CN111496856B

CN111496856B - Cutting and printing integrated device

Info

Publication number: CN111496856B
Application number: CN202010323304.7A
Authority: CN
Inventors: 刘丽丽; 葛行坤; 陈跃; 管鸿飏; 周文德
Original assignee: Xuzhou University of Technology
Current assignee: Xuzhou University of Technology
Priority date: 2020-04-22
Filing date: 2020-04-22
Publication date: 2021-11-26
Anticipated expiration: 2040-04-22
Also published as: CN111496856A

Abstract

A cutting and printing integrated device comprises a belt conveyor, a cutting mechanism and a printing mechanism; the cutting mechanism comprises a rack B, a conveying unit supported above the bearing surface of the belt conveyor through the rack B, and a cutter unit supported on the upper part of the belt conveyor through a support A; the conveying unit consists of a plurality of dessert guide beams distributed along the width direction of the belt conveyor; the cutter unit comprises a pair of cutter guide beams arranged above the belt conveyor in a spanning mode, a cutter supporting plate arranged between the pair of cutter guide beams, a driving arm arranged between the pair of cutter guide beams and a plurality of cutters fixedly connected below the cutter supporting plate; the printing mechanism comprises a supporting vertical plate, a transverse guide rail, a sliding plate, a food dye box, a guide cross beam, a connecting rod bracket A, a plurality of connecting rod groups, a plurality of seals and a driving motor; an arc-shaped through groove is formed in the middle of the supporting vertical plate; an oblique through groove which is obliquely arranged in a left-high-right direction is formed in the sliding plate. The device can realize the continuous going on of cutting and stamp process.

Description

Cutting and printing integrated device

Technical Field

The invention relates to a cutting and printing integrated device.

Background

In the industrial production process, a long snack bar is usually produced by a compression molding method, then the snack bar is cut into snack blocks with proper size by a cutting device, and finally a special pattern is printed on the snack blocks by a printing device. In the prior art, the cutting and printing processes cannot be performed simultaneously, and generally need to be performed separately, so that not only is the cutting equipment and the printing equipment required to be separately arranged, which leads to the increase of the input cost, but also a larger production space needs to be provided for the separately arranged equipment, and the production cost is further increased. Meanwhile, due to the discontinuity of the cutting and printing processes, an intermediate transfer link exists between the cutting and printing processes, so that the production and processing process of the snacks is slow, and the production efficiency is not high.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides the cutting and printing integrated device, which can realize the continuous operation of cutting and printing processes, improve the processing efficiency of snack production and effectively reduce the production input cost.

In order to achieve the purpose, the invention provides a cutting and printing integrated device, which comprises a belt conveyor, a cutting mechanism and a printing mechanism, wherein the belt conveyor is used for conveying a printing material;

the belt conveyor is supported on the ground through a rack A, and the length direction of the belt conveyor extends along the left-right direction;

the cutting mechanism comprises a rack B, a conveying unit supported above the bearing surface of the belt conveyor through the rack B, and a cutter unit arranged at the upper part of the belt conveyor in a supporting manner through a support A; the conveying unit consists of a plurality of dessert guide beams distributed along the width direction of the belt conveyor, the length directions of the dessert guide beams are consistent with the length direction of the belt conveyor, two ends of the dessert guide beams extend to the outer sides of two ends of the belt conveyor, the lower end faces of the dessert guide beams are flush and level and are in clearance fit with the bearing surface of the belt conveyor, and a strip-shaped conveying channel positioned above the bearing surface of the belt conveyor is formed between every two adjacent dessert guide beams; the cutter unit comprises a pair of cutter guide beams arranged above the belt conveyor in a spanning mode, a cutter supporting plate arranged between the pair of cutter guide beams, a driving arm arranged between the pair of cutter guide beams and a plurality of cutters fixedly connected below the cutter supporting plate, wherein the pair of cutter guide beams are arranged perpendicular to the length direction of the belt conveyor and are arranged at intervals along the length direction of the belt conveyor; a pair of cutter guide grooves are formed in the opposite sides of the pair of cutter guide beams; the cutter supporting plate is arranged perpendicular to the cutter guide beam, and two ends of the cutter supporting plate are arranged in the pair of cutter guide grooves in a sliding manner; the lower ends of the cutters are arranged in parallel and level and are in clearance fit with the bearing surface of the belt conveyor; the positions of the plurality of dessert guide beams corresponding to the plurality of cutters are provided with through notches in the front-back direction; the driving arm is horizontally supported through a support B arranged on the front side of the belt conveyor, the length direction of the driving arm is vertical to the length direction of the belt conveyor, and one end of the driving arm, which is far away from the support B, is connected with the middle part of the cutter supporting plate; the driving arm is a linear electric push rod and is used for controlling the cutter to pass through the notches on the plurality of dessert guiding beams in a reciprocating manner through stretching;

