CN112122498A

CN112122498A - Stepless adjustable thick iron wire cutting machine

Info

Publication number: CN112122498A
Application number: CN202010862242.7A
Authority: CN
Inventors: 邱华东
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-08-25
Filing date: 2020-08-25
Publication date: 2020-12-25

Abstract

The invention relates to a cutting machine, in particular to a stepless adjustable thick iron wire cutting machine. The technical problem is how to design a stepless adjustable thick iron wire cutting machine which can replace manpower to cut thick iron wires to the same length, has simpler operation and high working efficiency and is labor-saving. A stepless adjustable thick iron wire cutting machine comprises: the device comprises a base, wherein supporting rods are fixedly connected to two sides of the base at intervals, and the number of the supporting rods is six; the shell is fixedly connected between the end parts of the six support rods far away from the base, and guide grooves are formed in two sides of the shell far away from the base. According to the invention, the three thick iron wires are moved between the upper and lower conveying wheels, the swinging plate is adjusted to the position of the thick iron wire required to be cut off, and the servo motor is started to rotate forwards, so that the thick iron wire can move rightwards and be cut off to the same length.

Description

Stepless adjustable thick iron wire cutting machine

Technical Field

The invention relates to a cutting machine, in particular to a stepless adjustable thick iron wire cutting machine.

Background

The iron wire is a metal wire made of iron, the iron wire has different components according to different purposes, and the iron wire comprises the following components: iron, cobalt, nickel, copper, carbon, zinc, and other elements. The iron wires are divided into a plurality of models according to the thickness, the iron wires are thick and thin, and in the use process of the thick iron wires, the thick iron wires are required to be cut off to the same length due to the fact that the thick iron wires are longer.

At present, the thick iron wire is cut off manually by most, the user is firstly required to measure the length of the thick iron wire by using a ruler, the thick iron wire is cut off by using a wire cutter, the length of the thick iron wire is required to be measured every time, the operation is more troublesome, the working efficiency is low, and the user needs to use the wire cutter to cut off the thick iron wire every time, so that the operation is long and more labor is wasted.

Therefore, a stepless adjustable thick iron wire cutting machine which can replace manual work to cut thick iron wires to the same length, is simple to operate, high in working efficiency and labor-saving is particularly needed, so that the problems in the prior art are solved.

Disclosure of Invention

In order to overcome the defects that the thick iron wire needs to be cut into a required length every time, the operation is troublesome, the working efficiency is low, and people need to cut the thick iron wire by using wire cutters every time, so that the cutting time is long and the cutting time is laborious, the technical problem of the invention is as follows: the stepless adjustable thick iron wire cutting machine can replace manpower to cut thick iron wires to the same length, is simple to operate, has high working efficiency and is labor-saving.

A stepless adjustable thick iron wire cutting machine comprises: the device comprises a base, wherein supporting rods are fixedly connected to two sides of the base at intervals, and the number of the supporting rods is six; the shell is fixedly connected between the end parts of the six support rods far away from the base, and guide grooves are formed in two sides of the shell far away from the base; the movable block is slidably connected between the two guide grooves in a penetrating manner; the swinging plate is rotatably connected to one side of the movable block; the fixed cutter is fixedly connected between the two sides in the shell far away from the guide groove; the driving mechanism is arranged between one side of the shell far away from the guide groove and one side of the base and is used for driving the thick iron wire to move; and the cutting mechanism is arranged on the shell, is in contact fit with the driving mechanism, is also in sliding connection with one side of the swinging plate facing the driving mechanism and is used for cutting the thick iron wires.

More preferably, the drive mechanism includes: the servo motor is arranged at the edge of one side of the base; the number of the rotating shafts is two, and the rotating shafts are rotatably connected between the two sides in the shell far away from the guide groove; the conveying wheel is fixedly sleeved on the circumferential direction of one side of the rotating shaft and is positioned in the shell; the gear is fixedly sleeved on the circumferential direction of one side of the rotating shaft close to the conveying wheel and positioned outside the shell, and the two gears are meshed with each other; the first transmission assembly is connected between the end part of an output shaft of the servo motor and one end of the rotating shaft close to the base; the rotating rod is rotatably connected to one side of the shell close to the conveying wheel and the cut-off mechanism in a penetrating mode; the cams are fixedly sleeved on the circumferential directions of the two sides of the rotating rod and are in contact fit with the cutting mechanism; and the second transmission assembly is connected between the end part of one of the rotating shafts far away from the gear and the end part of the rotating rod far away from the first transmission assembly.

