CN111844890A - Cutting system of intelligence carton guillootine - Google Patents

Abstract

The invention relates to a cutting system of an intelligent carton cutting machine, which is characterized in that: comprises a longitudinal cutting mechanism and a transverse cutting mechanism; the longitudinal cutting mechanism comprises a longitudinal cutting assembly and a transverse moving positioning assembly; the longitudinal cutting assembly comprises a first transplanting support and an air bag cylinder which is used for controlling the first transplanting support to be clamped and fixed or movable relative to the cutting rack, and the air bag cylinder is arranged between the first transplanting support and the cutting rack; the transverse moving positioning assembly comprises a second transplanting bracket transversely moving on the cutting rack and a traction mechanism for drawing the designated longitudinal cutting assembly to transversely move, and the traction mechanism is arranged on the second transplanting bracket and transversely moves relative to the cutting rack along with the second transplanting bracket; and a first transverse moving power assembly for driving the second transplanting support to transversely move is arranged between the second transplanting support and the cutting rack. The cutting system is wide in applicable processing range, low in manufacturing cost and flexible in processing.

Description

Cutting system of intelligence carton guillootine

Technical Field

The invention relates to a carton cutting machine, in particular to a cutting system of an intelligent carton cutting machine.

Background

Chinese patent document CN208006333U discloses a press-cutting mechanism for a carton cutting machine, and specifically discloses: the cutting machine comprises a cutting frame, a plurality of groups of longitudinal pressing and cutting assemblies and transverse pressing and cutting assemblies, wherein a longitudinal pressing and cutting assembly driving device and a transverse pressing and cutting assembly driving device are arranged on the cutting frame, and a plurality of groups of linear guide rail assemblies which are parallel to each other are horizontally arranged; the longitudinal pressing and cutting assembly driving device comprises a longitudinal pressing and cutting assembly driving rack connected with the cutting rack, the longitudinal pressing and cutting assembly driving rack is parallel to the linear guide rail assembly, the longitudinal pressing and cutting assembly comprises a servo motor driving mechanism, the servo motor driving mechanism comprises a longitudinal pressing and cutting servo motor and a driving gear coaxially connected with an output shaft of the longitudinal pressing and cutting servo motor, and the driving gear is meshed with the longitudinal pressing and cutting assembly driving rack. In the pressing and cutting mechanism, in order to ensure that each group of longitudinal pressing and cutting components can move transversely, a servo motor driving mechanism is arranged on each group of longitudinal pressing and cutting components, the servo motor driving mechanism drives a driving gear to rotate, and the transverse movement of the longitudinal pressing and cutting components is realized under the action of a gear rack structure; however, because each group of longitudinal pressing and cutting assemblies needs to be provided with a servo motor, the center distance between two adjacent longitudinal pressing and cutting assemblies is larger (namely, the center distance between the cutter and the cutter is larger, and the center distance between the longitudinal indentation roller and the longitudinal indentation roller is larger), when the required distance between two indentation lines or between two cutting lines is smaller than the center distance between two longitudinal pressing and cutting assemblies, the two adjacent indentation lines or the two adjacent cutting lines cannot be finished simultaneously, and therefore, the processing and production efficiency is directly influenced; in addition, each group of longitudinal pressing and cutting assemblies needs to be provided with a corresponding motor, so that the equipment manufacturing cost is high, and a control system is adopted.

Therefore, further improvements are needed.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provides a cutting system of an intelligent carton cutting machine, which is wide in applicable processing range, low in manufacturing cost and flexible in processing.

The purpose of the invention is realized as follows:

the utility model provides a cutting system of intelligence carton guillootine which characterized in that: comprises a longitudinal cutting mechanism and a transverse cutting mechanism which are respectively arranged on a cutting frame; the longitudinal cutting mechanism comprises more than one group of longitudinal cutting components used for finishing longitudinal indentation work and longitudinal cutting work respectively and a transverse moving positioning component used for driving more than one group of longitudinal cutting components to transversely position and move on the cutting machine frame; the longitudinal cutting assembly comprises a first transplanting support transversely moving on the cutting rack and an air bag cylinder used for controlling the first transplanting support to be clamped and fixed or movable relative to the cutting rack, and the air bag cylinder is arranged between the first transplanting support and the cutting rack; the transverse moving positioning assembly comprises a second transplanting bracket transversely moving on the cutting rack and a traction mechanism for drawing the designated longitudinal cutting assembly to transversely move, and the traction mechanism is arranged on the second transplanting bracket and transversely moves relative to the cutting rack along with the second transplanting bracket; and a first transverse moving power assembly for driving the second transplanting support to transversely move is arranged between the second transplanting support and the cutting rack.

