclined plane or a supporting surface combined by the horizontal planes or the inclined planes, the cutting units form a cutting module, and the cutting units can form a horizontal plane, an inclined plane or an inclined plane combined by the horizontal planes or the inclined planes; the sheet may be partially cut and the cut portions bent to different angles.

Description

Punching cutting device

Technical Field

The invention relates to punching cutting, in particular to a punching cutting device.

Background

The stamping is a common processing mode in the mechanical field, the stamping is often used in bending the plate in the prior art, and in the prior art, when cutting the plate, the wire cutting or fire cutting and other modes are often used, so that a cutting gap is inevitably formed, and the cutting gap is not left in the mode of forcedly cutting the plate by utilizing the shearing force, so that the mode of cutting the plate by utilizing the shearing force is needed at present when the processing requirement of the plate is more.

Disclosure of Invention

The invention aims to provide a punching cutting device which can be used for partially cutting a plate and bending the cut part to different angles.

The aim of the invention is achieved by the following technical scheme:

a punching cutting device comprises a plurality of supporting units and a plurality of cutting units, wherein the supporting units form a supporting module, the supporting units can form a horizontal plane, an inclined plane or a supporting surface combining the horizontal planes or the inclined planes, the cutting units form a cutting module, and the cutting units can form a horizontal plane, the inclined planes or the inclined planes combining the inclined planes;

the device comprises a supporting bracket I, a plurality of supporting units, a spring I, a plurality of inserting nails I, a spring II and a plurality of inserting nails I, wherein the supporting bracket I is connected with the supporting units in a sliding mode, the spring I is fixedly connected between the supporting units and the supporting bracket I, the inserting nails I are connected with the supporting bracket I in a sliding mode, and the inserting nails I can be inserted into the supporting units;

a plurality of electromagnets I are fixedly connected to the support bracket I, and the electromagnets I can adsorb corresponding inserted nails I, so that the inserted nails I are separated from the support unit;

the support bracket I is fixedly connected with a plurality of sensors I, and the sensors I are respectively connected with a plurality of electromagnets I;

the support device comprises a support bracket I, a pushing bracket I, a rotating wheel I, a driving ball II, a driving base plate and a cutting groove I, wherein the pushing bracket I is fixedly connected with the supporting bracket I;

the ship type pushing plate comprises a supporting bracket I, a transverse moving bracket I, a first screw rod, a power mechanism V, a sliding block I, a toggle bracket I, a positioning screw I, a plurality of moving wheels I, an adjusting bracket I, a plurality of ship type pushing plates I, a sensor I, a positioning screw I and a positioning screw I, wherein the transverse moving bracket I is fixedly connected to the supporting bracket I;

the device comprises a transverse moving support I, a transverse moving support II, a plurality of cutting units, a spring III, a plurality of inserting nails II, a spring IV and a cutting unit, wherein the transverse moving support I is fixedly connected with a third telescopic mechanism;

a plurality of electromagnets II are fixedly connected to the support bracket II, the electromagnets II can attract corresponding inserted nails II, a plurality of sensors II are fixedly connected to the support bracket II, and the sensors II are respectively connected with the electromagnets II;

the support bracket II is fixedly connected with a fourth telescopic mechanism, the telescopic end of the fourth telescopic mechanism is fixedly connected with a pressing plate, and the pressing plate is provided with a cutting groove II;

the device is characterized in that a second screw rod is rotationally connected to a transverse moving support II, a sliding block II is connected to the second screw rod through threads, a power mechanism VII for driving the second screw rod to rotate is fixedly connected to the transverse moving support II, a fifth telescopic mechanism is fixedly connected to the sliding block II, a stirring support II is rotationally connected to a telescopic end of the fifth telescopic mechanism, a power mechanism VIII for driving the stirring support II to rotate is fixedly connected to a telescopic end of the fifth telescopic mechanism, a movable wheel II is fixedly connected to each cutting unit, a plurality of movable wheels II are in clearance fit in the stirring support II, an adjusting support II is fixedly connected to the fifth telescopic mechanism, two ship-shaped pushing plates II are slidingly connected to the adjusting support II, and the ship-shaped pushing plates II can be in contact with a sensor I, and a positioning screw II for positioning the ship-shaped pushing plates II is connected to the adjusting support II through threads.

Drawings

The invention will be described in further detail with reference to the accompanying drawings and detailed description.

