CN211494753U

CN211494753U - Online bundling machine for coiled materials

Info

Publication number: CN211494753U
Application number: CN201922248653.2U
Authority: CN
Inventors: 赵志文
Original assignee: Foshan Xuanyu Technology Co ltd
Current assignee: Foshan Xuanyu Technology Co ltd
Priority date: 2019-12-12
Filing date: 2019-12-12
Publication date: 2020-09-15
Anticipated expiration: 2029-12-12

Abstract

The utility model discloses an online binding machine for rolled materials, which belongs to the technical field of packaging machinery and comprises a frame, a case, a first sliding table, a binding core and a combined bow frame band channel, wherein the case is arranged on the frame through the sliding of the first sliding table, the binding core is arranged on the case, the combined bow frame band channel is arranged on the first sliding table, the combined bow frame band channel comprises a left band channel assembly, a right band channel assembly, a movable band channel assembly and a second sliding table, the left band channel assembly and the right band channel assembly are fixedly arranged on the first sliding table, the movable band channel assembly is arranged on the first sliding table through the sliding of the second sliding table, the movable band channel assembly drives the left band channel assembly to slide back and forth through the second sliding table, the left band channel assembly, the right band channel assembly and the movable band channel assembly form a bow frame band channel through the movable splicing, the first sliding table and the second sliding table drive the binding core and the combined bow frame band channel, realize the online automatic packing of bundling of rolling material.

Description

Online bundling machine for coiled materials

Technical Field

The utility model relates to the technical field of packaging machinery, in particular to online strapper of rolling material.

Background

The automatic double-station winding machine is applied to the industries of coiled materials and winding materials, and a plurality of development improvements are carried out according to different requirements, so that the automatic winding of various linear materials in online production is realized, and the production capacity of the linear materials is greatly improved. The linear materials which are wound need to be bundled and packaged on line, most of the existing bundling machines need to enable the materials to be bundled to be close to the bundling machines to achieve bundling and packaging, the bundling speed of manual-fit bundling or semi-automatic bundling is adopted, the improvement of the production capacity cannot be achieved, and the bundling speed of the linear materials after winding is completed limits the further improvement of the production capacity. Therefore, the online automatic bundling technology on the winding machine is a key technology for solving the systematic automation of the production link of the linear materials. However, due to the fact that technical difficulty is high and the matched binding is unstable, a key technical solution is basically blank in the domestic market, and the international market is almost monopolized. In 2019, at the international German plastic and rubber exhibition, no 368 exhibitors in China have the matched technology, and only three relevant rolled online automatic bundling and packaging technologies in Germany, Italy and Turkey are bright and meet all over the world.

SUMMERY OF THE UTILITY MODEL

The utility model provides an online strapper of rolling material realizes the online automation of rolling material and ties up the packing.

In order to solve the technical problem, the utility model discloses a technical scheme does:

an online bundling machine for wound materials comprises a rack, a case, a first sliding table, a bundling machine core and a combined bow frame band channel, wherein the case is arranged on the rack in a sliding mode through the first sliding table;

the bundling machine core and the combined bow frame band channel are driven by the first sliding table to slide in a reciprocating manner relative to the multi-station winding machine;

the combined type bow rack belt path comprises a left belt path assembly, a right belt path assembly, a movable belt path assembly and a second sliding table, wherein the left belt path assembly and the right belt path assembly are fixedly arranged on the first sliding table, the movable belt path assembly is arranged on the first sliding table in a sliding mode through the second sliding table, the movable belt path assembly drives the relative left belt path assembly to slide in a reciprocating mode through the second sliding table, and the left belt path assembly, the right belt path assembly and the movable belt path assembly form a bow rack belt path through movable splicing.

Preferably, the first sliding table comprises a guide rail group and a first driving cylinder, the case and the combined bow frame belt channel are connected with the guide rail group in a sliding mode through a connecting slider, and the case and the combined bow frame belt channel are driven by the first driving cylinder to slide on the guide rail group in a reciprocating mode;

the second slip table says slide rail, second including the area and drives actuating cylinder, the area says slide rail and guide rail group mutually perpendicular, the area says the slide rail and passes through link block sliding connection guide rail group, the removal area says that the sub-assembly says the slide rail through link block sliding connection area, the removal area says that the sub-assembly drives actuating cylinder through the second and drives reciprocating sliding on the slide rail is said in the area.