the printing mechanism comprises a supporting vertical plate, a transverse guide rail, a sliding plate, a food dye box, a guide cross beam, a connecting rod bracket A, a plurality of connecting rod groups, a plurality of seals and a driving motor;

the supporting vertical plate is fixedly connected to the front side of the belt conveyor, an arc through groove is formed in the middle of the supporting vertical plate, the arc top of the arc through groove is located at the center of the supporting vertical plate, and the two arc bottoms of the arc through groove are arranged in a parallel and level mode; the pair of transverse guide rails are longitudinally and fixedly connected to the rear side face of the supporting vertical plate at intervals, are positioned on the upper side and the lower side of the arc-shaped through groove, form a transverse sliding groove between the pair of transverse guide rails, and are positioned above the belt conveyor; the size of the sliding chute is matched with that of the transverse sliding chute, and the sliding chute is transversely and slidably arranged in the transverse sliding chute; an oblique through groove which is obliquely arranged in a left-high-right direction is formed in the sliding plate corresponding to the arc-shaped through groove, and the top end and the bottom end of the oblique through groove are respectively flush with the arc top and the arc bottom of the arc-shaped through groove; the front end of the food dye box is fixedly connected to the rear side face of the supporting vertical plate and extends above the plurality of dessert guide beams; the front end of the guide cross beam sequentially penetrates through the oblique through groove and the arc-shaped through groove and is respectively in sliding fit with the oblique through groove and the arc-shaped through groove; the connecting rod bracket A is arranged at the rear side of the sliding plate, and the center of the front end of the connecting rod bracket A is fixedly connected with the rear end of the guide cross beam; the connecting rod groups are arranged corresponding to the strip-shaped conveying channels, each connecting rod group consists of a plurality of connecting rods which are uniformly distributed along the length direction of the belt conveyor, and the lower ends of the connecting rods are level and are connected with stamps; the driving motor is fixedly installed on the front side of the belt conveyor and located on the left side of the supporting vertical plate, an output shaft of the driving motor is vertically and fixedly connected with one end of the crank, the other end of the crank is hinged with one end of the rocker, and the other end of the rocker is hinged with the left end of the sliding plate.

Preferably, the number of the snack guide beams is three, and the number of the link groups is two.

Preferably, the longitudinal cross-section of the opposite side of the adjacent snack guide beam is dovetail shaped.

In order to improve the printing efficiency, each linkage group comprises three connecting rods.

Preferably, the cutter and the notch are obliquely arranged in a left-high-right manner, and the inclination angle is 45 degrees.