FIG. 1 is a schematic view of a press cutting apparatus of the present invention;

FIG. 2 is a schematic view of a partial structure of a press cutting device of the present invention;

FIG. 3 is a schematic view of the pushing bracket I of the present invention;

FIG. 4 is a schematic view of the structure of the support bracket I of the present invention;

FIG. 5 is a schematic view of the structure of the support unit of the present invention;

FIG. 6 is a schematic view of the toggle support I of the present invention;

FIG. 7 is a schematic view of the traversing carriage I structure of the present invention;

FIG. 8 is a schematic view of the structure of a support bracket II according to the present invention;

FIG. 9 is a schematic view of the structure of the cutting unit of the present invention;

FIG. 10 is a schematic view of a toggle bracket II of the present invention;

fig. 11 is a schematic view of the structure of the sheet material of the present invention after being partially cut and bent.

In the figure:

pushing the bracket I11; a support bracket I12; a support base plate 13; a rotating wheel I14; a driving wheel I15; a drive ball I16; a traversing bracket I17; cutting a groove I18;

a first telescopic mechanism 21;

a support bracket 31; rotating wheel II 32; a drive wheel II 33; a drive ball II 34;

electromagnet I41; sensor I42;

a supporting unit 51; a moving wheel I52; plug pin I53;

a first screw 61; sliding block I62; a second telescopic mechanism 63; toggle support I64; adjusting a bracket I65; boat-shaped push plate I66;

a third telescopic mechanism 70;

a traversing bracket II 81; a support bracket II 82; electromagnet II 83; sensor ii 84; a fourth telescoping mechanism 85; a pressing plate 86; cutting a groove II 87;

a cutting unit 91; a moving wheel II 92; plug pin II 93; a second screw 94; sliding block II 95; a fifth telescopic mechanism 96; toggle the bracket II 97; adjusting a bracket II 98; boat-shaped push plate II 99.

Detailed Description

The invention is described in further detail below with reference to the accompanying drawings.

As shown in fig. 1, the structure and function of a die cutting device will be described in detail;

the punching cutting device comprises a plurality of supporting units 51 and a plurality of cutting units 91, wherein the supporting units 51 form a supporting module, the supporting units 51 can form a horizontal plane, an inclined plane or a supporting surface of the horizontal plane or the inclined plane combination, the cutting units 91 form a cutting module, and the cutting units 91 can form a horizontal plane, the inclined plane or the inclined plane of the horizontal plane or the inclined plane combination;

when the plate cutting machine is used, when simple cutting is required to be carried out on the plate, the plurality of supporting units 51 are positioned on one plane, the plurality of cutting units 91 are positioned on one plane, the plate is placed on the supporting bottom plate 13, the plane formed by the plurality of supporting units 51 is lower than the upper plane of the supporting bottom plate 13, downward stamping force is applied to the cutting module, and then the plate is cut;

when the plate needs to be partially cut, and different angles are bent between the cut part and the plate, the plurality of supporting units 51 form a combination of a plane and an inclined plane, one side of the supporting module is a plane, the other side of the supporting module is an inclined plane connected with the plane, the plurality of cutting units 91 form a combination of a plane and an inclined plane, one side of the cutting module is a plane, the other side of the supporting module is an inclined plane connected with the plane, the plate is placed on the supporting bottom plate 13, the plane formed by the plurality of supporting units 51 is leveled with the upper plane of the supporting bottom plate 13, downward stamping force is applied to the cutting module, the inclined part of the cutting module cuts the plate, the horizontal part of the cutting module does not move until reaching the upper side of the plate, the plate is cut out, the angles of the cutting module and the inclined plane of the supporting module can be adjusted, the cut plate part is extruded by the inclined part of the cutting module and the inclined part of the supporting module, and the cut part of the plate is bent into different angles with the plate body, as shown in fig. 11;

the structure and function of a die cutting device will be described in detail;

the device further comprises a support bracket I12, a plurality of support units 51 are all connected to the support bracket I12 in a sliding mode, a spring I is fixedly connected between the support units 51 and the support bracket I12, a plurality of inserting nails I53 are connected to the support bracket I12 in a sliding mode, a spring II is fixedly connected between the inserting nails I53 and the support bracket I12, and the inserting nails I53 can be inserted into the support units 51;