More preferably, the cutoff mechanism includes: the contact rod is slidably connected to two sides of the shell, close to the conveying wheel and far away from the base in a penetrating manner; the sleeve is fixedly connected to the end part, far away from the conveying wheel, of the contact rod and is positioned outside the shell; the special-shaped sliding rod is slidably arranged in the sleeve, and the tail end of the special-shaped sliding rod penetrates through the guide groove and is in sliding connection with one side of the swinging plate facing the rotating shaft; the fastening bolt is rotatably connected to the circumferential direction of one outer side of the sleeve far away from the conveying wheel in a penetrating mode through threads, and the inner end of the fastening bolt is in contact fit with the special-shaped sliding rod; the movable plate is rotatably connected between two sides in the shell close to the rotating rod; the swinging blocks are rotatably connected to two ends of the movable plate facing the conveying wheel and are in contact fit with the cam; the torsion spring is connected between the swinging block and the end part of the movable plate; the guide sleeves are fixedly connected to one side of the movable plate far away from the base and the guide groove, the number of the guide sleeves is two, and the guide sleeves correspond to the swinging blocks; the L-shaped rod is slidably penetrated in the guide sleeve and matched with the contact rod and the swinging block; the second spring is connected between one side, facing the inner side of the L-shaped rod of the swinging block, of the second spring and one side, far away from the torsion spring, of the guide sleeve; the movable cutter is slidably connected between two sides of the shell close to the movable plate in a penetrating manner, is in contact fit with the end part of the movable plate facing the base, and is also matched with the fixed cutter; the first spring is symmetrically connected to one side of the movable cutter facing the base, and the tail end of the first spring is fixedly connected with the inside of the shell.

More preferably, the device further comprises a pushing mechanism, wherein the pushing mechanism comprises: the n-type guide rod is slidably connected to one side of the shell, which is far away from the base and close to the sleeve in a penetrating manner; the push plate is fixedly connected between the end parts of the n-type guide rods facing the base; the third spring is sleeved on the two sides of the n-shaped guide rod in the circumferential direction, one end of the third spring is fixedly connected with one side in the shell far away from the base, and the other end of the third spring is fixedly connected with one side of the push plate far away from the base; the rotating plate is rotatably connected to one side of the n-shaped guide rod far away from the conveying wheel and the base; the n-shaped rod is fixedly connected between the outer sides of the two sleeves close to the fastening bolt; the inclined block is fixedly connected to one side, facing the n-shaped guide rod and far away from the base, of the n-shaped rod and is matched with the rotating plate.

More preferably, the method further comprises the following steps: the protective shell is fixedly connected to one side of the base, which is close to the first transmission assembly, and the first transmission assembly and the gear are located in the protective shell.

More preferably, the method further comprises the following steps: the material receiving frame is fixedly connected between the inner sides of the six supporting rods close to the base; the cylinder, the installation of cylinder interval rotary type is close to the base connect material frame one side.

Compared with the prior art, the invention has the following advantages:

1. through moving three thick iron wires between the supreme both sides delivery wheel down, and adjust the swing plate to the thick iron wire position that the demand was cuted, start servo motor corotation, can make thick iron wire move rightly and be cuted to same length, so, need not that operating personnel is manual to cut thick iron wire, and measure good length, convenient operation, work efficiency is high, still laborsaving.

2. Through the effect of pushing equipment, can be after thick iron wire cuts off, push off the iron wire after cutting off, so, can avoid the iron wire after cutting off to block and be difficult to drop.

3. Through the effect of connecing material frame and cylinder, can receive the thick iron silk that drops and make it drop to collecting the container in, so, more conveniently collect the thick iron silk that cuts.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

FIG. 2 is a schematic view of a first partial body structure according to the present invention.