The longitudinal cutting assembly also comprises a longitudinal indentation roller for finishing longitudinal indentation work and a longitudinal cutter for finishing longitudinal cutting work; the longitudinal indentation roller and the longitudinal cutter are respectively and longitudinally and rotatably arranged; a longitudinal indentation power cylinder used for controlling the longitudinal indentation roller to act or not act on the paperboard is arranged between the first transplanting bracket and the longitudinal indentation roller; and a longitudinal cutting power cylinder used for controlling the longitudinal cutter to act or not act on the paperboard is arranged between the first transplanting bracket and the longitudinal cutter.

The cylinder body of the longitudinal indentation power cylinder is arranged on the first transplanting support, a piston rod of the longitudinal indentation power cylinder is connected with the longitudinal indentation roller to drive the longitudinal indentation roller to move up and down relative to the first transplanting support, the longitudinal indentation roller acts on the paperboard when moving downwards to a certain position, and the longitudinal indentation roller does not act on the paperboard when moving upwards to a certain position; the cylinder body of the longitudinal cutting power cylinder is arranged on the first transplanting support, a piston rod of the longitudinal cutting power cylinder is connected with the longitudinal cutter to drive the longitudinal cutter to move up and down relative to the first transplanting support, the longitudinal cutter acts on the paperboard when moving downwards to a certain position, and the longitudinal cutter does not act on the paperboard when moving upwards to a certain position.

The cutting machine is characterized in that a transversely extending positioning plate is arranged on the cutting machine frame, the first transplanting support is located on the inner side of the positioning plate and moves transversely relatively, at least part of the air bag cylinder is exposed out of the outer side wall of the first transplanting support and corresponds to the positioning plate, the air bag cylinder at least extrudes the positioning plate in an expansion state to enable the first transplanting support to be clamped and fixed on the cutting machine frame, and the air bag cylinder at least does not act on the positioning plate in a contraction state to enable the first transplanting support to move relatively to the cutting machine.

The first transplanting support is provided with a paper pressing part, the paper pressing part is provided with a pressing action part for pressing a paper board, and the longitudinal indentation roller and/or the longitudinal cutter protrudes outwards from the pressing action part when moving to a certain position.

The traction mechanism comprises a traction cylinder and a contact pin, the traction cylinder drives the contact pin to be inserted into or separated from a traction hole in the longitudinal cutting assembly, so that the transverse moving positioning assembly is connected with or separated from the longitudinal cutting assembly, and the transverse moving positioning assembly in a connection state pulls the longitudinal cutting assembly to move transversely.

The first transverse moving power assembly comprises a first transverse moving crawler belt for driving the second transplanting bracket to transversely move; the second transplanting bracket is provided with a transmission assembly used for connecting the first transverse moving crawler; the transmission assembly comprises a transmission movable block and a transmission fixed block; the transmission movable block can be movably adjusted relative to the second transplanting support, and the first transverse moving crawler is clamped between the transmission movable block and the transmission fixed block.

A stroke sensor is arranged on the cutting frame; the second transplanting support is provided with an induction block, when the second transplanting support moves to a set position relative to the cutting rack, the stroke inductor corresponds to the induction block, and the transverse moving positioning assembly stops moving.

The transverse cutting mechanism comprises a third transplanting bracket which transversely moves on the cutting rack, a transverse indentation roller wheel for finishing transverse indentation work and a transverse cutter for finishing transverse cutting work, and the transverse indentation roller wheel and the transverse cutter are respectively and transversely and rotatably arranged; a transverse indentation power cylinder used for controlling the transverse indentation roller to act or not act on the paperboard is arranged between the third transplanting bracket and the transverse indentation roller; a transverse cutting power cylinder used for controlling the transverse cutter to act or not act on the paperboard is arranged between the third transplanting bracket and the transverse cutter; and a second transverse moving power assembly for driving the third transplanting support to transversely move is arranged between the third transplanting support and the cutting rack.

