CN111890454A - High-grade packing of comprehensive ization aassessment test production line - Google Patents

Abstract

The invention discloses a comprehensive high-grade packaging evaluation test production line which comprises a feeding system, a cutting system, a printing system and an evaluation system which are sequentially connected, wherein the cutting system comprises a cutting chamber and a roller conveying mechanism, the roller conveying mechanism comprises a first roller and a second roller which are vertically arranged, a feeding hole connected with the feeding system is formed in the cutting chamber, and a feeding mechanism positioned between the feeding hole and the first roller is arranged in the cutting chamber; a blanking mechanism is arranged in the cutting chamber, a blanking avoiding opening is arranged on the first roller machine, a material receiving mechanism is arranged between the first roller machine and the second roller machine, the output end of the second roller machine is connected with a printing system, and a material arranging mechanism for arranging materials is arranged on the second roller machine. According to the invention, through the optimized design in the cutting systems among the evaluation systems, not only is the cutting function realized, but also the molding materials are timely and orderly cut, so that the accuracy of subsequent machine vision evaluation is improved.

Description

High-grade packing of comprehensive ization aassessment test production line

Technical Field

The invention relates to the technical field of high-grade packaging of white spirit, in particular to a comprehensive high-grade packaging evaluation and test production line.

Background

The top-grade liquor packaging is characterized in that the top-grade liquor packaging is made of a fiber board and an acrylic board and is supplemented with a fine-package auxiliary material, if the appearance quality of a packaging box or a packaging box does not meet the requirement after leaving a factory, the packaging box or the packaging box is returned basically and is required to be re-packaged, and therefore, the appearance, particularly printed marks and patterns, of the packaging box or the packaging box can be evaluated and tested finally on a production line of the packaging box or the packaging box to see whether the packaging box or the packaging box can reach the factory standard or not. Before, the work of evaluation and test is finished manually by relying on direct observation and combining with experience, but the labor intensity is very high; with the development of machine vision technology, human eyes are gradually replaced to carry out observation and judgment, namely, machine vision is adopted to replace manual work to carry out appearance evaluation and judgment on a production line.

The machine vision judgment mainly adopts an industrial camera to take multiple-point pictures of the package, and the photographed images are taken according to a certain coordinate system and compared with standard images through an algorithm, so that whether the appearance quality reaches the standard or not is judged. This production line mainly comprises feeding shaping module, cut the type module of getting, sign printing module and machine evaluation module, and we find, machine vision judges to rely on very much the fixed point or decide the visual angle and shoot, in case the type material after cutting does not flush the gui ji in the former process especially cuts the process, and can not change the transmission position of type material after the printing nearly, the printing type material position that leads to getting into in the machine vision scope differs, directly influenced machine vision's comparison and judge, can't carry out more accurate aassessment test operation.

Disclosure of Invention

The invention aims to provide a comprehensive high-grade package evaluation test production line, which not only realizes the cutting function by carrying out optimization design in a cutting system among evaluation systems, but also timely and neatly carries out shape material cutting so as to improve the accuracy of subsequent machine vision evaluation.

The embodiment of the invention is realized by the following steps: a comprehensive high-grade packaging evaluation test production line comprises a feeding system, a cutting system, a printing system and an evaluation system which are sequentially connected, wherein the cutting system comprises a cutting chamber and a roller conveying mechanism arranged in the cutting chamber, the roller conveying mechanism comprises a first roller and a second roller which are arranged one above the other, a feeding hole connected with the feeding system is formed in the cutting chamber, and a feeding mechanism located between the feeding hole and the first roller is arranged in the cutting chamber; the blanking mechanism is arranged in the cutting chamber, a blanking avoiding opening is formed in the first rotary machine, the blanking avoiding opening is located under a blanking end of the blanking mechanism, the receiving mechanism is arranged between the first rotary machine and the second rotary machine and used for transmitting the blanked section materials to the second rotary machine, the output end of the second rotary machine is connected with the printing system, the sorting mechanism for sorting the section materials is installed on the second rotary machine, and the sorting mechanism is located on one side, close to the printing system, of the receiving mechanism.