FIG. 3 is a schematic view of a second partial body structure according to the present invention.

Fig. 4 is a perspective view of a third embodiment of the present invention.

Fig. 5 is an enlarged schematic view of part a of the present invention.

Fig. 6 is an enlarged view of part B of the present invention.

The parts are labeled as follows: 1. the device comprises a base, 2, support rods, 3, a shell, 4, a guide groove, 5, a movable block, 6, a swinging plate, 7, a driving mechanism, 71, a rotating shaft, 72, a gear, 73, a servo motor, 74, a first transmission component, 75, a conveying wheel, 76, a rotating rod, 77, a cam, 78, a second transmission component, 8, a fixed cutter, 9, a cutting mechanism, 91, a sleeve, 92, a movable plate, 93, a movable cutter, 94, a swinging block, 95, a contact rod, 96, an L-shaped rod, 97, a fastening bolt, 98, a special-shaped sliding rod, 99, a first spring, 910, a guide sleeve, 911, a second spring, 912, a torsion spring, 10, a pushing mechanism, 101, an n-shaped rod, 102, a sloping block, 103, an n-shaped guide rod, 104, a rotating plate, 105, a push plate, 106, a third spring, 11, a protective shell, 12, a material receiving frame, 13 and a roller.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

A stepless adjustable thick iron wire cutting machine, as shown in figures 1-6, comprising a base 1, a support rod 2, a shell 3 and a movable block 5, swing board 6, actuating mechanism 7, fixed cutter 8 and truncation mechanism 9, both sides are all even spaced rigid coupling has three spinal branch 2 around the base 1 top, the rigid coupling has casing 3 between 2 tail ends of six spinal branch poles, both sides right side upper portion has all opened guide way 4 around the casing 3, slidingtype be equipped with movable block 5 between front and back both sides guide way 4, the swing board 6 that is connected with of movable block 5 left surface rotary type, the rigid coupling has fixed cutter 8 between the left part of face around in the casing 3, be equipped with actuating mechanism 7 between casing 3 and the base 1 top left side, casing 3 upper portion left side is equipped with truncation mechanism 9, truncation mechanism 9 and actuating mechanism 7 contact cooperation, truncation mechanism 9 and swing board 6 left side upper portion sliding connection.

The driving mechanism 7 comprises a rotating shaft 71, a gear 72, a servo motor 73, a first transmission component 74, a conveying wheel 75, a rotating rod 76, a cam 77 and a second transmission component 78, the rotating shaft 71 is rotatably connected between the upper part and the lower part of the left side of the front and back side surfaces of the shell 3, the conveying wheel 75 capable of conveying thick iron wires is circumferentially fixedly connected in the middle of the rotating shaft 71, the conveying wheels 75 on the upper and lower sides are matched, the gear 72 is circumferentially fixedly connected in the front of the rotating shaft 71, the gears 72 on the upper and lower sides are meshed, the servo motor 73 is installed on the left side of the top of the base 1 in a bolt connection mode, the first transmission component 74 is connected between the end part of an output shaft of the servo motor 73 and the front end of the rotating shaft 71 below, the first transmission component 74 is in belt pulley and belt transmission, the rotating rod 76 is rotatably connected in the middle of the left part of the back side of the shell, the cam 77 is in contact fit with the cut-off mechanism 9, a second transmission component 78 is connected between the rear end of the rotating rod 76 and the rear end of the upper rotating shaft 71, and the second transmission component 78 is in belt pulley and belt transmission.