According to the invention, a plurality of snack guide beams are arranged above the belt conveyor, and a strip-shaped conveying channel is formed between the adjacent snack guide beams, so that the snack long strips molded by the pressing die can be conveniently placed on a person and conveyed towards the printing mechanism and the cutting mechanism under the action of the belt conveyor; set up the arc and lead to the groove on the support riser among the stamp mechanism, and set up the slant on the slide and lead to the groove, thus, drive the rocker through the crank and drive the slide reciprocating sliding in horizontal spout, thus, can make the direction crossbeam that transversely wears to establish in the groove is led to the slant and the arc leads to the groove and is reciprocating motion along the length direction that the arc leads to the groove, when the arc end that the arc leads to the groove right-hand member is reachd to the direction crossbeam, the seal of connecting rod lower extreme just can reachd in the food dye box, and dip in of edible dyestuff, when the arc end that the arc leads to the groove left end is reachd to the direction crossbeam, the seal of connecting rod lower extreme just can reachd the rectangular upper surface of correspondence at bar conveying channel interior point heart, so that carry out quick stamp operation. This process is realized by controlling the operation of the drive motor. Belt conveyor adopts step motor drive, and the snack rectangular of through the stamp operation continues to remove to cutting mechanism direction under belt conveyor's effect, through the reciprocal flexible operation of control sharp electric putter, can be in order to drive cutter backup pad at the back to the up reciprocating motion, and then can be with being located the cutting of the snack rectangular of a plurality of bar conveying passageway in batches into the piece of snack. The device can realize the continuous operation of cutting and stamp process, has the machining efficiency who improves the dessert production, and can effectively reduce the cost of production input.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural diagram of a medium printing mechanism of the present invention.

In the figure: 1. band conveyer, 2, cutting mechanism, 3, stamp mechanism, 4, frame B,5, support A, 6, dessert guide beam, 7, bar conveying channel, 8, cutter guide beam, 9, cutter backup pad, 10, actuating arm, 11, cutter, 12, cutter guiding way, 13, incision, 14, support B, 15, support riser, 16, transverse guide, 17, slide, 18, food dye box, 19, guide crossbeam, 20, connecting rod support A, 21, connecting rod, 22, seal, 23, driving motor, 24, arc logical groove, 25, transverse sliding groove, 26, slant logical groove, 27, crank, 28, rocker.

Detailed Description

The present invention is further described below.

As shown in fig. 1 and 2, a cutting and printing integrated device comprises a belt conveyor 1, a cutting mechanism 2 and a printing mechanism 3;

the belt conveyor 1 is supported on the ground through a frame A, and the length direction of the belt conveyor extends along the left-right direction;

the cutting mechanism 2 comprises a rack B4, a conveying unit supported above the bearing surface of the belt conveyor 1 through a rack B4, and a cutter unit supported on the upper part of the belt conveyor 1 through a support A5; the conveying unit consists of a plurality of dessert guide beams 6 distributed along the width direction of the belt conveyor 1, the length direction of each dessert guide beam 6 is consistent with the length direction of the belt conveyor 1, two ends of each dessert guide beam extend to the outer sides of two ends of the belt conveyor 1, the lower end faces of the dessert guide beams 6 are flush with each other and are in clearance fit with the bearing surface of the belt conveyor 1, and a strip-shaped conveying channel 7 positioned above the bearing surface of the belt conveyor 1 is formed between every two adjacent dessert guide beams 6; the cutter unit comprises a pair of cutter guide beams 8 arranged above the belt conveyor 1 in a spanning mode, a cutter support plate 9 arranged between the pair of cutter guide beams 8, a driving arm 10 arranged between the pair of cutter guide beams 8 and a plurality of cutters 11 fixedly connected below the cutter support plate 9, and the pair of cutter guide beams 8 are arranged perpendicular to the length direction of the belt conveyor 1 and are arranged at intervals along the length direction of the belt conveyor 1; a pair of cutter guide grooves 12 are formed in the opposite sides of the pair of cutter guide beams 8; the cutter supporting plate 9 is arranged perpendicular to the cutter guiding beam 8, and two ends of the cutter supporting plate are arranged in the pair of cutter guiding grooves 12 in a sliding manner; the lower ends of the cutters 11 are arranged in parallel and level and are in clearance fit with the bearing surface of the belt conveyor 1; the positions of the plurality of dessert guiding beams 6 corresponding to the plurality of cutters 11 are provided with through notches 13 in the front-back direction; the driving arm 10 is horizontally supported through a bracket B14 arranged at the front side of the belt conveyor 1, the length direction of the driving arm is vertical to the length direction of the belt conveyor 1, and one end of the driving arm far away from the bracket B14 is connected with the middle part of the cutter supporting plate 9; the driving arm 10 is a linear electric push rod and is used for controlling the cutter 11 to pass through the notches 13 on the plurality of dessert guiding beams 6 in a reciprocating manner through stretching;