Preferably, the bundling machine core comprises a bundling mechanism, a feeding and returning belt tightening mechanism for pushing the bundling belt into the bundling mechanism and reversely returning the belt for tightening;

the feeding and withdrawing belt tightening mechanism comprises a mounting substrate, an auxiliary feeding and withdrawing bull wheel, a feeding and withdrawing belt motor for driving the auxiliary feeding and withdrawing bull wheel to rotate, an auxiliary feeding and withdrawing pinch roller, a tightening pressure adjusting rod, a feeding and withdrawing belt crescent guide plate, a belt channel guide groove, a feeding and withdrawing belt main wheel and a feeding and withdrawing belt pinch roller;

the conveying and returning belt crescent guide plate is arranged on the outer side of the auxiliary conveying and returning main wheel and forms an arc belt path with the auxiliary conveying and returning main wheel, the conveying and returning belt main wheel is arranged on the side edge of a belt path guide groove, the conveying and returning belt pressing wheel is arranged on the other side of the belt path guide groove and is movably abutted to and pressed by the conveying and returning belt main wheel, the belt path guide groove is communicated with the arc belt path, the tightening pressure adjusting rod is connected with the auxiliary conveying and returning pressing wheel through a tightening eccentric shaft, and the auxiliary conveying and returning pressing wheel is movably arranged on the outer side, close to the arc belt path, of the auxiliary conveying and returning main wheel through the tightening pressure adjusting rod.

Preferably, the belt feeding and retracting tightening mechanism further comprises a machine core belt inlet arranged on the mounting base plate, the machine core belt inlet is arranged on one side, away from the arc-shaped belt channel, of the auxiliary feeding and retracting large wheel and the auxiliary feeding and retracting pressing wheel, and the machine core belt inlet comprises two groups of guide blocks.

Preferably, the feeding and returning belt tightening mechanism further comprises a feeding and returning belt pressure adjusting rod, the feeding and returning belt pressure adjusting rod is connected with a feeding and returning belt pressing wheel through a feeding and returning belt eccentric shaft, and the feeding and returning belt pressing wheel is movably arranged on the side edge of the belt guide groove through the feeding and returning belt pressure adjusting rod.

Preferably, the bundling mechanism comprises a pressing and belt cutting mechanism, a head scalding crutch, a linkage crutch, a cam group and a main motor for driving the cam group to rotate;

the pressing and tape cutting mechanism is movably connected with the cam group, and the head scalding crutch, the linkage crutch and the cam group are movably connected.

Preferably, the pressing and tape cutting mechanism comprises a right cutter body, a right cutter, a middle cutter body, a middle cutter, a left cutter, an upper sliding plate and a T-shaped tape guide block, wherein the right cutter body, the right cutter, the middle cutter body, the middle cutter and the left cutter are movably arranged below the same side of the upper sliding plate, the T-shaped tape guide block is movably arranged between the middle cutter and the upper sliding plate, and a small detection swing rod is arranged at one end, close to the left cutter, of the upper sliding plate.

By adopting the technical scheme, when the multi-station winding machine winds materials, the case is positioned at the position, far away from the multi-station winding machine, of the first sliding table, the bundling machine core is positioned at an initial position, and the movable belt channel assembly is positioned at the rightmost side of the second sliding table; after the multi-station winding machine finishes material winding, the first sliding table is triggered and controlled to drive the case to slide towards the direction of the multi-station winding machine, the bundling machine core is tightly attached to the outer surface of one side of a wound material after being in place, the second sliding table drives the movable band channel assembly to slide leftwards, the left band channel assembly, the right band channel assembly and the movable band channel assembly are spliced to form an annular bow frame band channel, and preparation actions before bundling are finished.

After the bundling action is finished, the second sliding table and the first sliding table sequentially slide in opposite directions to drive the movable belt channel assembly to move towards the right side, and the bundling machine core slides in opposite directions to an initial position, so that the reset of the online bundling machine for the rolled materials is finished, and the next period of bundling is waited.