The cutting mechanism 9 comprises a sleeve 91, a movable plate 92, a movable cutter 93, a swinging block 94, a contact rod 95, an L-shaped rod 96, a fastening bolt 97, a special-shaped slide rod 98, a first spring 99, a guide sleeve 910, a second spring 911 and a torsion spring 912, wherein the movable cutter 93 is arranged between the lower sides of the left parts of the front and rear sides of the shell 3 in a sliding manner, the movable cutter 93 is positioned right above the fixed cutter 8 and matched with the fixed cutter, the first spring 99 is respectively connected between the front and rear sides of the bottom of the movable cutter 93 and the inside of the shell 3, the movable plate 92 is rotatably connected between the middle parts of the front and rear sides of the inside of the shell 3, the movable plate 92 is positioned on the right side of the cam 77, the bottom end of the movable plate 92 is in contact and matching with the top of the movable cutter 93, the swinging block 94 matched with the cam 77 is rotatably connected at both ends, guide sleeves 910 are fixedly connected to the front portion and the rear portion of the left side of the top of the movable plate 92, an L-shaped rod 96 matched with the swing block 94 is arranged in the guide sleeves 910 in an inward sliding mode, a second spring 911 is connected between the lower portion of the inner right side face of the L-shaped rod 96 and the upper portion of the right side face of the guide sleeves 910, contact rods 95 are connected to the upper portions of the left side faces of the front side and the rear side of the shell 3 in a sliding mode in a penetrating mode, the inner ends of the contact rods 95 are in contact fit with the upper portion of the L-shaped rod 96, sleeves 91 are fixedly connected to the outer ends of the contact rods 95, special-shaped slide rods 98 are arranged in the inward sliding mode of the sleeves 91, the tail ends of the special-shaped slide rods 98 are in sliding connection with the upper portion of.

Firstly, an operator moves three thick iron wires to be in contact fit with a driving mechanism 7, then adjusts the position of a cutting mechanism 9 according to the length of the cut iron wires, the cutting mechanism 9 moves to drive a swinging plate 6 to move left and right, when the swinging plate 6 moves left and right to the length of the iron wires required to be cut, the cutting mechanism 9 is stopped to be pulled to move, the driving mechanism 7 is started, the driving mechanism 7 operates to drive the thick iron wires to move right, the thick iron wires move right to be in contact with a fixed cutter 8, when the thick iron wires continue to move right to be in contact with the swinging plate 6, the thick iron wires drive the lower part of the swinging plate 6 to swing right, the upper part of the swinging plate 6 swings left to drive the cutting mechanism 9 to move left, when the cutting mechanism 9 moves left to a proper position, the driving mechanism 7 drives the cutting mechanism 9 to operate to be matched with the fixed cutter, the cut thick iron wires fall downwards onto the base 1, the thick iron wires are separated from the swinging plate 6, the cutting mechanism 9 operates and resets to drive the swinging plate 6 to swing and reset, and the driving mechanism 7 operates to continue to drive the thick iron wires to move rightwards to be cut. When the thick iron wires are all cut to the same length, the driving mechanism 7 is closed, and the cut thick iron wires are collected and processed.

Firstly, when an operator moves three thick iron wires between the upper and lower conveying wheels 75 and further the swinging plate 6 moves to a proper position, the servo motor 73 is started to rotate forward, the servo motor 73 rotates forward to drive the first transmission component 74 to rotate forward, the first transmission component 74 rotates forward to drive the lower rotating shaft 71 to rotate forward, the lower rotating shaft 71 rotates forward to drive the lower conveying wheel 75 to rotate forward, meanwhile, the lower rotating shaft 71 also drives the lower gear 72 to rotate forward, the lower gear 72 rotates forward to drive the upper gear 72 to rotate backward, the upper gear 72 rotates backward to drive the upper rotating shaft 71 to rotate backward, the upper rotating shaft 71 rotates backward to drive the upper conveying wheel 75 to rotate backward, the upper conveying wheel 75 rotates backward and the lower conveying wheel 75 rotates forward to drive the thick iron wires to move rightward to be in contact with the swinging plate 6, meanwhile, the upper rotating shaft 71 rotates backward to drive the second transmission component 78 to rotate backward, the second transmission component 78 rotates backward to drive the rotating rod 76, when the cutting mechanism 9 moves to a proper position leftwards, the cam 77 drives the cutting mechanism 9 to operate and cooperate with the fixed cutter 8 to cut the thick iron wires, the cut thick iron wires fall downwards to be separated from the swinging plate 6, the cutting mechanism 9 operates and resets and does not cooperate with the cam 77, and the upper and lower conveying wheels 75 continue to drive the thick iron wires to move rightwards to be cut. When all the thick iron wires are cut to the same length, the servo motor 73 is turned off, the upper and lower conveying wheels 75 are stopped, and the cam 77 is also stopped.