Further, the feeding mechanism comprises a bearing plate and a power assembly, the bearing plate is connected with the top wall of the cutting chamber through a plurality of hanging rods and is hung below the feeding port, a sliding slope plate for discharging is formed on one side of the bearing plate, a sliding chute is processed on the bearing plate, one end of the sliding chute is in contact with the sliding slope plate, the other end of the sliding chute penetrates through the side wall of the bearing plate, a sliding rail is mounted on the lower surface of the bearing plate on one side of the sliding chute, the length direction of the sliding rail is consistent with the length direction of the sliding chute, the power assembly comprises a swinging rod, a sliding block and a rotating rod, the sliding block is in sliding fit with the sliding rail, a material pushing rod is fixed on one side of the sliding block, which is far away from the sliding slope plate, the upper end of the material pushing rod penetrates into the sliding chute, a telescopic material pushing head is arranged at the upper end of the material pushing rod through a spring, a vertical support is fixed, the both ends in bar hole are located the upper and lower both sides of first cylinder machine frame respectively, and the roller of one of them cylinder of first cylinder machine wears out first cylinder machine frame, and the roller end fixed connection is worn out with the roller of cylinder to bull stick one end, and the other end is provided with and penetrates to the bar downthehole and with bar hole sliding fit's sliding pin.

Further, receiving mechanism is including connecing the workbin and connecing a section of thick bamboo soon, connects the workbin to be located the blanking and dodges a mouthful below, and connect the transfer passage of the interior profile modeling material of workbin, transfer passage includes smooth material chamber and hourglass material chamber, smooth material chamber is located hourglass material chamber and blanking and dodges between the mouth, the diapire in smooth material chamber is towards connecing a section of thick bamboo one side downward sloping soon, it connects in one side under in smooth material chamber to leak the material chamber, and the axis in hourglass material chamber is vertical state, connect a section of thick bamboo soon to be located the hourglass material chamber below of connecing the workbin and be used for shifting the profile modeling material to on the second rotary machine.

Further, connect a section of thick bamboo soon and rotationally set up between material case and second cylinder machine, and connect the axis of a section of thick bamboo soon and the axis of cylinder in the second cylinder machine is parallel, be provided with a plurality of silos that connect on the lateral wall of a section of thick bamboo soon, a plurality of silos that connect evenly set up around the axis circumference of a section of thick bamboo soon, and every length direction who connects the silo all is unanimous with the axial of a section of thick bamboo soon, when connect a section of thick bamboo rotatory soon, one of them connect the silo can be used to accept from the type material that leaks the material intracavity and fall, when connect a section of thick bamboo soon to continue rotatory, the type material of accepting can break away from to the second cylinder machine in connecing the silo.

Further, material all in one piece mechanism includes the motor, the motor cabinet, transmission case and two neat boards, the upper surface at second cylinder machine frame one side is installed to the motor cabinet, the upper surface at second cylinder machine frame opposite side is installed to the transmission case, rotationally be provided with the transmission shaft of being connected with the transmission case input on the motor cabinet, the motor is installed on the motor cabinet, and the output of motor passes through shaft coupling and transmission shaft connection, be fixed with the backup pad between motor cabinet and the transmission case, the backup pad is located the top of transmission shaft, two neat boards set up the both ends at the backup pad respectively slidable, and the lower extreme of every neat board is close to the cylinder surface of second cylinder machine, the output of transmission case is installed and is made the neat board that is close to it and make a round trip gliding link gear in the backup pad, be provided with the adjustment mechanism who is used for adjusting another neat board position on the motor cabinet.

Furthermore, the leveling plate comprises an upper cross beam, a lower cross beam and a vertical beam, the upper cross beam is arranged on the supporting plate in a sliding mode, the lower cross beam is located below the transmission shaft, and the vertical beam is fixed between the upper cross beam and the lower cross beam.

Furthermore, the linkage mechanism comprises a rotary table and an eccentric rod, the rotary table is rotatably arranged on the upper surface of the transmission case, the center of the end surface of the rotary table is fixedly connected with the output end of the transmission case, one end of the eccentric connecting rod is hinged to the eccentric position of the upper end surface of the rotary table, and the other end of the eccentric connecting rod is hinged to the upper surface of the leveling plate.