It should be noted that after the online bundling machine for the wound materials is reset, the multi-station winding machine can be controlled to rotate by a set angle according to needs, and then a plurality of bundling actions are performed in a circulating manner again, so that a plurality of bundling and packaging processes are performed on the wound materials.

Compared with the prior art, the on-line automatic bundling and packaging of the rolled materials can be realized through the technical scheme, so that the production capacity of the linear materials is improved.

Drawings

Fig. 1 is a schematic top view of the strapping core in the initial position according to the embodiment of the present invention;

fig. 2 is a schematic top view of the strapping machine core sliding to the side of the multi-station winder in the embodiment of the present invention;

fig. 3 is a schematic rear view of the embodiment of the present invention;

fig. 4 is a schematic top view of the strapping core in the initial position in the working state of the embodiment of the present invention;

fig. 5 is a schematic top view of the strapping core of the embodiment of the present invention when the strapping core is tightly attached to the outer surface of one side of the winding material in the working state;

fig. 6 is a schematic top view of the ring-shaped bow rack track formed by the assembly of the left track, the right track and the movable track in the working state of the embodiment of the present invention;

fig. 7 is a schematic side view of the working state of the embodiment of the present invention;

FIG. 8 is a schematic structural view of a belt tightening mechanism according to an embodiment of the present invention;

FIG. 9 is a schematic structural view of a strapping mechanism according to an embodiment of the present invention;

FIG. 10 is an enlarged view of the structure at A in FIG. 9;

fig. 11 is a schematic structural diagram of a strapping movement in an embodiment of the present invention.

In the figure, 10-rack, 20-cabinet, 31-first driving cylinder, 32-left guide rail, 33-middle guide rail, 34-right guide rail, 41-left belt path assembly, 42-right belt path assembly, 43-moving belt path assembly, 44-second sliding table, 45-belt path sliding rail, 46-second driving cylinder;

500-bundling machine core, 501-mounting base plate, 502-auxiliary delivering and receiving large wheel, 503-auxiliary delivering and receiving press wheel, 504-tightening pressure adjusting rod, 505-tightening eccentric shaft, 506-delivering and withdrawing belt crescent guide plate, 507-arc belt path, 508-belt path guide groove, 509-delivering and withdrawing belt main wheel, 510-delivering and withdrawing belt press wheel, 511-withdrawing belt pressure adjusting rod, 512-delivering and withdrawing belt eccentric shaft, 513-machine core belt inlet, 514-arc guide groove, 515-hot head crank, 516-cam group, 517-cam shaft, 518-cam base plate group, 519-switch plate, 520-main motor, 521-right knife body, 522-right knife, 523-middle knife body, 524-middle knife body, 525-left knife, 526-upper slide plate, 527-pressing groove, 528-a right guide block, 529-a left guide block, 530-a T-shaped conduction band block, 531-a linkage crank and 532-a small detection swing rod;

60-a multi-station winding machine.

Detailed Description

The following describes the present invention with reference to the accompanying drawings. It should be noted that the description of the embodiments is provided to help understanding of the present invention, but the present invention is not limited thereto. In addition, the technical features related to the embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

As shown in fig. 1-11, the utility model provides an online bundling machine for rolled materials, which comprises a frame 10, a case 20, a first sliding table, a bundling movement 500, and a combined bow frame belt path, wherein the case 20 is slidably arranged on the frame 10 through the first sliding table, the bundling movement 500 is arranged on the case 20, and the combined bow frame belt path is arranged on the first sliding table;

the bundling machine core 500 and the combined bow frame band channel are driven by the first sliding table to slide in a reciprocating manner relative to the multi-station winder 60;

the combined bow rack tape track comprises a left tape track assembly 41, a right tape track assembly 42, a movable tape track assembly 43 and a second sliding table 44, wherein the left tape track assembly 41 and the right tape track assembly 42 are fixedly arranged on the first sliding table, the left tape track assembly 41 is butted with an outlet of a T-shaped tape guide block 530 of the bundling machine core 500, the right tape track assembly 42 is butted with a right tape inserting port of the bundling machine core 500, the movable tape track assembly 43 is arranged on the first sliding table in a sliding mode through the second sliding table 44, the movable tape track assembly 43 drives the left tape track assembly 41 to slide in a reciprocating mode through the second sliding table 44, and the left tape track assembly 41, the right tape track assembly 42 and the movable tape track assembly 43 are movably spliced to form the bow rack tape track.