a plurality of electromagnets I41 are fixedly connected to the support bracket I12, and the electromagnets I41 can adsorb the corresponding inserted nails I53, so that the inserted nails I53 are separated from the support unit 51;

the support bracket I12 is fixedly connected with a plurality of sensors I42, and the sensors I42 are respectively connected with a plurality of electromagnets I41;

the cutting device is characterized in that a pushing support I11 is fixedly connected to the supporting support I12, a rotating wheel I14 is rotatably connected to the pushing support I11, a driving wheel I15 is rotatably connected to the rotating wheel I14, a driving ball I16 is in clearance fit on the pushing support I11, the driving wheel I15 can be in contact with the driving ball I16, a power mechanism I for driving the rotating wheel I14 to rotate is fixedly connected to the pushing support I11, a power mechanism II for driving the driving wheel I15 to rotate is fixedly connected to the rotating wheel I14, a first telescopic mechanism 21 is fixedly connected to the pushing support I11, a supporting support 31 is fixedly connected to the telescopic end of the first telescopic mechanism 21, a rotating wheel II 32 is rotatably connected to the supporting support 31, a power mechanism III for driving the rotating wheel II 32 to rotate is fixedly connected to the supporting support 31, a driving wheel II 33 is rotatably connected to the rotating wheel II 32, a power mechanism IV for driving the driving wheel II 33 to rotate is in clearance fit on the supporting support 31, the driving ball II 34 is in contact with the driving wheel II 33, a supporting base plate 13 is fixedly connected to the pushing support I11, and a cutting groove I18 is formed in the supporting base plate 13;

the ship type pushing plate fixing device is characterized in that a transverse moving support I17 is fixedly connected to the supporting support I12, a first screw rod 61 is rotatably connected to the transverse moving support I17, a power mechanism V for driving the first screw rod 61 to rotate is fixedly connected to the transverse moving support I17, a sliding block I62 is connected to the first screw rod 61 through threads, the sliding block I62 is connected to the transverse moving support I17 in a sliding mode, a second telescopic mechanism 63 is fixedly connected to the sliding block I62, a stirring support I64 is rotatably connected to the telescopic end of the second telescopic mechanism 63, a power mechanism VI for driving the stirring support I64 to rotate is fixedly connected to the telescopic end of the second telescopic mechanism 63, a moving wheel I52 is fixedly connected to each supporting unit 51, a plurality of moving wheels I52 are in the stirring support I64 in a clearance fit mode, two ship type pushing plates I66 are fixedly connected to the second telescopic mechanism 63, the ship type pushing plates I66 can be contacted with the sensor I42, and a positioning screw I is connected to the adjusting support I65 through threads and used for fixing the ship type pushing plates I66;

the transverse moving support I17 is fixedly connected with a third telescopic mechanism 70, the telescopic end of the third telescopic mechanism 70 is fixedly connected with a transverse moving support II 81, the transverse moving support II 81 is fixedly connected with a supporting support II 82, a plurality of cutting units 91 are all slidably connected to the supporting support II 82, a spring III is fixedly connected between the cutting units 91 and the supporting support II 82, a plurality of inserting nails II 93 are slidably connected to the supporting support II 82, a spring IV is fixedly connected between the inserting nails II 93 and the supporting support II 82, and the inserting nails II 93 can be inserted into the bottoms of the cutting units 91;

a plurality of electromagnets II 83 are fixedly connected to the support bracket II 82, the electromagnets II 83 can attract corresponding inserted nails II 93, a plurality of sensors II 84 are fixedly connected to the support bracket II 82, and the plurality of sensors II 84 are respectively connected with the plurality of electromagnets II 83;

the support bracket II 82 is fixedly connected with a fourth telescopic mechanism 85, the telescopic end of the fourth telescopic mechanism 85 is fixedly connected with a pressing plate 86, and the pressing plate 86 is provided with a cutting groove II 87;