Furthermore, the adjusting mechanism comprises two adjusting screw rods, a support plate is formed on the upper surface of the motor base, the two adjusting screw rods penetrate through the support plate and are rotatably connected with the leveling plate, the two adjusting screw rods are parallel to each other, two adjusting nuts are matched on each adjusting screw rod, and the two adjusting nuts on each adjusting screw rod are respectively positioned on two sides of the support plate.

Furthermore, one side of the material receiving box is fixedly connected with a frame of the first roller machine through a support, two side plates are fixed below the support, a rotary connecting cylinder is rotatably arranged between the two side plates through an inner rotary shaft, an intermittent driving wheel is fixed at one end of the inner rotary shaft of the rotary connecting cylinder, a plurality of radial sliding chutes with the same number as the material receiving grooves are processed on the intermittent driving wheel, the plurality of radial sliding chutes are uniformly distributed along the circumferential direction of the center of the end face of the intermittent driving wheel, a driving shifting wheel is rotatably arranged on one side plate and is positioned at one side of the intermittent driving wheel, a shifting rod is arranged on the outer end face of the driving shifting wheel, and the shifting rod is provided with a shifting pin which can be in sliding fit with the radial sliding chutes, so that the intermittent driving wheel intermittently rotates under the action of the; the center of the outer end face of the driving dial wheel is provided with a driven belt pulley, a driving belt pulley is fixed on the transmission shaft, and a transmission belt is arranged between the driving belt pulley and the driven belt pulley.

Furthermore, an arc avoiding cavity matched with the arc of the outer edge of the driving thumb wheel is formed in the outer edge part of the intermittent driving wheel between the adjacent radial sliding grooves.

The embodiment of the invention has the beneficial effects that:

the evaluation test production line provided by the embodiment of the invention is improved by the cutting system in front of the printing system and the evaluation system, so that the function of automatically discharging the cut section materials can be realized, and the cut section materials can be transferred to the second roller machine and timely and orderly arranged, so that the subsequent printing system can accurately position and print and the evaluation system can accurately take points for comparison, and a more accurate evaluation result and a more superior appearance quality standard can be achieved on the whole production line.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic structural diagram of an evaluation test line according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a trimming system according to an embodiment of the present invention;

FIG. 3 is an enlarged schematic view of FIG. 2 at A;

FIG. 4 is a schematic diagram of an assembly state of a material receiving box and a material arranging mechanism provided by the embodiment of the invention.

Icon: 1-a cutting chamber; 2-a printing system; 3-a first roller machine; 4-a second tumbling machine; 5-evaluating the system; 6-a blanking mechanism; 7-a feed inlet; 8-hanging the rod; 9-a power assembly; 10-bearing plate; 11-a ramp plate; 12-a slide rail; 13-a scaffold; 14-reinforcing ribs; 15-blanking the avoidance opening; 16-an auxiliary flap; 17-a material receiving box; 18-a transfer channel; 19-side plates; 20-a spin-on cartridge; 21-a monolith mechanism; 91-oscillating bar; 92-a slider; 93-a pusher bar; 94-a pushing head; 95-a spring; 96-strip shaped holes; 97-vertical support; 98-rotating rod; 99-a sliding pin; 201-spin-on cartridge sidewall; 202-material receiving groove; 203-intermittent driving wheels; 204-an arc avoidance cavity; 205-radial runners; 206-driving dial wheel; 207-a deflector rod; 208-a deadbolt; 209-driven pulley; 210-a drive belt; 211-a motor; 212-a motor mount; 213-first leveling plate; 214-a support plate; 215-a second leveling plate; 216-a transmission case; 217-carousel; 218-eccentric rod; 219-chute.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings or the orientations or positional relationships that the products of the present invention are conventionally placed in use, and are only used for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

Furthermore, the terms "parallel," "perpendicular," and the like do not require that the components be absolutely parallel or perpendicular, but may be slightly inclined. For example, "parallel" merely means that the directions are more parallel relative to "perpendicular," and does not mean that the structures are necessarily perfectly parallel, but may be slightly tilted.