Specifically, when the multi-station winding machine 60 winds the material, the case 20 is located at a position where the first sliding table is far away from the multi-station winding machine 60, the bundling core 500 is located at an initial position, and the movable tape channel assembly 43 is located at the rightmost side of the second sliding table 44; after the multi-station winding machine 60 finishes winding the material, the first sliding table is triggered and controlled to drive the case 20 to slide towards the multi-station winding machine 60, the bundling machine core 500 is tightly attached to the outer surface of one side of the wound material after being in place, the second sliding table 44 drives the movable band channel assembly 43 to slide leftwards, the left band channel assembly 41, the right band channel assembly 42 and the movable band channel assembly 43 are spliced to form an annular bow frame band channel, and the preparation action before bundling is finished.

After the binding action is finished, the second sliding table 44 and the first sliding table sequentially slide in opposite directions to drive the movable belt channel assembly 43 to move towards the right side, and the binding machine core 500 slides in opposite directions to an initial position, so that the reset of the online binding machine for the rolled materials is finished, and the next cycle of binding is waited.

It should be noted that after the online bundling machine for the wound materials is reset, the multi-station winding machine 60 can be controlled to rotate by a set angle as required, and then a plurality of bundling actions are performed in a circulating manner, so that a plurality of bundling operations are performed on the wound materials.

Further, the first sliding table comprises a guide rail group and a first driving cylinder 31, the case 20 and the combined bow frame belt way are slidably connected with the guide rail group through a connecting slider, and the case 20 and the combined bow frame belt way are driven by the first driving cylinder 31 to slide on the guide rail group in a reciprocating manner;

the guide rail group comprises a left guide rail 32, a middle guide rail 33 and a right guide rail 34, the case 20 is connected with the left guide rail 32 and the middle guide rail 33 in a sliding mode through a connecting sliding block, and the second sliding table 44 is connected with the middle guide rail 33 and the right guide rail 34 in a sliding mode through a connecting sliding block;

the second sliding table 44 includes a belt guide rail 45 and a second driving cylinder 46, the belt guide rail 45 is perpendicular to the guide rail set, the belt guide rail 45 is slidably connected to the middle guide rail 33 and the right guide rail 34 in the guide rail set through a connection slider, the movable belt guide assembly 43 is slidably connected to the belt guide rail 45 through a connection slider, and the movable belt guide assembly 43 is driven by the second driving cylinder 46 to slide on the belt guide rail 45 in a reciprocating manner.

Further, the bundling machine core 500 comprises a bundling mechanism, a feeding and returning belt tightening mechanism for pushing the packing belt into the bundling mechanism and reversely returning the belt for tightening;

the feeding and withdrawing belt tightening mechanism comprises a mounting substrate 501, an auxiliary feeding and withdrawing bull wheel 502 for feeding, withdrawing and tightening the packing belt, a feeding and withdrawing belt motor for driving the auxiliary feeding and withdrawing bull wheel 502 to rotate, an auxiliary feeding and withdrawing pressure wheel 503 matched with the auxiliary feeding and withdrawing bull wheel 502 to press the packing belt tightly, a tightening pressure adjusting rod 504 for driving the auxiliary feeding and withdrawing pressure wheel 503 to movably press on the auxiliary feeding and withdrawing bull wheel 502, a feeding and withdrawing belt crescent guide plate 506, a belt path guide groove 508, a feeding and withdrawing belt main wheel 509 and a feeding and withdrawing belt pressure wheel 510, wherein the auxiliary feeding and withdrawing bull wheel 502, the auxiliary feeding and withdrawing pressure wheel 503, a tightening pressure adjusting rod 504, the feeding and withdrawing belt crescent guide plate 506, the belt path guide groove 508, the feeding and withdrawing belt main wheel 509 and the feeding and withdrawing belt pressure wheel 510 are all arranged on the mounting substrate 501, and the feeding and withdrawing belt motor for driving the auxiliary feeding and withdrawing bull wheel 502 to rotate is arranged on;