Firstly, an operator twists the fastening bolt 97 to move outwards to be separated from the special-shaped slide rod 98, pulls the special-shaped slide rod 98 to move left and right, the special-shaped slide rod 98 moves left and right to drive the swing plate 6 to move left and right, when the swing plate 6 moves left and right to the length of the thick iron wire required to be cut off, the special-shaped slide rod 98 stops being pulled to move left and right, the twisting fastening bolt 97 moves inwards to contact with the special-shaped slide rod 98 to fix the special-shaped slide rod, the servo motor 73 is started to rotate forward, the cam 77 drives the swing block 94 to swing up and down under the action of the torsion spring 912, the upper and lower side conveying wheels 75 rotate to drive the thick iron wire to move right, when the thick iron wire moves right to contact with the swing plate 6, the thick iron wire makes the upper part of the swing plate 6 swing left, the upper part of the swing plate 6, the contact rod 95 moves leftwards to drive the L-shaped rod 96 to move leftwards, the second spring 911 is compressed, when the L-shaped rod 96 moves leftwards to contact with the swinging block 94, the cam 77 drives the swinging block 94 to swing upwards, due to the limit of the L-shaped rod 96 to the swinging block 94, the swinging block 94 swings upwards to drive the left part of the movable plate 92 to swing upwards, the left part of the movable plate 92 swings upwards to make the right part swing downwards, the right part of the movable plate 92 swings downwards to drive the movable cutter 93 to move downwards, the first spring 99 is compressed, the movable cutter 93 moves downwards to match with the fixed cutter 8 to cut off the thick iron wires, the cut-off thick iron wires fall downwards, at the moment, the convex end of the cam 77 is separated from the swinging block 94, due to the action of the first spring 99, the movable cutter 93 moves upwards to drive the right part of the movable plate 92 to swing upwards to reset, the left part of the movable plate 92 swings, the cut thick iron wires are separated from the swinging plate 6, due to the action of the second spring 911, the L-shaped rod 96 moves rightwards to drive the sleeve 91 to move rightwards for resetting through the contact rod 95, the sleeve 91 moves rightwards to drive the swinging plate 6 to swing for resetting through the special-shaped sliding rod 98, and the process is repeated, so that the thick iron wires can be cut to the same length continuously. When all the thick iron wires are cut off, the servo motor 73 is turned off, and the cam 77 stops driving the swinging block 94 to swing up and down.

Example 2

Based on embodiment 1, as shown in fig. 3, the device further includes a material pushing mechanism 10, the material pushing mechanism 10 includes an n-type rod 101, an oblique block 102, an n-type guide rod 103, a rotating plate 104, a pushing plate 105 and a third spring 106, the n-type rod 101 is fixedly connected between the upper portions of the right sides of the outer side surfaces of the front and rear sleeves 91, the oblique block 102 is fixedly connected between the upper portions of the left side surfaces of the n-type rod 101, the n-type guide rod 103 is slidably connected to the left side of the top of the housing 3 in a penetrating manner, the n-type guide rod 103 is located on the right side of the movable cutter 93, the rotating plate 104 is rotatably connected to the upper portion of the right side of the n-type guide rod 103, the rotating plate 104 is matched with the oblique block 102, the pushing plate 105 is fixedly connected between the bottom ends of the n-type guide.

When the thick iron wire drives the lower part of the swinging plate 6 to swing rightwards, the sleeve 91 moves leftwards and also drives the n-type rod 101 to move leftwards, the n-type rod 101 moves leftwards and drives the inclined block 102 to move leftwards, the inclined block 102 moves leftwards and is in contact with the rotating plate 104, the inclined block 102 drives the rotating plate 104 to move upwards, the rotating plate 104 moves upwards and drives the n-type guide rod 103 to move upwards, the third spring 106 compresses, the n-type guide rod 103 moves upwards and drives the push plate 105 to move upwards, when the inclined block 102 continues to move leftwards, the inclined block 102 is separated from the rotating plate 104, and due to the action of the third spring 106, the push plate 105 moves downwards and pushes off the cut and dropped thick iron wire. When the sleeve 91 is reset to the right, the sleeve 91 drives the inclined block 102 to reset to the right through the n-shaped rod 101, and the inclined block 102 moves to the right and slides on the rotating plate 104 to reset. Thus, the phenomenon that the cut thick iron wire is clamped and is difficult to drop can be avoided.