the printing mechanism comprises a supporting vertical plate 15, a transverse guide rail 16, a sliding plate 17, a food dye box 18, a guide beam 19, a connecting rod support A20, a plurality of connecting rod groups, a plurality of stamps 22 and a driving motor 23;

the supporting vertical plate 15 is fixedly connected to the front side of the belt conveyor, an arc through groove 24 is formed in the middle of the supporting vertical plate 15, the arc top of the arc through groove 24 is located at the center of the supporting vertical plate 15, and the two arc bottoms of the arc through groove 24 are arranged in a flush manner; the pair of transverse guide rails 16 are horizontally arranged, are longitudinally and fixedly connected to the rear side face of the supporting vertical plate 15 at intervals, are positioned on the upper side and the lower side of the arc-shaped through groove 24, form a transverse sliding groove 25 between the pair of transverse guide rails 16, and are positioned above the belt conveyor 1; the size of the sliding plate 17 is matched with that of the transverse sliding groove 25, and the sliding plate is transversely and slidably arranged in the transverse sliding groove 25; an oblique through groove 26 which is obliquely arranged in a left-high-right direction is formed in the sliding plate 17 corresponding to the arc-shaped through groove 24, and the top end and the bottom end of the oblique through groove 26 are respectively flush with the arc top and the arc bottom of the arc-shaped through groove 24; the front end of the food dye box 18 is fixedly connected to the rear side surface of the supporting vertical plate 15 and extends to the upper part of the plurality of dessert guiding beams 6; the front end of the guide beam 19 sequentially passes through the inclined through groove 26 and the arc-shaped through groove 24 and is respectively in sliding fit with the inclined through groove 26 and the arc-shaped through groove 24; preferably, the guide beam 19 is fixedly sleeved with a front limit ring at the front side of the supporting vertical plate 15, and fixedly sleeved with a rear limit ring at the rear side of the sliding plate 17, and the front limit ring and the rear limit ring are respectively in sliding fit with the front side surface of the supporting vertical plate 15 and the rear side surface of the sliding plate 17 to limit the displacement of the guide beam 19 in the front-rear direction; the connecting rod bracket A20 is arranged at the rear side of the sliding plate 17, and the center of the front end of the connecting rod bracket A20 is fixedly connected with the rear end of the guide cross beam 19; the plurality of connecting rod groups are arranged corresponding to the plurality of strip-shaped conveying channels 7, each connecting rod group consists of a plurality of connecting rods 21 which are uniformly distributed along the length direction of the belt conveyor, the lower ends of the plurality of connecting rods 21 are level and level, and the connecting rods are connected with stamps 22; the area where the plurality of stamps 22 are located is smaller than the area inside the food dye box 18 so as to ensure that the dipping of the dye can be carried out; preferably, the upper end of the stamp 22 is provided with a threaded hole, the external size of the lower end of the connecting rod 21 is matched with the size of the threaded hole, and the connecting rod 21 is provided with an external thread structure, and the lower end of the connecting rod 21 is connected to the upper end of the stamp 22 in a threaded fit manner, so that the replacement of stamps with different printed patterns can be conveniently realized, and the types of the printed patterns can be effectively increased; the driving motor 23 is fixedly installed at the front side of the belt conveyor 1 and located at the left side of the supporting vertical plate 15, an output shaft of the driving motor is vertically and fixedly connected with one end of a crank 27, the other end of the crank 27 is hinged with one end of a rocker 28, and the other end of the rocker 28 is hinged with the left end of the sliding plate 17.