the belt feeding and withdrawing crescent guide plate 506 is arranged on the outer side of the auxiliary belt feeding and withdrawing bull wheel 502 and forms an arc-shaped belt track 507 with the auxiliary belt feeding and withdrawing bull wheel 502, the belt feeding and withdrawing main wheel 509 is arranged on the side edge of the belt track guide groove 508, the belt feeding and withdrawing roller 510 is arranged on the other side of the belt track guide groove 508 and is clamped on two sides of the belt track guide groove 508 in a mutually movable abutting mode with the belt feeding and withdrawing main wheel 509, the belt track guide groove 508 is communicated with the arc-shaped belt track 507, the tightening pressure adjusting rod 504 is connected with the auxiliary belt feeding and withdrawing roller 503 through the tightening eccentric shaft 505, and the auxiliary belt feeding and withdrawing roller 503 is movably arranged on the outer side, close to the arc-shaped belt track 507.

Specifically, when the tape is fed for the first time, the tape head of the packing tape stored in the tape storage bin enters the gap between the auxiliary feeding and retracting bull wheel 502 and the auxiliary feeding and retracting pinch wheel 503 through the arc-shaped guide groove 514 formed by the tape inlet 513 of the machine core, and enters the arc-shaped tape channel 507 formed by the feeding and retracting tape crescent guide plate 506 and the auxiliary feeding and retracting bull wheel 502, so that the action of the packing tape penetrating into the machine core is completed. Send and move back the belting motor and drive supplementary send and receive bull wheel 502 and penetrate tangent line angle direction along the packing area and rotate, synchronous accessible electro-magnet or cylinder drive tighten up pressure regulating rod 504, drive through the electro-magnet and tighten up pressure regulating rod 504 in this embodiment, promote supplementary send and receive pinch roller 503 and compress tightly the packing area on supplementary send and receive bull wheel 502, thereby in the rotation process of supplementary sending and receiving bull wheel 502, promote the packing area and carry forward along arc lane 507, then enter into lane guide slot 508, and the extrusion is through sending and moving back the clearance between belting main wheel 509 and send and move back belting pinch roller 510. At this time, the tightening pressure adjusting rod 504 moves in the reverse direction to drive the auxiliary feeding and retracting pressure wheel 503 to separate from the auxiliary feeding and retracting bull wheel 502, so as to complete the first feeding and conveying of the packing belt. The subsequent tape is fed forward along the loop-like bow lane by the high-speed rotation of the main feeding/discharging roller 509 and the feeding/discharging roller 510.

The main belt feeding and returning wheel 509 and the belt feeding and returning pinch roller 510 continuously press against the two sides of the packing belt, the auxiliary large belt feeding and returning wheel 502 continuously rotates for a unit belt feeding time under the control of a PLC program, and the belt drives the main belt feeding and returning wheel 509 and the belt feeding and returning pinch roller 510 to push the packing belt to feed forward at a high speed and enter a right side belt inserting port of the bundling mechanism. When the strapping tape is reversely withdrawn, the strapping tape is not easy to fall out from the tape feeding and withdrawing mechanism because the strapping tape is limited by the arc-shaped structure of the arc-shaped tape channel 507, thereby avoiding the phenomenon that the strapping tape falls off in the strapping and packaging process.

Further, the belt feeding and retracting tightening mechanism further comprises a belt inlet 513 of the machine core arranged on the mounting base plate 501, the belt inlet 513 of the machine core is arranged on one side, away from the arc-shaped belt channel 507, of the auxiliary feeding and retracting large wheel 502 and the auxiliary feeding and retracting pressing wheel 503, the belt inlet 513 of the machine core comprises two groups of guide blocks, an arc-shaped guide groove 514 is formed between the two groups of guide blocks, and a packing belt penetrates into the belt inlet 513 of the machine core from the arc-shaped guide groove 514.