A positioning assembly consisting of a positioning conical head, a positioning cylinder and a positioning sensor is arranged on the third transplanting bracket; the cylinder body of the positioning cylinder and the positioning sensor are respectively and fixedly arranged on the third transplanting bracket, and a piston rod of the positioning cylinder is connected with the positioning conical head; the longitudinal cutting assembly is provided with an induction part with a positioning hole; when the transverse cutting mechanism transversely moves to the position sensor and corresponds to the sensing part, the positioning cylinder drives the positioning conical head to be inserted into the positioning hole, so that the transverse cutting mechanism is positioned.

The invention has the following beneficial effects:

in the longitudinal cutting mechanism, the longitudinal cutting components transversely move on the cutting rack in an external force action mode, and because the moving power is derived from external force, related power elements (such as a motor, a cylinder and the like) do not need to be arranged on the longitudinal cutting components, so that the volume of the longitudinal cutting components is minimized, the center distance between every two adjacent longitudinal cutting components is small, the applicable processing range is wide compared with the traditional structure, and most processing requirements are met; in addition, because the power element is omitted in each group of longitudinal cutting assemblies, the manufacturing cost of the whole equipment is greatly reduced, and the equipment is simple and quick; the transverse moving of the longitudinal cutting assembly is achieved by arranging the transverse moving positioning assembly to pull the longitudinal cutting assembly to move transversely, and the transverse moving positioning assembly is separated from or connected with the longitudinal cutting assembly through the traction mechanism, so that a plurality of sets of longitudinal cutting assemblies can be controlled by one set of transverse moving positioning assembly to transversely move to a specified position respectively, the traction performance is reliable, and the structure is simple and reasonable.

In the transverse cutting mechanism, a transverse indentation roller is matched with an indentation power cylinder, a transverse cutter is matched with a cutting power cylinder, the indentation power cylinder and the cutting power cylinder are not interfered with each other, and a system can respectively control the indentation power cylinder and the cutting power cylinder to work in a matched mode according to processing requirements, so that indentation and cutting actions are flexibly controlled, the performance is reliable, the working efficiency is high, and the working quality is effectively guaranteed; the transverse cutting mechanism realizes transverse movement under the control of the transverse moving power assembly, and has the effects of reliable performance, high moving speed, sensitive response and the like; under the action of the positioning assembly, the transverse cutting mechanism can realize effective/accurate positioning, and further improve indentation and cutting accuracy.

Drawings

Fig. 1 is a perspective view of an internal structure of a cutting system in an intelligent carton cutting machine according to an embodiment of the present invention.

Fig. 2 is a front view of the internal structure of the cutting system in the intelligent carton cutting machine according to an embodiment of the present invention.

Fig. 3 is a rear view of the internal structure of the cutting system in the intelligent carton cutting machine according to an embodiment of the present invention.

Fig. 4 is a side view of the internal structure of the cutting system in the intelligent carton cutting machine according to an embodiment of the invention.

FIG. 5 is a front view of a longitudinal cutting assembly in an embodiment of the present invention.

FIG. 6 is a left side view of a longitudinal cutting assembly in an embodiment of the present invention.

Fig. 7 is a sectional view taken in the direction H-H in fig. 6.

FIG. 8 is a perspective view of a longitudinal cutting assembly in an embodiment of the present invention.

FIG. 9 is a front view of a traversing stop assembly according to an embodiment of the invention.

FIG. 10 is a top view of a traversing stop assembly according to an embodiment of the invention.

FIG. 11 is a left side view of the traversing stop assembly in accordance with an embodiment of the invention.

FIG. 12 is a rear view of a traversing stop assembly according to an embodiment of the invention.

FIG. 13 is a schematic view of the attachment of the longitudinal cutting assembly to the traversing positioning assembly in accordance with one embodiment of the present invention.

Fig. 14 is a front view of a lateral cutting mechanism in an embodiment of the present invention.

Fig. 15 is a rear view of a lateral cutting mechanism in an embodiment of the present invention.

Fig. 16 is a left side view of the lateral cutting mechanism in an embodiment of the present invention.

Fig. 17 is a perspective view of a lateral cutting mechanism in an embodiment of the invention.

Fig. 18 is a partial structural schematic view of a transverse cutting mechanism according to an embodiment of the invention.

FIG. 19 is a schematic view of the attachment of the longitudinal cutting assembly to the transverse cutting mechanism in one embodiment of the present invention.