Furthermore, the terms "horizontal", "vertical", "overhang" and the like do not imply that the components are required to be absolutely horizontal or overhang, but may be slightly inclined. For example, "horizontal" merely means that the direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Examples

Referring to fig. 1, the integrated high-end package evaluation test production line provided by this embodiment includes a feeding system (not shown), a cutting system, a printing system 2 and an evaluation system 5, which are connected in sequence, the feeding system mainly includes various types of conveyors (chain plates, rollers, belt conveyors), each sheet of material after compression molding is sequentially conveyed into the cutting system for shape cutting of a package box (box), the cut material is conveyed into the printing system 2 for marking or image printing, since the printed material is conveyed by the belt conveyors, the position of the material is not changed by a large friction force, the printed material directly enters the evaluation system 5 for evaluation, an image taking mechanism of the evaluation system 5 is arranged between the belt conveyors for point location acquisition of the material and a printing surface thereof, and comparison is performed by a background system, this part is the technology that is mature at present, and therefore, the detailed description is omitted, and the present embodiment mainly uses the trimming system for the improved design.

Referring to fig. 2 to 4, the cutting system includes a cutting chamber 1 and a roller conveying mechanism disposed in the cutting chamber 1, the roller conveying mechanism includes a first roller 3 and a second roller 4 disposed one above the other, and the first roller 3 and the second roller 4 may be formed on the same frame or may be separately disposed. The cutting chamber 1 is provided with a feeding hole 7 connected with a feeding system, and the cutting chamber 1 is internally provided with a feeding mechanism positioned between the feeding hole 7 and the first roller 3. Specifically, feed mechanism is used for sending into every board material in proper order to first cylinder machine 3 on, and it is including accepting board 10 and power component 9, it is the rectangular plate to accept board 10, and the four corners department of accepting board 10 all is connected and hangs in feed inlet 7 below through peg 8 and the roof in cutting chamber 1, and the sheet material passes through feed system and carries to feed inlet department, and the sheet material falls in proper order to accepting on board 10, and four pegs 8 can regard as the gag lever post of sheet material. A landslide plate 11 for discharging is formed on one side of the bearing plate 10, namely, one side of the landslide plate 11 inclines downwards and points to the conveying roller surface of the first roller machine 3, so that timely discharging is facilitated. The middle part of the bearing plate 10 is provided with a chute, one end of the chute penetrates through the upper surface and the lower surface of the bearing plate 10, and the other end of the chute penetrates through the side wall of the bearing plate 10, namely the chute is arranged along the direction from the bearing plate 10 far away from the sliding plate 11 to the sliding plate 11 close to the sliding plate, and the two ends of the chute penetrate through the front side wall and the rear side wall of the bearing plate 10. The lower surface of the bearing plate 10 on one side of the sliding chute is provided with a sliding rail 12, the length direction of the sliding rail 12 is consistent with the length direction of the sliding chute, namely the sliding rail 12 is arranged along the sliding chute direction and is positioned on one side of the sliding chute, and the length of the sliding rail 12 is larger than or equal to the length of the sliding chute, so that the length range of the whole sliding chute can be optimally covered.

In this embodiment, the power assembly includes a swing rod 91, a slider 92 and a rotating rod 98, the slider 92 is in sliding fit with the slide rail 12, a material pushing rod 93 is fixed to one side of the slider 92 away from the ramp plate 11 through a bolt, the upper end of the material pushing rod 93 penetrates into the slide groove, a telescopic material pushing head 94 is arranged at the upper end of the material pushing rod 93 through a spring 95, specifically, a vertical insertion rod is formed at the lower part of the material pushing head 94, an insertion hole matched with the insertion rod is formed at the upper end of the material pushing rod 93, the material pushing head 94 is slidably arranged in the insertion hole of the material pushing rod 93 through the insertion rod, and the spring 95 is fixed between the upper end of the material pushing rod 93 and the material pushing head 94, so that the material pushing head 94 has scalability. A vertical support 97 is fixed on the lower surface of the frame of the first roller machine 3, one end of the swing rod 91 is hinged with the slide block 92, the other end of the swing rod 91 is hinged on the lower part of the vertical support 97, and the whole swing rod 91 can freely swing within a certain range in a vertical plane.