When the tape is fed for the first time, due to insufficient tape feeding time or other abnormal conditions, the tape head is not fed in place and cannot trigger the bundling mechanism to detect the small swing rod 532, the PIC program controls the tape feeding and withdrawing motor to rotate reversely for one unit of tape withdrawing time, the tape withdrawing action is executed, the tape feeding and withdrawing main wheel 509 and the tape feeding and withdrawing pressing wheel 510 are pressed to drive the packaging tape to be conveyed reversely, the packaging tape is withdrawn into the arc-shaped tape channel 507, and the phenomenon that the packaging tape falls out from the tape inlet 513 of the machine core cannot occur due to the fact that the packaging tape is limited by the arc-shaped structure of the arc-shaped tape channel 507.

Further, the tape feeding and retracting tightening mechanism further comprises a tape feeding and retracting pressure adjusting rod 511, the tape feeding and retracting pressure adjusting rod 511 is connected with a tape feeding and retracting roller 510 through a tape feeding and retracting eccentric shaft 512, and the tape feeding and retracting roller 510 is movably arranged on the side edge of the tape guide channel 508 through the tape feeding and retracting pressure adjusting rod 511.

The belt feeding and retracting pressure adjusting rod 511 can be driven by an electromagnet or an air cylinder, the belt feeding and retracting pressure adjusting rod 511 is driven by the electromagnet in the embodiment, the clamping force of the belt feeding and retracting pinch roller 510 and the belt feeding and retracting main wheel 509 for clamping the packing belt is adjusted, and the high-speed and stable conveying of the packing belt is realized.

Further, the bundling mechanism comprises a pressing and belt cutting mechanism for pressing and cutting off the packing belt, an ironing head crank 515 for thermally bonding the packing belt, a linkage crank 531, a cam group 516 for driving the pressing and belt cutting mechanism, the ironing head crank 515 and the linkage crank 531 to be sequentially linked, and a main motor 520 for driving the cam group 516 to rotate;

the cam group 516 is rotatably arranged on the cam substrate group 518 through a cam shaft 517, the output shaft of the main motor 520 is in key connection with the cam shaft 517, the other end of the cam shaft 517 is in key connection with a switch panel 519, a plurality of grooves are formed in the switch panel 519, the position of each groove is detected through a photoelectric switch to judge the rotating angle of the cam group 516, the pressing and tape cutting mechanism is movably connected with the cam group 516, a hot crutch 515 is movably connected with the cam group 516, the annular bow frame tape channel is connected with the two sides of the pressing and tape cutting mechanism, a packaging tape conveyed into the pressing and tape cutting mechanism by the feeding and withdrawing tape tightening mechanism is guided and wound on an object through the annular bow frame tape channel and then is conveyed into the pressing and tape cutting mechanism in a retracing mode to form annular closing of the packaging tape and to.

Further, the pressing tape cutting mechanism comprises a right knife body 521, a right knife 522, a middle knife body 523, a middle knife 524, a left knife 525, an upper sliding plate 526 and a T-shaped tape guide block 530, wherein the right knife body 521, the right knife 522, the middle knife body 523, the middle knife 524 and the left knife 525 are movably arranged below the same side of the upper sliding plate 526, the T-shaped tape guide block 530 and the upper sliding plate 526 are arranged on a linkage turning hand 531, the linkage turning hand 531 is movably connected with the cam group 516, the T-shaped tape guide block 530 is movably arranged between the middle knife 524 and the upper sliding plate 526 through the linkage turning hand 531, and a small detection swing rod 532 used for triggering the in-place detection photoelectric switch is arranged at one end, close to the left knife 525, of the upper sliding;

the two ends of the upper sliding plate 526 are respectively connected with a right guide block 528 and a left guide block 529 in a sliding manner, the upper sliding plate 526 can slide along the right guide block 528 and the left guide block 529 under the driving of a linkage crank 531, the two ends of one side of the upper sliding plate 526, which faces the right cutter 522 and the left cutter 525, are respectively provided with a pressing groove 527, the middle part of the right cutter 522 is provided with a through groove, the right cutter 522 is arranged at the front end of the right cutter body 521, and the middle cutter 524 is arranged at the right side of the middle cutter body 523;