the device comprises a transverse moving support II 81, a second screw rod 94, a sliding block II 95, a power mechanism VII, a fifth telescopic mechanism 96, a stirring support II 97, a power mechanism VIII, a movable wheel II 92, two ship-shaped push plates II 99 and a positioning screw II, wherein the second screw rod 94 is rotationally connected to the transverse moving support II 81, the sliding block II 95 is connected to the second screw rod 94 through threads, the power mechanism VII is fixedly connected to the transverse moving support II 81 and drives the second screw rod 94 to rotate, the power mechanism VII is rotationally connected to the telescopic end of the fifth telescopic mechanism 96, the power mechanism VIII is fixedly connected to the telescopic end of the fifth telescopic mechanism 96 and drives the stirring support II 97 to rotate, a plurality of movable wheels II 92 are in clearance fit with the stirring support II 97, an adjusting support II 98 is fixedly connected to the fifth telescopic mechanism 96, two ship-shaped push plates II 99 are connected to the adjusting support II 98 in a sliding mode, and the ship-shaped push plates II 99 can be contacted with a sensor I42;

when the sheet metal cutting machine is used, a sheet metal to be cut is placed on a supporting bottom plate 13, when the sheet metal is required to be moved, a first telescopic mechanism 21 is started, the first telescopic mechanism 21 can be a hydraulic cylinder or an electric push rod, the telescopic end of the first telescopic mechanism 21 drives a supporting bracket 31 to move downwards, a driving ball II 34 is in contact with the upper side of the sheet metal, a power mechanism IV is started, an output shaft of the power mechanism IV starts to rotate, the output shaft of the power mechanism IV drives a driving ball II 33 to rotate, the driving ball II 33 drives the driving ball II 34 to move, the driving ball II 34 is in contact with the sheet metal, the sheet metal is further pushed to move, a power mechanism III is started, the power mechanism III can be a servo motor, the output shaft of the power mechanism III drives a rotating wheel II 32 to rotate, the rotating wheel II 32 drives the driving wheel II 33 to rotate, the deflection direction of the driving wheel II 33 is adjusted, the driving ball II 34 is further adjusted, and the movement direction of the sheet metal is further adjusted;

further, the power mechanism II can be started, the power mechanism II is preferably a servo motor, an output shaft of the power mechanism II drives the driving wheel I15 to move, the driving wheel I15 drives the driving ball I16 to move, the driving ball I16 contacts with the plate to push the plate to move, the power mechanism I is started, the power mechanism I is preferably a servo motor, the output shaft of the power mechanism I drives the rotating wheel I14 to rotate, the rotating wheel I14 drives the driving wheel I15 to move, the rotating direction of the driving wheel I15 is further adjusted, the rotating direction of the driving ball I16 is further adjusted, and the plate is further driven to different positions;

further, during cutting, when ordinary cutting is required, a plate is pushed to the upper sides of the supporting units 51, the plate extends out to a specified length, the two boat-shaped push plates I66 squeeze the sensors I42, the sensors I42 can be contact sensors or squeeze sensors, the corresponding electromagnets I41 are controlled to be electrified after the sensors I42 are subjected to pressure, the electromagnets I41 adsorb the inserting nails I53 after being electrified, the inserting nails I53 move, the inserting nails I53 are separated from the supporting units 51, and the supporting units 51 can move up and down;

when the ship-shaped push plate I66 does not squeeze the sensor I42 any more, the electromagnet I41 is powered off, the plug pin I53 is reset, the plug pin I53 is inserted into the supporting unit 51, and the supporting unit 51 can not move up and down any more;

the length formed by the two ship-shaped push plates I66 is adjusted in advance, so that the length formed by the two ship-shaped push plates I66 is the same as the length of the toggle support I64, the electromagnet I41 of the extruded part of the ship-shaped push plates I66 works, the plurality of supporting units 51 of the extruded part of the ship-shaped push plates I66 can move, and the part of the plate to be cut is positioned on the upper sides of the plurality of supporting units 51;

the second telescopic mechanism 63 is started, the second telescopic mechanism 63 can be a hydraulic cylinder or an electric push rod, the telescopic end of the second telescopic mechanism 63 drives the toggle support I64 to move downwards, and then the toggle support I64 drives the plurality of support units 51 to move downwards, so that a plane formed by the plurality of support units 51 is lower than the upper plane of the support bottom plate 13;

starting a third telescopic mechanism 70, wherein the third telescopic mechanism 70 can be a hydraulic cylinder or an electric push rod, and the telescopic end of the third telescopic mechanism 70 drives a plurality of cutting units 91 to move downwards so as to cut the extending part of the plate;