Detailed Description

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

Referring to fig. 1-19, the cutting system of the intelligent carton cutting machine comprises a longitudinal cutting mechanism and a transverse cutting mechanism C respectively arranged on a cutting frame D; the longitudinal cutting mechanism comprises more than one group of longitudinal cutting assemblies A used for finishing longitudinal indentation work and longitudinal cutting work respectively and a transverse moving positioning assembly B used for driving more than one group of longitudinal cutting assemblies A to move on the cutting rack D in a transverse positioning mode; the longitudinal cutting assembly A transversely moves on the cutting rack D under the action of external force (the external force can be driven by hands or by an electric motor, and the like), namely a power element for controlling movement is cancelled on the longitudinal cutting assembly A, and compared with the prior art, the motor is cancelled; the longitudinal cutting assembly A comprises a first transplanting bracket A1 which transversely moves on the cutting rack D, and an air bag cylinder A2 which is used for controlling the first transplanting bracket A1 to be clamped and fixed or movable relative to the cutting rack D, wherein the air bag cylinder A2 is arranged between the first transplanting bracket A1 and the cutting rack D; the transverse moving positioning assembly B comprises a second transplanting bracket B1 which transversely moves on the cutting rack D and a traction mechanism for drawing the designated longitudinal cutting assembly A to transversely move, and the traction mechanism is arranged on the second transplanting bracket B1 and transversely moves relative to the cutting rack D along with the second transplanting bracket B1; a first transverse moving power assembly for driving the second transplanting bracket B1 to transversely move is arranged between the second transplanting bracket B1 and the cutting machine frame D.

Further, referring to fig. 5-8, the longitudinal cutting assembly a further comprises a longitudinal creasing roller a9 for performing longitudinal creasing work, a longitudinal cutter a5 for performing longitudinal cutting work; the longitudinal indentation roller A9 and the longitudinal cutter A5 are respectively longitudinally and rotatably arranged and longitudinally arranged side by side; a longitudinal indentation power cylinder A7 used for controlling the action or non-action of the longitudinal indentation roller A9 on the paperboard is arranged between the first transplanting bracket A1 and the longitudinal indentation roller A9; a longitudinal cutting power cylinder A3 used for controlling the longitudinal cutter A5 to act or not act on the paperboard is arranged between the first transplanting bracket A1 and the longitudinal cutter A5; the longitudinal indentation power cylinder A7, the longitudinal cutting power cylinder A3 and the air bag cylinder A2 work independently without interference with each other, and the longitudinal indentation power cylinder A7 and the longitudinal cutting power cylinder A3 are longitudinally arranged side by side.

Further, a cylinder body of a longitudinal indentation power cylinder A7 is fixedly arranged on the first transplanting bracket A1, a piston rod of the longitudinal indentation power cylinder A7 extends downwards and is rotatably connected with a longitudinal indentation roller A9 through a corresponding first adapter A8 so as to drive the longitudinal indentation roller A9 to move up and down relative to the first transplanting bracket A1; the longitudinal indentation roller A9 acts on the paperboard when moving downwards to a certain position, so as to press a longitudinal indentation line; when the longitudinal creasing roller A9 moves upwards to a certain position, it does not act on the paper board, so as to prevent the longitudinal creasing roller A9 from affecting the paper board in a non-creasing state. The cylinder body of the longitudinal cutting power cylinder A3 is arranged on the first transplanting bracket A1, and the piston rod of the longitudinal cutting power cylinder A3 extends downwards and is rotatably connected with the longitudinal cutter A5 through the corresponding first transfer seat A8 so as to drive the longitudinal cutter A5 to move up and down relative to the first transplanting bracket A1; the longitudinal cutter A5 acts on the paperboard when moving downwards to a certain position, so as to cut the paperboard longitudinally; when the longitudinal cutter A5 moves upwards to a certain position, the longitudinal cutter A5 does not act on the paperboard, so that the paperboard is prevented from being damaged by the longitudinal cutter A5 in a non-cutting state.

Furthermore, two positioning plates D1 which correspond to each other and respectively extend transversely are arranged on the cutting frame D, the first transplanting bracket A1 is positioned between the inner sides of the two positioning plates D1 and moves transversely relatively, the air bag cylinder A2 is at least partially exposed out of the outer side wall of the first transplanting bracket A1 and corresponds to the positioning plate D1, and a proper gap is formed between the air bag cylinder A2 and the positioning plate D1 in an initial state; the air bag cylinder A2 extrudes the positioning plate D1 at least in an expansion state, so that the first transplanting bracket A1 is clamped and fixed on the cutting rack D, and the longitudinal cutting assembly A is effectively positioned relative to the cutting rack D; the air bag cylinder A2 does not act on the positioning plate D1 at least in the contraction state, so that the first transplanting support A1 can move relative to the cutting machine frame D, and the influence on the transverse movement of the longitudinal cutting assembly A relative to the cutting machine frame D is avoided.