The middle part of the swing rod 91 is provided with a strip-shaped hole 96 arranged along the length direction, and two ends of the strip-shaped hole 96 are respectively positioned at the upper side and the lower side of the frame of the first roller machine 3, namely, the span of the strip-shaped hole 96 covers the height of the upper beam of the frame of the whole first roller machine 3, so that the subsequent rotating rod 98 can be conveniently installed. The roller shaft of one of the rollers of the first roller machine 3 penetrates out of the frame of the first roller machine 3, one end of the rotating rod 98 is fixedly connected with the end part of the penetrating end of the roller shaft of the roller, and the other end of the rotating rod is provided with a sliding pin 99 which penetrates into the strip-shaped hole 96 and is in sliding fit with the strip-shaped hole 96. When the roll shaft of the roller rotates, the rotating rod 98 can be driven to rotate in a vertical plane, so that the oscillating rod 91 swings back and forth under the interaction of the sliding pin 99 and the strip-shaped hole 96, and the sliding block 92 is driven to slide back and forth on the sliding rail 12, so that the material pushing head 94 has the condition of pushing the plate materials. Specifically, when the swing rod 91 swings to the limit position on one side of the landslide plate 11, the pushing head 94 is located on the rear side of the receiving plate 10 at this time, namely, in the initial state, the pushing head 94 in the initial state is higher than the upper surface of the receiving plate 10 by the thickness of the plate, when the swing rod 91 swings towards one side of the landslide plate 11, the pushing head 94 interacts with the rear side of the plate and drives the plate to slide towards one side of the landslide plate 11, when the swing rod 91 swings in place towards one side of the landslide plate 11, the plate slides from the landslide plate 11, the swing rod 91 starts to move backwards, at this time, the pushing head 94 is in a micro-compression state under the pressure of the plate on the upper side, when the pushing head 94 returns to the initial state, the next cycle is started, the pushing is repeated to complete the operation of all the plates, of course, the pushing head 94 is made of a wear-resistant flexible material, and the surface of the plate cannot.

And after the plate smoothly slides onto the first roller machine 3, the section material cutting operation can be carried out, and the section material is cut into a specific state so as to be convenient for forming a box at the back. The cutting chamber 1 is internally provided with a blanking mechanism 6, the blanking mechanism 6 adopts a structural form of a hydraulic blanking machine, the blanking mechanism 6 is positioned above the first roller machine 3 and is used for cutting the plate materials transmitted on the first roller machine 3, and a die head with a specific shape is formed at the blanking end of the blanking mechanism 6 and can be used for cutting the plate materials with the specific shape. Be provided with the blanking on the first cylinder machine 3 and dodge mouthful 15, the blanking dodges mouthful 15 and is located under blanking mechanism 6's the blanking end for dodge the die head so that the type material breaks away from smoothly from first cylinder machine 3, the form accessible that the blanking dodged mouthful 15 is dismantled corresponding cylinder on the first cylinder machine 3 and is formed the space and realize, be provided with receiving mechanism between first cylinder machine 3 and the second cylinder machine 4, receiving mechanism is used for transmitting the type material after the blanking to on the second cylinder machine 4. Specifically, the receiving mechanism comprises a receiving box 17 and a rotary receiving barrel 20, the receiving box 17 is located below the blanking avoiding opening 15, a conveying channel 18 of the molding material is formed in the receiving box 17, the blanking molding material falls into the conveying channel 18 of the receiving box 17, and then the molding material falls out from a discharging end of the conveying channel 18. The spin-on drums 20 are located below the receiving box 17 and are used to transfer the profile in the transfer channel 18 to the second tumbling machine 4, i.e. the spin-on drums 20 are shown to function mainly as a transitional transfer profile. The output end of the second roller machine 4 is connected with the printing system 2, namely the feed inlet of the printing machine, so that the molding materials can smoothly enter the printing machine for printing. The second roller machine 4 is provided with a material arranging mechanism 21 for arranging and shaping the profile materials, and the material arranging mechanism 21 is positioned on one side of the rotary connecting cylinder 20 close to the printing system 2 and used for arranging and shaping the profile materials falling onto the second roller machine 4 so as to facilitate accurate positioning of subsequent equipment and ensure that the whole processing result has higher accuracy.