further, when the shape shown in fig. 11 is to be cut, correspondingly, a portion of the sheet material to be cut is placed on the upper side of the movable supporting unit 51 and the upper side of the supporting unit 51 pressed by the boat-shaped push plate i 66, and a portion of the sheet material not to be cut is placed on the upper side of the non-movable supporting unit 51 and the upper side of the supporting unit 51 not pressed by the boat-shaped push plate i 66;

the power mechanism VI is started, an output shaft of the power mechanism VI starts to rotate, the output shaft of the power mechanism VI drives the poking bracket I64 to rotate, the poking bracket I64 drives the plurality of moving wheels I52 to move, the moving wheels I52 drive the supporting units 51 to move, the supporting units 51 form inclined planes, and the plurality of supporting units 51 form a plane and downward inclined planes;

as shown in fig. 10, two boat-shaped pushing plates ii 99 squeeze the sensor ii 84, the sensor ii 84 may be a contact sensor or a squeeze sensor, and further the sensor ii 84 is connected to the electromagnet ii 83 by an electrical control means commonly used in the art, when the sensor ii 84 is squeezed, the electromagnet ii 83 is energized, the electromagnet ii 83 attracts the plug pin ii 93, and the plurality of cutting units 91 may move;

starting a power mechanism VIII, wherein an output shaft of the power mechanism VIII starts to rotate, the output shaft of the power mechanism VIII drives a toggle support II 97 to move, the toggle support II 97 drives a moving wheel II 92 to move, the moving wheel II 92 drives a corresponding cutting unit 91 to move, so that a plurality of cutting units 91 incline, and the plurality of cutting units 91 form a plane and a downward inclined surface;

starting the third telescopic mechanism 70, wherein the telescopic end of the third telescopic mechanism 70 drives the plurality of cutting units 91 to move downwards, the inclined part of the cutting module cuts the plate, the horizontal part of the cutting module does not move after moving to the upper side of the plate, the plate is cut into a hole, the angles of the inclined surfaces of the cutting module and the supporting module can be adjusted, the cut plate part can be extruded by the inclined part of the cutting module and the inclined part of the supporting module, an inclined angle is formed between the cut plate part and the plate body, and the cut plate part is folded into different angles, as shown in fig. 11;

further, the power mechanism v can be started, the output shaft of the power mechanism v drives the first screw rod 61 to rotate, and the first screw rod 61 drives the plurality of support units 51 to transversely move through threads when rotating, so that the support positions of the plurality of support units 51 are adjusted;

further, the power mechanism vii may be started, the output shaft of the power mechanism vii drives the second screw rod 94 to rotate, and the second screw rod 94 drives the plurality of cutting units 91 to move transversely through threads when rotating, so as to adjust the cutting positions of the plurality of cutting units 91.

Claims

1. A punching cutting device comprising a plurality of support units (51) and a plurality of cutting units (91), characterized in that: the plurality of supporting units (51) form a supporting module, the plurality of supporting units (51) can form a supporting surface of a horizontal surface, an inclined surface or a combination of the horizontal surfaces or the inclined surfaces, the plurality of cutting units (91) form a cutting module, and the plurality of cutting units (91) can form a horizontal surface, an inclined surface or a combination of the horizontal surfaces or the inclined surfaces;

the device comprises a supporting bracket I (12), a plurality of supporting units (51) are all connected to the supporting bracket I (12) in a sliding mode, a spring I is fixedly connected between the supporting units (51) and the supporting bracket I (12), a plurality of inserting nails I (53) are connected to the supporting bracket I (12) in a sliding mode, a spring II is fixedly connected between the inserting nails I (53) and the supporting bracket I (12), and the inserting nails I (53) can be inserted into the supporting units (51);

a plurality of electromagnets I (41) are fixedly connected to the support bracket I (12), and the electromagnets I (41) can adsorb the corresponding inserted nails I (53) so that the inserted nails I (53) are separated from the support unit (51);

a plurality of sensors I (42) are fixedly connected to the support bracket I (12), and the sensors I (42) are respectively connected with a plurality of electromagnets I (41);