Example 3

On the basis of the embodiments 1 and 2, as shown in fig. 1, the portable electronic device further includes a protective shell 11, the protective shell 11 is fixedly connected to the front portion of the left side of the top of the base 1, and the gear 72 and the first transmission assembly 74 are located in the protective shell 11.

The device is characterized by further comprising a material receiving frame 12 and a roller 13, wherein the material receiving frame 12 is fixedly connected between the lower portions of the inner side surfaces of the six support rods 2, and the roller 13 is rotatably connected between the front side and the rear side of the bottom of the material receiving frame 12 at intervals.

When the device is operated to cut the thick iron wire into the same length, the protective shell 11 blocks the first transmission component 74 and the gear 72, so as to prevent foreign matters from falling onto the first transmission component 74 and the gear 72 to influence the operation thereof.

Firstly, an operator can place a collecting container at the right lower part of the material receiving frame 12, when the cut thick iron wires fall downwards, the thick iron wires fall into the material receiving frame 12, and the thick iron wires in the material receiving frame 12 slide into the collecting container through the roller 13.

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

Claims

1. The utility model provides a thick iron silk clipper with adjustable it is stepless, characterized by, including:

the device comprises a base (1), wherein supporting rods (2) are fixedly connected to two sides of the base (1) at intervals, and the number of the supporting rods is six;

the shell (3) is fixedly connected between the end parts of the six support rods (2) far away from the base (1), and guide grooves (4) are formed in two sides of the shell (3) far away from the base (1);

the movable block (5) is connected between the two guide grooves (4) in a sliding mode in a penetrating mode;

the swinging plate (6), the swinging plate (6) is rotatably connected to one side of the movable block (5);

the fixed cutter (8), the said fixed cutter (8) is fixedly connected to the said both sides of inside of the said body (3) far away from the said guide way (4);

the driving mechanism (7) is arranged between one side of the shell (3) far away from the guide groove (4) and one side of the base (1) and is used for driving the thick iron wire to move;

and the cutting mechanism (9) is arranged on the shell (3) and is in contact fit with the driving mechanism (7), and the cutting mechanism (9) is also in sliding connection with one side of the swinging plate (6) facing the driving mechanism (7) and is used for cutting the thick iron wires.

2. The thick iron wire cutting machine with adjustable it is a stepless according to claim 1, characterized by that, the driving mechanism (7) includes:

the servo motor (73), the said servo motor (73) is mounted to the edge position of one side of the said base (1);

the number of the rotating shafts (71) is two, and the rotating shafts (71) are rotatably connected between two sides in the shell (3) far away from the guide groove (4);

the conveying wheel (75) is fixedly sleeved on the circumferential direction of one side of the rotating shaft (71) and is positioned in the shell (3);

the gear (72) is fixedly sleeved on one side of the rotating shaft (71) close to the conveying wheel (75) in the circumferential direction and positioned outside the shell (3), and the two gears (72) are meshed with each other;

the first transmission assembly (74) is connected between the end part of an output shaft of the servo motor (73) and one end of the rotating shaft (71) close to the base (1);

the rotating rod (76) is rotatably connected to one side of the shell (3) close to the conveying wheel (75) and the cut-off mechanism (9) in a penetrating mode;

the cam (77) is fixedly sleeved on the circumferential directions of two sides of the rotating rod (76) and is in contact fit with the cut-off mechanism (9);

a second transmission assembly (78), wherein the second transmission assembly (78) is connected between the end of one of the rotating shafts (71) far away from the gear (72) and the end of the rotating rod (76) far away from the first transmission assembly (74).