After the blanking action was accomplished, in order to make the type material can smooth the landing to connect a section of thick bamboo 20 department soon, transfer passage 18 is including smooth material chamber and hourglass material chamber, smooth material chamber is located hourglass material chamber and blanking and dodges between mouthful 15, the workbin 17 department that connects of smooth material chamber roof one side is provided with supplementary board 16 that turns over, supplementary board 16 top of turning over towards 3 output inclines on one side of first tumbling cylinder machine, and the first time and supplementary board 16 interact and make it slope after the type material falls down, the diapire of smooth material chamber connects a section of thick bamboo 20 one side downward sloping soon, and supplementary board 16 that turns over after preliminary slope slides down along the inclined plane in smooth material chamber, leak the material chamber and connect in one side down in smooth material chamber, and the axis in hourglass material chamber is vertical state, and the type material that the slope slides down enters into to leaking the material chamber and under the restriction of hourglass material chamber shape vertical landing to connect a section of thick bamboo 20 department soon. Two side plates 19 are fixed on the lower surface of the platform plate 13, the rotary connecting cylinder 20 is rotatably arranged between the two side plates 19 through an inner rotating shaft, that is, the rotary connecting cylinder 20 is located between the material receiving box 17 and the second roller machine 20, and the central axis of the rotary connecting cylinder 20 is parallel to the central axis of the roller in the second roller machine 4, that is, the central axis of the rotary union barrel 20 is horizontal, the side wall 201 of the rotary union barrel is provided with a plurality of material receiving grooves 202, the plurality of material receiving grooves 202 are uniformly arranged around the central axis of the rotary union barrel 20 in the circumferential direction, and the length direction of each material receiving groove 202 is consistent with the axial direction of the rotary connecting cylinder 20, when the rotary connecting cylinder 20 rotates, a receiving groove 202 is arranged on the material receiving groove and can be used for receiving the molding material which falls vertically from the material leaking cavity, when the rotary connecting cylinder 20 continues to rotate, the received molding materials can be separated from the material receiving groove 202 to the second rotary machine 4, so that the aim of intermittent transition transmission of the rotary connecting cylinder 20 is fulfilled. In addition, the rotation direction of the rotary connecting cylinder 20 is opposite to the transmission direction of the second roller 4, and when the molding material in the material receiving groove 202 contacts the second roller 4 for the first time, the molding material can be smoothly discharged under the interaction force.

The molding material after taking off smoothly is not high at second cylinder machine 4 alignment degree, can influence the positioning accuracy of follow-up equipment, material all in one piece mechanism 21 includes motor 211, motor cabinet 212, transmission case 216 and two neat boards, the upper surface at second cylinder machine 4 frame one side is installed to motor cabinet 212, the upper surface at second cylinder machine 4 frame opposite side is installed to transmission case 216, rotationally be provided with the transmission shaft of being connected with transmission case 216 input through the bearing on the motor cabinet 212, the transmission shaft is the horizontality, motor 211 is installed on motor cabinet 212, and the output of motor 211 passes through the shaft coupling and is connected with the transmission shaft. A support plate 214 is fixed between the motor base 212 and the transmission case 216, and the support plate 214 is located above the transmission shaft and is also in a horizontal state. The two leveling plates, namely the first leveling plate 213 and the second leveling plate 215, are slidably disposed at two ends of the supporting plate 214, and a lower end of each leveling plate is close to a roller surface of the second roller machine 4. In this embodiment, the leveling plate includes an upper beam, a lower beam and a vertical beam, the upper beam is slidably disposed on the support plate 213 in the form of a sliding groove 219 and a sliding protrusion, the lower beam is located below the transmission shaft, and the vertical beam is fixed between the upper beam and the lower beam.