the supporting bracket I (12) is fixedly connected with a pushing bracket I (11), the pushing bracket I (11) is rotationally connected with a rotating wheel I (14), the rotating wheel I (14) is rotationally connected with a driving wheel I (15), the pushing bracket I (11) is rotationally connected with a driving ball I (16) in a clearance fit manner, the driving wheel I (15) can be contacted with the driving ball I (16), the pushing bracket I (11) is fixedly connected with a power mechanism I for driving the rotating wheel I (14) to rotate, the pushing bracket I (14) is fixedly connected with a power mechanism II for driving the driving wheel I (15) to rotate, the pushing bracket I (11) is fixedly connected with a first telescopic mechanism (21), the telescopic end of the first telescopic mechanism (21) is fixedly connected with a supporting bracket (31), the supporting bracket (31) is rotationally connected with a rotating wheel II (32), the supporting bracket (31) is fixedly connected with a power mechanism III for driving the rotating wheel II (32), the driving wheel II (32) is rotationally connected with a driving wheel II (33), the driving wheel II (32) is fixedly connected with a driving wheel II (33) to rotationally drive the driving wheel II (33), the driving ball (33) is fixedly connected with a supporting ball II (13) in a clearance fit manner, a cutting groove I (18) is formed in the supporting bottom plate (13);

the ship push plate is characterized in that a transverse moving support I (17) is fixedly connected to the support I (12), a first screw rod (61) is rotationally connected to the transverse moving support I (17), a power mechanism V for driving the first screw rod (61) to rotate is fixedly connected to the transverse moving support I (17), a sliding block I (62) is connected to the first screw rod (61) through threads, a second telescopic mechanism (63) is fixedly connected to the sliding block I (62) in a sliding mode, a stirring support I (64) is rotationally connected to the telescopic end of the second telescopic mechanism (63), a power mechanism VI for driving the stirring support I (64) to rotate is fixedly connected to the telescopic end of the second telescopic mechanism (63), a movable wheel I (52) is fixedly connected to each support unit (51), a plurality of movable wheels I (52) are arranged in the stirring support I (64) in a clearance fit mode, two ship push plates I (66) are fixedly connected to the second telescopic mechanism I (62) in a sliding mode, and two ship push plates I (66) can be fixedly connected to the ship push plate I (66) through the positioning screw I (42).

2. A die cutting apparatus as defined in claim 1, wherein: fixedly connected with third telescopic machanism (70) on sideslip support I (17), fixedly connected with sideslip support II (81) on the flexible end of third telescopic machanism (70), fixedly connected with support frame II (82) on sideslip support II (81), a plurality of cutting units (91) all sliding connection are on support frame II (82), fixedly connected with spring III between cutting unit (91) and support frame II (82), fixedly connected with a plurality of inserted pin II (93) on support frame II (82), fixedly connected with spring IV between inserted pin II (93) and support frame II (82), inserted pin II (93) can insert the bottom of cutting unit (91).

3. A die cutting apparatus as defined in claim 2, wherein: fixedly connected with a plurality of electro-magnet II (83) on support II (82), electro-magnet II (83) can carry out the actuation to corresponding dowel II (93), fixedly connected with a plurality of sensor II (84) on support II (82), a plurality of sensor II (84) are connected with a plurality of electro-magnet II (83) respectively.

4. A die cutting apparatus as defined in claim 3, wherein: the device is characterized in that a fourth telescopic mechanism (85) is fixedly connected to the support bracket II (82), a pressing plate (86) is fixedly connected to the telescopic end of the fourth telescopic mechanism (85), and a cutting groove II (87) is formed in the pressing plate (86).

5. A die cutting apparatus as defined in claim 4, wherein: the device is characterized in that a second screw rod (94) is rotationally connected to a traversing bracket II (81), a sliding block II (95) is connected to the second screw rod (94) through threads, a power mechanism VII for driving the second screw rod (94) to rotate is fixedly connected to the traversing bracket II (81), a fifth telescopic mechanism (96) is fixedly connected to the sliding block II (95), a stirring bracket II (97) is rotationally connected to the telescopic end of the fifth telescopic mechanism (96), a power mechanism VIII for driving the stirring bracket II (97) to rotate is fixedly connected to the telescopic end of the fifth telescopic mechanism (96), a movable wheel II (92) is fixedly connected to each cutting unit (91), a plurality of movable wheels II (92) are arranged in the stirring bracket II (97) in a clearance fit mode, two ship-shaped pushing plates II (99) are fixedly connected to the adjusting bracket II (98), the ship-shaped pushing plates II (99) can be contacted with a sensor I (42), and positioning screws for positioning the ship-shaped pushing plates II (99) are connected to threads on the adjusting bracket II (98).