Further, a paper pressing part A6 is fixedly arranged at the bottom of the first transplanting bracket A1, the bottom end face of the paper pressing part A6 is a pressing action part A601 used for pressing the paper board, and the longitudinal indentation roller A9 and the longitudinal cutter A5 protrude out of the pressing action part A601 when moving downwards to a certain position so as to act on the paper board well.

Further, fixedly on two lateral walls of first transplanting support A1 being provided with first guide rail slider A4 respectively, fixedly on the cutting frame D being provided with transversely extending's first transverse guide rail, first transverse guide rail is specifically the inside wall that is fixed in locating plate D1, first guide rail slider A4 slides on first transverse guide rail, and first guide rail slider A4 mutually supports with first transverse guide rail, effectively guides vertical cutting assembly A lateral shifting. Eight groups (or more than one group, according to production needs) of longitudinal cutting assemblies A which are transversely arranged side by side are arranged on the intelligent carton cutting machine related to the embodiment.

Further, referring to fig. 9-12, the traction mechanism comprises a traction cylinder B2 and a contact pin B3, the traction cylinder B2 drives the contact pin B3 to be inserted into or separated from a traction hole a11 on the longitudinal cutting assembly a, so that the traverse positioning assembly B is connected with or separated from the longitudinal cutting assembly a, and the traverse positioning assembly B in the connected state pulls the longitudinal cutting assembly a to move transversely, so that the traverse positioning assembly B pulls the longitudinal cutting assembly a transversely. The cylinder body of the traction cylinder B2 is fixedly arranged on the second transplanting bracket B1, and the piston rod of the traction cylinder B2 is fixedly connected with the contact pin B3 so as to drive the contact pin B3 to move up and down; specifically, referring to fig. 13, when the pulling cylinder B2 drives the pin B3 to move downward to a set position, the pin B3 is inserted into the pulling hole a11, and the traverse positioning assembly B can pull the longitudinal cutting assembly a to move laterally; when the traction cylinder B2 drives the contact pin B3 to move upwards to a set position, the contact pin B3 is separated from the traction hole A11, at the moment, the transverse moving positioning assembly B and the longitudinal cutting assembly A do not interfere with each other, namely the transverse moving positioning assembly B pulls the next group of longitudinal cutting assemblies A or stops working according to the system specification, and the longitudinal cutting assembly A which finishes moving is positioned at the final moving position through the positioning action of the air bag cylinder A2.

Further, the first transverse moving power assembly comprises a first transverse moving crawler B4 for driving the second transplanting support B1 to transversely move, a first transverse moving servo motor D2 and more than two first transverse moving transmission rollers D3, the first transverse moving servo motor D2 is fixedly arranged on the cutting rack D, at least one first transverse moving transmission roller D3 is in transmission connection with a motor shaft of the first transverse moving servo motor D2, the first transverse moving crawler B4 is wound on the outer sides of more than two first transverse moving transmission rollers D3, and when the first transverse moving servo motor D2 works, at least part of the first transverse moving crawler B4 transversely moves. The second transplanting bracket B1 is provided with a transmission assembly used for connecting the first traverse crawler B4, so that the first traverse crawler B4 drives the traverse positioning assembly B to move transversely; the transmission assembly comprises a transmission movable block B6 and a transmission fixed block B5; the transmission movable block B6 can be movably adjusted relative to the second transplanting bracket B1, the first transverse moving track B4 is clamped between the transmission movable block B6 and the transmission fixed block B5, and the transmission assembly is connected with the first transverse moving track B4 in a clamping mode.

Further, a stroke sensor D4 is arranged on the cutting frame D; the second transplanting bracket B1 is provided with a sensing block B8, when the second transplanting bracket B1 moves to a set position relative to the cutting rack D, a stroke sensor D4 corresponds to the sensing block B8, at the moment, a stroke sensor D4 feeds back a corresponding sensing signal to the system, the system immediately judges that the transverse moving positioning component B reaches a specified position, and the system controls the transverse moving positioning component B to stop moving through the first transverse moving power component. The bottom of the second transplanting bracket B1 is provided with a second guide rail sliding block B9, the cutting rack D is provided with a second transverse guide rail D5 which extends transversely, the second guide rail sliding block B9 slides on the second transverse guide rail D5, and the second guide rail sliding block B9 is matched with the second transverse guide rail D5 to effectively guide the transverse movement of the transverse movement positioning component B.