when the packing belt is conveyed, the packing belt enters the through groove in the middle of the right cutter 522 from the belt guide groove 508, sequentially enters the T-shaped belt guide block 530 and the annular bow frame belt channel, and then enters the belt inserting port formed between the upper sliding plate 526 and the T-shaped belt guide block 530. When the tape head of the packing tape is continuously conveyed forwards and impacts the small detection swing rod 532, an in-place detection photoelectric switch is triggered, or when one unit tape conveying time is finished, the PLC program controls the tape feeding and withdrawing motor to stop rotating, and the tape conveying action is finished.

When the small swing rod 532 for detecting the impact of the belt head of the packing belt triggers the photoelectric switch for checking the in-place, the PLC program controls the belt feeding and withdrawing motor to rotate reversely, and after the belt withdrawing action is executed, secondary belt feeding is carried out according to the normal belt feeding process.

When the small swing rod 532 for impact detection of the strapping head of the strapping tape triggers the in-place detection photoelectric switch, the main motor 520 is automatically triggered to rotate to drive the cam group 516 to rotate, the right cutter body 521 is jacked up, the front end of the right cutter 522 compresses the strapping tape on the pressing groove 527 on the right side of the upper sliding plate 526, the synchronous T-shaped strap guiding block 530 exits between the middle cutter 524 and the upper sliding plate 526, and the strap feeding and withdrawing motor rotates reversely for one unit of strap withdrawing time to complete the strap withdrawing action of normal strapping.

After the normal binding tape withdrawing action is finished, the tightening pressure adjusting rod 504 is synchronously driven by the electromagnet to push the auxiliary sending and receiving pressing wheel 503 to press the packing belt on the auxiliary sending and receiving large wheel 502, so that a binding force for tightening the packing belt and preventing the packing belt from sliding is formed.

Synchronously, the cam group 516 continues to rotate, the left knife 525 is jacked up, and the front end of the left knife 525 presses the packing belt onto the pressing groove 527 on the left side of the upper sliding plate 526. After the left knife 525 compresses the packing belt, the pressure adjusting rod 504 is tightened to reset, and the belt feeding and withdrawing motor stops reverse rotation.

The cam group 516 continues to rotate to jack up the middle cutter body 523 and the middle cutter 524, and the middle cutter body 521 cooperates with the through groove in the middle of the right cutter 522 to cut off the packing belt, so that the belt cutting action is completed. After the tape cutting operation is completed, the cam group 516 continues to rotate, and the middle blade body 523 and the middle blade 524 descend.

Then, the cam group 516 continues to rotate the head scalding crutch 515 to drive the head scalding crutch 515 to extend into the space between the upper and lower layers of the packing belts of the binding mechanism, and the hot scalding action is completed. Then the cam group 516 continues to rotate, the ironing head crank 515 drives the ironing head assembly to extend out of the space between the packing belts, and then the middle cutter body 523 continues to rotate and drive the upper cutter body to move upwards at the cam group 516, so that the upper and lower packing belts after being hot-ironed are pressed between the upper sliding plates 526, and the pressing action after bonding is completed. Then, the cam group 516 continues to rotate to drive the lower sliding plate 526 to retreat to the rear side through the T-shaped belt guiding block 530 arranged on the linkage crank 531, the tightened packing belt is ejected out of the binding mechanism under the elasticity of self tension, the cam group 516 continues to rotate the T-shaped belt guiding block 530 to return, and the upper sliding plate 526 resets. The main motor 520 is stopped and returns to the original state.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the described embodiments. It will be apparent to those skilled in the art that various changes, modifications, substitutions and alterations can be made in the embodiments without departing from the principles and spirit of the invention, and the scope of the invention is to be accorded the full scope of the claims.