Preferably, the number of the snack guide beams 6 is three, and the number of the link groups is two.

Preferably, the longitudinal section of the opposite side of the adjacent snack guide beams 6 is dovetail shaped.

Further, in order to improve the printing efficiency, three links 21 are included in each linkage.

Preferably, the cutting knife 11 and the notch 13 are arranged in a manner of inclining left and right, and the inclination angle is 45 degrees.

A plurality of snack guide beams are arranged above the belt conveyor, and a strip-shaped conveying channel is formed between the adjacent snack guide beams, so that the snack long strips molded by the pressing die can be conveniently placed on people and conveyed towards the printing mechanism and the cutting mechanism under the action of the belt conveyor; set up the arc and lead to the groove on the support riser among the stamp mechanism, and set up the slant on the slide and lead to the groove, thus, drive the rocker through the crank and drive the slide reciprocating sliding in horizontal spout, thus, can make the direction crossbeam that transversely wears to establish in the groove is led to the slant and the arc leads to the groove and is reciprocating motion along the length direction that the arc leads to the groove, when the arc end that the arc leads to the groove right-hand member is reachd to the direction crossbeam, the seal of connecting rod lower extreme just can reachd in the food dye box, and dip in of edible dyestuff, when the arc end that the arc leads to the groove left end is reachd to the direction crossbeam, the seal of connecting rod lower extreme just can reachd the rectangular upper surface of correspondence at bar conveying channel interior point heart, so that carry out quick stamp operation. This process is realized by controlling the operation of the drive motor. Belt conveyor adopts step motor drive, and the snack rectangular of through the stamp operation continues to remove to cutting mechanism direction under belt conveyor's effect, through the reciprocal flexible operation of control sharp electric putter, can be in order to drive cutter backup pad at the back to the up reciprocating motion, and then can be with being located the cutting of the snack rectangular of a plurality of bar conveying passageway in batches into the piece of snack. The device can realize the continuous operation of cutting and stamp process, has the machining efficiency who improves the dessert production, and can effectively reduce the cost of production input.

Claims

1. A cutting and printing integrated device comprises a belt conveyor (1), a cutting mechanism (2) and a printing mechanism (3), and is characterized in that;

the belt conveyor (1) is supported on the ground through a rack A, and the length direction of the belt conveyor extends along the left-right direction;

the cutting mechanism (2) comprises a rack B (4), a conveying unit supported above the bearing surface of the belt conveyor (1) through the rack B (4), and a cutter unit arranged on the upper part of the belt conveyor (1) in a supporting mode through a support A (5); the conveying unit consists of a plurality of dessert guide beams (6) distributed along the width direction of the belt conveyor (1), the length directions of the dessert guide beams (6) are consistent with the length direction of the belt conveyor (1), the two ends of the dessert guide beams extend to the outer sides of the two ends of the belt conveyor (1), the lower end faces of the dessert guide beams (6) are flush with each other and are in clearance fit with the bearing surface of the belt conveyor (1), and a strip-shaped conveying channel (7) located above the bearing surface of the belt conveyor (1) is formed between every two adjacent dessert guide beams (6); the cutter unit comprises a pair of cutter guide beams (8) arranged above the belt conveyor (1) in a crossing mode, a cutter support plate (9) arranged between the pair of cutter guide beams (8), a driving arm (10) arranged between the pair of cutter guide beams (8) and a plurality of cutters (11) fixedly connected below the cutter support plate (9), and the pair of cutter guide beams (8) are arranged perpendicular to the length direction of the belt conveyor (1) and are arranged at intervals along the length direction of the belt conveyor (1); a pair of cutter guide grooves (12) are formed in the opposite sides of the pair of cutter guide beams (8); the cutter supporting plate (9) is arranged perpendicular to the cutter guide beam (8), and two ends of the cutter supporting plate are arranged in the pair of cutter guide grooves (12) in a sliding manner; the lower ends of the cutters (11) are arranged in parallel and are in clearance fit with the bearing surface of the belt conveyor (1); the positions of the plurality of dessert guiding beams (6) corresponding to the plurality of cutters (11) are provided with through notches (13) in the front-back direction; the driving arm (10) is horizontally supported through a support B (14) arranged on the front side of the belt conveyor (1), the length direction of the driving arm is perpendicular to the length direction of the belt conveyor (1), and one end, far away from the support B (14), of the driving arm is connected with the middle part of the cutter supporting plate (9); the driving arm (10) is a linear electric push rod and is used for controlling the cutter (11) to pass through the notches (13) on the plurality of dessert guiding beams (6) in a reciprocating manner through expansion and contraction;