Further, referring to fig. 14 to 18, the transverse cutting mechanism C includes a third transplanting frame C1 transversely moving on the cutting frame D, a transverse creasing roller C6 for performing transverse creasing work, and a transverse cutter C11 for performing transverse cutting work, the transverse creasing roller C6 and the transverse cutter C11 are respectively transversely rotatably disposed and arranged side by side transversely to each other; a transverse indentation power cylinder C4 used for controlling the action or non-action of the transverse indentation roller C6 on the paperboard is arranged between the third transplanting bracket C1 and the transverse indentation roller C6; a transverse cutting power cylinder C10 used for controlling the action or non-action of the transverse cutter C11 on the paperboard is arranged between the third transplanting bracket C1 and the transverse cutter C11, the transverse indentation power cylinder C4 and the transverse cutting power cylinder C10 do not interfere with each other and work independently, and the transverse indentation power cylinder C4 and the transverse cutting power cylinder C10 are arranged transversely side by side; a second transverse moving power assembly for driving the third transplanting bracket C1 to transversely move is arranged between the third transplanting bracket C1 and the cutting machine frame D.

Further, a cylinder body of the transverse indentation power cylinder C4 is fixedly arranged on the third transplanting bracket C1, a piston rod of the transverse indentation power cylinder C4 extends downward and is rotatably connected with a transverse indentation roller C6 through a corresponding second adapter C5 to drive the transverse indentation roller C6 to move up and down relative to the third transplanting bracket C1, the transverse indentation roller C6 acts on the paperboard to press out a transverse indentation line when moving downward to a certain position, and the transverse indentation roller C6 does not act on the paperboard when moving upward to a certain position to prevent the transverse indentation roller C6 from influencing the paperboard in a non-indentation working state. The fixed cylinder body of the transverse cutting power cylinder C10 is arranged on the third transplanting support C1, a piston rod of the transverse cutting power cylinder C10 extends downwards and is rotatably connected with a transverse cutter C11 through a corresponding second adapter C5 to drive the transverse cutter C11 to move up and down relative to the third transplanting support C1, the transverse cutter C11 acts on the paperboard when moving downwards to a certain position to cut the paperboard transversely, and the transverse cutter C11 does not act on the paperboard when moving upwards to a certain position to prevent the transverse cutter C11 from damaging the paperboard in a non-transverse cutting working state.

Further, the second traverse power assembly comprises a second traverse servo motor C7, a second traverse transmission roller C3 and a second traverse crawler C14; a second transverse moving servo motor C7 is fixedly arranged at the top of the third transplanting bracket C1, and a motor shaft of the second transverse moving servo motor C7 is connected with a second transverse moving transmission roller C3 through a reduction box; the second traverse transmission roller C3 is engaged with the second traverse track C14; the second traverse crawler C14 is transversely arranged on the cutting frame D (two ends of the second traverse crawler C14 are respectively and fixedly connected with the cutting frame D); the second traverse servo motor C7 drives the second traverse transmission roller C3 to roll relatively on the second traverse track C14, so that the third transplanting frame C1 moves laterally relative to the cutting frame D. Specifically, the second traverse power assembly further includes a cooperating roller C12 for acting upon the second traverse drive roller C3 for operative engagement with the second traverse track C14; the two cooperation rollers C12 are rotatably arranged on the third transplanting bracket C1 respectively, the projection of the second traverse transmission roller C3 is positioned between the two cooperation rollers C12, the second traverse transmission roller C3 is positioned on one side of the second traverse crawler C14, the cooperation roller C12 is positioned on the other side of the second traverse crawler C14 and extrudes the second traverse crawler C14, and the second traverse crawler C14 can be effectively meshed with the second traverse transmission roller C3 under the cooperation of the two cooperation rollers C12, so that the transmission effectiveness is ensured.

Further, a third guide rail slide block C13 is arranged on the third transplanting bracket C1; a third transverse guide rail D7 which extends transversely is fixedly arranged on the cutting rack D; the third guide slider C13 slides on the third cross guide D7, effectively guiding the lateral cutting mechanism C to move laterally.