Claims

1. The utility model provides an online strapper of rolling material which characterized in that: the binding machine comprises a rack (10), a case (20), a first sliding table, a binding machine core (500) and a combined bow frame band channel, wherein the case (20) is arranged on the rack (10) in a sliding mode through the first sliding table, the binding machine core (500) is arranged on the case (20), and the combined bow frame band channel is arranged on the first sliding table;

the combined bow rack band path comprises a left band path assembly (41), a right band path assembly (42), a movable band path assembly (43) and a second sliding table (44), wherein the left band path assembly (41) and the right band path assembly (42) are fixedly arranged on the first sliding table, the movable band path assembly (43) is arranged on the first sliding table in a sliding mode through the second sliding table (44), and the left band path assembly (41), the right band path assembly (42) and the movable band path assembly (43) are spliced through activity to form a bow rack band path.

2. The wound material in-line strapping machine of claim 1, wherein: the first sliding table comprises a guide rail group and a first driving cylinder (31), and the case (20) and the combined bow frame belt channel are slidably connected with the guide rail group through a connecting slide block;

second slip table (44) are including taking way slide rail (45), second drive actuating cylinder (46), take way slide rail (45) and guide rail group mutually perpendicular, take way slide rail (45) through link block sliding connection guide rail group, it takes way slide rail (45) through link block sliding connection to remove to take way sub-assembly (43).

3. The wound material in-line strapping machine of claim 1, wherein: the bundling machine core (500) comprises a bundling mechanism, a feeding and returning belt tightening mechanism for pushing a bundling belt into the bundling mechanism and reversely returning the belt for tightening;

the feeding and withdrawing belt tightening mechanism comprises a mounting substrate (501), an auxiliary feeding and withdrawing bull wheel (502), a feeding and withdrawing belt motor for driving the auxiliary feeding and withdrawing bull wheel (502) to rotate, an auxiliary feeding and withdrawing pressure wheel (503), a tightening pressure adjusting rod (504), a feeding and withdrawing belt crescent guide plate (506), a belt channel guide groove (508), a feeding and withdrawing belt main wheel (509) and a feeding and withdrawing belt pinch wheel (510);

the belt feeding and retracting device is characterized in that the feeding and retracting belt crescent guide plate (506) is arranged on the outer side of the auxiliary feeding and retracting bull wheel (502) and forms an arc-shaped belt channel (507) with the auxiliary feeding and retracting bull wheel (502), the feeding and retracting belt main wheel (509) is arranged on the side edge of the belt channel guide groove (508), the feeding and retracting belt pressing wheel (510) is arranged on the other side of the belt channel guide groove (508) and movably abutted against the feeding and retracting belt main wheel (509) and clamped on two sides of the belt channel guide groove (508), the belt channel guide groove (508) is communicated with the arc-shaped belt channel (507), the tightening pressure adjusting rod (504) is connected with the auxiliary feeding and retracting wheel (503) through a tightening eccentric shaft (505), and the auxiliary feeding and retracting wheel (503) is movably arranged on the outer side, close to the arc-shaped belt channel (507), of the auxiliary feeding and retracting bull wheel.

4. The wound material in-line strapping machine of claim 3, wherein: the feeding and returning belt tightening mechanism further comprises a machine core belt inlet (513) arranged on the mounting base plate (501), the machine core belt inlet (513) is arranged on one side, away from the arc belt channel (507), of the auxiliary feeding and retracting large wheel (502) and the auxiliary feeding and retracting pressing wheel (503), and the machine core belt inlet (513) comprises two groups of guide blocks.

5. The wound material in-line strapping machine of claim 3, wherein: the feeding and returning belt tightening mechanism further comprises a feeding and returning belt pressure adjusting rod (511), the feeding and returning belt pressure adjusting rod (511) is connected with a feeding and returning belt pressing wheel (510) through a feeding and returning belt eccentric shaft (512), and the feeding and returning belt pressing wheel (510) is movably arranged on the side edge of the belt guide groove (508) through the feeding and returning belt pressure adjusting rod (511).

6. The wound material in-line strapping machine of claim 3, wherein: the bundling mechanism comprises a pressing and belt cutting mechanism, a head scalding crutch (515), a linkage crutch (531), a cam group (516) and a main motor (520) for driving the cam group (516) to rotate;

the pressing and tape cutting mechanism is movably connected with the cam group (516), and the head scalding crutch (515), the linkage crutch (531) and the cam group (516) are movably connected.