the printing mechanism (3) comprises a supporting vertical plate (15), a transverse guide rail (16), a sliding plate (17), a food dye box (18), a guide cross beam (19), a connecting rod bracket A (20), a plurality of connecting rod groups, a plurality of stamps (22) and a driving motor (23);

the supporting vertical plate (15) is fixedly connected to the front side of the belt conveyor (1), an arc through groove (24) is formed in the middle of the supporting vertical plate (15), the arc top of the arc through groove (24) is located at the center of the supporting vertical plate (15), and the two arc bottoms of the arc through groove (24) are arranged in a flush manner; the pair of transverse guide rails (16) are longitudinally and fixedly connected to the rear side face of the supporting vertical plate (15) at intervals and are positioned on the upper side and the lower side of the arc-shaped through groove (24), a transverse sliding groove (25) is formed between the pair of transverse guide rails (16), and the transverse sliding groove (25) is positioned above the belt conveyor (1); the size of the sliding plate (17) is matched with that of the transverse sliding chute (25) and is transversely and slidably arranged in the transverse sliding chute (25); an oblique through groove (26) which is obliquely arranged in a left-high-right direction is formed in the sliding plate (17) corresponding to the arc through groove (24), and the top end and the bottom end of the oblique through groove (26) are respectively flush with the arc top and the arc bottom of the arc through groove (24); the front end of the food dye box (18) is fixedly connected to the rear side surface of the supporting vertical plate (15) and extends above the plurality of dessert guiding beams (6); the front end of the guide beam (19) sequentially penetrates through the inclined through groove (26) and the arc-shaped through groove (24) and is respectively in sliding fit with the inclined through groove (26) and the arc-shaped through groove (24); the connecting rod support A (20) is arranged on the rear side of the sliding plate (17), and the center of the front end of the connecting rod support A is fixedly connected with the rear end of the guide cross beam (19); the connecting rod groups are arranged corresponding to the strip-shaped conveying channels (7), each connecting rod group is composed of a plurality of connecting rods (21) which are uniformly distributed along the length direction of the belt conveyor (1), the lower ends of the connecting rods (21) are level, and the connecting rods (21) are connected with stamps (22); the driving motor (23) is fixedly installed on the front side of the belt conveyor (1) and located on the left side of the supporting vertical plate (15), an output shaft of the driving motor is vertically and fixedly connected with one end of a crank (27), the other end of the crank (27) is hinged with one end of a rocker (28), and the other end of the rocker (28) is hinged with the left end of the sliding plate (17).

2. A cutting and printing integrated device according to claim 1, characterized in that the number of said snack guide beams (6) is three and the number of said linkages is two.

3. A cutting and embossing integrated device according to claim 1 or 2, characterized in that the longitudinal section of the opposite side of the adjacent snack guide beams (6) is dovetail-shaped.

4. A cutting and printing integrated device according to claim 3, characterized in that each linkage comprises three links (21).

5. A cutting and printing integrated device according to claim 4, wherein the cutting knife (11) and the cut (13) are arranged in a manner of inclining from high to low in the left and the right, and the inclination angle is 45 degrees.