Furthermore, a positioning assembly consisting of a positioning conical head C9, a positioning cylinder C2 and a positioning sensor C8 is arranged on the third transplanting bracket C1; a cylinder body of the positioning cylinder C2 and a positioning sensor C8 are respectively and fixedly arranged on the third transplanting bracket C1, and a piston rod of the positioning cylinder C2 is connected with a positioning conical head C9 so as to drive the positioning conical head C9 to do reciprocating telescopic movement; the longitudinal cutting assembly A is provided with a sensing component A15 with a positioning hole A1501; when the transverse cutting mechanism C moves transversely to the position sensor C8 to correspond to the sensing component, the positioning cylinder C2 drives the positioning conical head C9 to be inserted into the positioning hole A1501, so that the transverse cutting mechanism C is positioned. Specifically, referring to fig. 19, a sensing part a15 is disposed at a side of the longitudinal cutting assembly a, and when the transverse cutting mechanism C moves transversely to correspond to the front and rear of the corresponding longitudinal cutting assembly a, the positioning cylinder C2 drives the positioning conical head C9 to extend outwards and insert into the corresponding positioning hole a1501, so that the transverse cutting mechanism C is maintained to correspond to and be positioned in the designated longitudinal cutting assembly a.

The foregoing is a preferred embodiment of the present invention, and the basic principles, principal features and advantages of the invention are shown and described. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are intended to illustrate the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, and the invention is intended to be protected by the following claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a cutting system of intelligence carton guillootine which characterized in that: comprises a longitudinal cutting mechanism and a transverse cutting mechanism (C) which are respectively arranged on a cutting frame (D); the longitudinal cutting mechanism comprises more than one group of longitudinal cutting assemblies (A) used for finishing longitudinal indentation work and longitudinal cutting work respectively and a transverse moving positioning assembly (B) used for driving more than one group of longitudinal cutting assemblies (A) to transversely position and move on a cutting rack (D); the longitudinal cutting assembly (A) comprises a first transplanting bracket (A1) which transversely moves on the cutting rack (D), and an air bag cylinder (A2) which is used for controlling the first transplanting bracket (A1) to be clamped and fixed or movable relative to the cutting rack (D), wherein the air bag cylinder (A2) is arranged between the first transplanting bracket (A1) and the cutting rack (D); the transverse moving positioning assembly (B) comprises a second transplanting bracket (B1) which transversely moves on the cutting rack (D) and a traction mechanism which is used for drawing the designated longitudinal cutting assembly (A) to transversely move, and the traction mechanism is arranged on the second transplanting bracket (B1) and transversely moves relative to the cutting rack (D) along with the second transplanting bracket (B1); a first transverse moving power assembly for driving the second transplanting bracket (B1) to transversely move is arranged between the second transplanting bracket (B1) and the cutting frame (D).

2. The cutting system of intelligent carton cutting machine according to claim 1, characterized in that: the longitudinal cutting assembly (A) further comprises a longitudinal creasing roller (A9) for completing longitudinal creasing work and a longitudinal cutter (A5) for completing longitudinal cutting work; the longitudinal indentation roller (A9) and the longitudinal cutter (A5) are respectively arranged in a longitudinal rotating way; a longitudinal indentation power cylinder (A7) used for controlling the longitudinal indentation roller (A9) to act or not act on the paperboard is arranged between the first transplanting bracket (A1) and the longitudinal indentation roller (A9); a longitudinal cutting power cylinder (A3) used for controlling the longitudinal cutter (A5) to act or not act on the paperboard is arranged between the first transplanting bracket (A1) and the longitudinal cutter (A5).

3. The cutting system of intelligent carton cutting machine of claim 2, characterized in that: the cylinder body of the longitudinal indentation power cylinder (A7) is arranged on the first transplanting bracket (A1), the piston rod of the longitudinal indentation power cylinder (A7) is connected with the longitudinal indentation roller (A9) to drive the longitudinal indentation roller (A9) to move up and down relative to the first transplanting bracket (A1), the longitudinal indentation roller (A9) acts on the paperboard when moving downwards to a certain position, and the longitudinal indentation roller (A9) does not act on the paperboard when moving upwards to a certain position; the cylinder body of the longitudinal cutting power cylinder (A3) is arranged on the first transplanting support (A1), a piston rod of the longitudinal cutting power cylinder (A3) is connected with the longitudinal cutter (A5) to drive the longitudinal cutter (A5) to move up and down relative to the first transplanting support (A1), the longitudinal cutter (A5) acts on the paperboard when moving downwards to a certain position, and the longitudinal cutter (A5) does not act on the paperboard when moving upwards to a certain position.