3. The continuously variable thick iron wire cutting machine according to claim 2, characterized in that the cutting mechanism (9) comprises:

the contact rod (95) is slidably connected to two sides of the shell (3) close to the conveying wheel (75) and far away from the base (1) in a penetrating manner;

the sleeve (91) is fixedly connected to the end part, far away from the conveying wheel (75), of the contact rod (95), and is positioned outside the shell (3);

the special-shaped sliding rod (98) is slidably placed in the sleeve (91), and the tail end of the special-shaped sliding rod (98) penetrates through the guide groove (4) to be slidably connected with one side of the swinging plate (6) facing the rotating shaft (71);

the fastening bolt (97) is rotatably threaded on the outer side circumferential direction of the sleeve (91) far away from the conveying wheel (75) through threads, and the inner end of the fastening bolt (97) is in contact fit with the special-shaped sliding rod (98);

a movable plate (92), wherein the movable plate (92) is rotatably connected between two sides in the shell (3) close to the rotating rod (76);

an oscillating block (94), said oscillating block (94) being rotatably connected to both ends of said movable plate (92) facing said conveying wheel (75), in contact engagement with said cam (77);

a torsion spring (912), the torsion spring (912) connected between the swing block (94) and the end of the movable plate (92);

the guide sleeves (910), the guide sleeves (910) are fixedly connected to one side of the movable plate (92) far away from the base (1) and the guide groove (4), the number of the guide sleeves (910) is two, and the guide sleeves (910) correspond to the swinging blocks (94);

the L-shaped rod (96), the L-shaped rod (96) is slidably threaded in the guide sleeve (910), and is matched with the contact rod (95) and the swinging block (94);

a second spring (911), the second spring (911) being connected between a side of the inside of the L-shaped lever (96) facing the swing block (94) and a side of the guide bush (910) away from the torsion spring (912);

the movable cutter (93) is slidably connected between two sides of the shell (3) close to the movable plate (92) in a penetrating manner, the movable cutter (93) is in contact fit with the end part of the movable plate (92) facing the base (1), and the movable cutter (93) is also matched with the fixed cutter (8);

the first spring (99) is symmetrically connected to one side, facing the movable cutter (93), of the base (1), and the tail end of the first spring (99) is fixedly connected with the inside of the shell (3).

4. A thick iron wire guillotine shear with adjustable stepless of claim 3, characterized by that, also include pushing equipment (10), pushing equipment (10) includes:

the n-type guide rod (103), the n-type guide rod (103) is slidably connected to one side of the shell (3) far away from the base (1) and close to the sleeve (91);

the push plate (105), the push plate (105) is fixedly connected between the ends of the n-type guide rod (103) facing the base (1);

the third spring (106) is sleeved on the two sides of the n-shaped guide rod (103) in the circumferential direction, one end of the third spring (106) is fixedly connected with one side, far away from the base (1), in the shell (3), and the other end of the third spring is fixedly connected with one side, far away from the base (1), of the push plate (105);

the rotating plate (104) is rotatably connected to one side of the n-shaped guide rod (103) far away from the conveying wheel (75) and the base (1) by the rotating plate (104);

the n-shaped rod (101), the n-shaped rod (101) is fixedly connected between the outer sides of the two sleeves (91) close to the fastening bolt (97);

the inclined block (102) is fixedly connected to one side, facing the n-type guide rod (103) and far away from the n-type rod (101) of the base (1), of the inclined block (102), and the inclined block is matched with the rotating plate (104).

5. The stepless adjustable thick iron wire cutting machine as claimed in claim 4, characterized by further comprising:

protective housing (11), protective housing (11) rigid coupling in be close to first drive assembly (74) base (1) one side, first drive assembly (74) with gear (72) are located in protective housing (11).

6. The stepless adjustable thick iron wire cutting machine as claimed in claim 5, characterized by further comprising:

the material receiving frame (12) and the roller (13), wherein the material receiving frame (12) is fixedly connected between the inner sides of the six support rods (2) close to the base (1);

the rotary drum (13), the rotary drum (13) is installed near the base (1) in an interval rotating mode on one side of the material receiving frame (12).