4. The cutting system of intelligent carton cutting machine according to claim 1, characterized in that: be equipped with horizontal extension's locating plate (D1) on cutting frame (D), first transplanting support (A1) is located locating plate (D1) inboard and relative lateral shifting, gasbag cylinder (A2) at least part expose in first transplanting support (A1) lateral wall and correspond with locating plate (D1), gasbag cylinder (A2) extrude locating plate (D1) under the inflation state at least, make first transplanting support (A1) press from both sides tightly to be fixed in cutting frame (D), gasbag cylinder (A2) do not act on locating plate (D1) under the shrink state at least, make first transplanting support (A1) relative cutting frame (D) portable.

5. The cutting system of intelligent carton cutting machine according to claim 1, characterized in that: the first transplanting bracket (A1) is provided with a paper pressing part (A6), the paper pressing part (A6) is provided with a pressing action part (A601) for pressing a paper board, and the longitudinal indentation roller (A9) and/or the longitudinal cutter (A5) protrude out of the pressing action part (A601) when moving to a certain position.

6. The cutting system of intelligent carton cutting machine according to claim 1, characterized in that: the traction mechanism comprises a traction cylinder (B2) and a contact pin (B3), the traction cylinder (B2) drives the contact pin (B3) to be connected with or separated from a traction hole (A11) on the longitudinal cutting assembly (A), so that the transverse moving positioning assembly (B) is connected with or separated from the longitudinal cutting assembly (A), and the transverse moving positioning assembly (B) in a connection state pulls the longitudinal cutting assembly (A) to move transversely.

7. The cutting system of intelligent carton cutting machine according to claim 1, characterized in that: the first transverse moving power assembly comprises a first transverse moving track (B4) for driving a second transplanting bracket (B1) to move transversely; the second transplanting bracket (B1) is provided with a transmission assembly used for connecting a first transverse moving track (B4); the transmission assembly comprises a transmission movable block (B6) and a transmission fixed block (B5); the transmission movable block (B6) can be movably adjusted relative to the second transplanting bracket (B1), and the first transverse moving track (B4) is clamped between the transmission movable block (B6) and the transmission fixed block (B5).

8. The cutting system of intelligent carton cutting machine according to claim 1, characterized in that: a stroke sensor (D4) is arranged on the cutting rack (D); the second transplanting support (B1) is provided with a sensing block (B8), when the second transplanting support (B1) moves to a set position relative to the cutting rack (D), the stroke sensor (D4) corresponds to the sensing block (B8), and the transverse moving positioning assembly (B) stops moving.

9. The cutting system of intelligent carton cutting machine according to claim 1, characterized in that: the transverse cutting mechanism (C) comprises a third transplanting bracket (C1) which transversely moves on the cutting rack (D), a transverse indentation roller (C6) for finishing transverse indentation work and a transverse cutter (C11) for finishing transverse cutting work, wherein the transverse indentation roller (C6) and the transverse cutter (C11) are respectively and transversely and rotatably arranged; a transverse indentation power cylinder (C4) used for controlling the action or non-action of the transverse indentation roller (C6) on the paperboard is arranged between the third transplanting bracket (C1) and the transverse indentation roller (C6); a transverse cutting power cylinder (C10) used for controlling the transverse cutter (C11) to act or not act on the paperboard is arranged between the third transplanting bracket (C1) and the transverse cutter (C11); a second transverse moving power assembly for driving the third transplanting bracket (C1) to transversely move is arranged between the third transplanting bracket (C1) and the cutting frame (D).

10. The cutting system of the intelligent carton cutter of claim 9, characterized in that: a positioning assembly consisting of a positioning conical head (C9), a positioning cylinder (C2) and a positioning sensor (C8) is arranged on the third transplanting bracket (C1); a cylinder body of the positioning cylinder (C2) and a positioning sensor (C8) are respectively and fixedly arranged on the third transplanting bracket (C1), and a piston rod of the positioning cylinder (C2) is connected with a positioning conical head (C9); the longitudinal cutting assembly (A) is provided with a sensing component (A15) with a positioning hole (A1501); when the transverse cutting mechanism (C) moves transversely to a position sensor (C8) to correspond to the sensing component (A15), the positioning cylinder (C2) drives the positioning conical head (C9) to be inserted into the positioning hole (A1501), so that the transverse cutting mechanism (C) is positioned.

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