In this embodiment, the purpose of leveling the profile on the second rolling machine 4 is achieved by the mutual back-and-forth approaching motion of the two leveling plates, a linkage mechanism which can make the leveling plate approaching the linkage mechanism, that is, the second leveling plate 215, slide back and forth on the supporting plate 214 is installed at the output end of the transmission case 216, the linkage mechanism comprises a turntable 217 and an eccentric rod 218, the turntable 217 is rotatably arranged on the upper surface of the transmission case 216, the center of the end surface of the turntable 217 is fixedly connected with the output end of the transmission case 216, it should be noted that the transmission case 216 is a gear transmission case, and the purpose of transmission and steering is achieved by the engagement of two bevel gears therein; one end of the eccentric connecting rod 218 is hinged to the eccentric position of the upper end face of the turntable 217, the other end of the eccentric connecting rod is hinged to the upper surface of the upper beam of the second leveling plate 215, and the purpose that the second leveling plate 215 slides back and forth can be achieved by taking the motor 211 as power output. The motor base 212 is provided with an adjusting mechanism for adjusting the position of the other leveling plate, namely the first leveling plate 213, the adjusting mechanism comprises two adjusting screws, a support plate is formed on the upper surface of the motor base 212, the two adjusting screws penetrate through the support plate and are rotatably connected with the first leveling plate 213, the rotatable connection mode can be realized by additionally arranging a bearing, and the movable matching mode of a large hole and a small shaft can also be realized by only adding a limit cap. Two adjusting screw are parallel to each other, and all cooperate two adjusting nut on every adjusting screw, and two adjusting nut on every adjusting screw are located the extension board both sides respectively, can change the initial position of first neat board 213 through the position that changes two adjusting screw to select the operating position of adjusting first neat board 213 according to the size of type material, under the relative first neat board 213 gliding action that makes a round trip of second neat board 215, carry out the alignment respectively to the both sides of type flitch and level and can.

In order to achieve the purpose of saving power and keeping consistency of actions, one side of the material receiving box 17 is fixedly connected with a support leg of a frame of the first roller machine 3 through a support 13, a reinforcing rib 14 is arranged at the fixed connection position, two side plates 19 are fixed below the support 13, a screwing cylinder 20 is rotatably arranged between the two side plates 19 through an inner rotating shaft, an intermittent driving wheel 203 is fixedly sleeved at one end of the screwing cylinder 20, which is connected with one of the side plates 19, of the screwing cylinder, four radial sliding grooves 205 are processed on the intermittent driving wheel 203, the four radial sliding grooves 205 are uniformly distributed along the circumferential direction of the end surface center of the intermittent driving wheel 203, a driving dial wheel 206 is rotatably arranged on the side plate 19 close to the intermittent driving wheel 203, the driving dial wheel 206 is positioned at one side of the intermittent driving wheel 203, and a deflector rod 207 is fixed on the outer end surface of the driving dial wheel 206, namely, the shifting lever 207 and the intermittent transmission wheel 203 are arranged in a staggered manner, and the rotation of the shifting lever 207 does not influence the rotation of the intermittent transmission wheel 203; and a shifting pin 208 which can be in sliding fit with the radial sliding grooves 205 is fixed on the inner side wall of the shifting rod 207, so that the intermittent driving wheel 203 intermittently rotates under the action of the shifting pin 208 and the radial sliding grooves 205, that is, when the driving shifting wheel 206 and the shifting rod 207 rotate anticlockwise, the shifting pin 208 can be embedded into one of the radial sliding grooves 205 and slide in the radial sliding groove 205, and then the intermittent driving wheel 203 is driven to rotate by a certain angle (90 degrees) through the interaction of the driving shifting wheel 206 and the radial sliding grooves 207, and is timely separated after the rotation is finished, and then the shifting rod 207 enters the next circle to circularly rotate and interacts with the other radial sliding groove 205, so that the purpose of driving the intermittent driving wheel 203 to intermittently rotate clockwise is. In addition, an arc avoiding cavity matched with an arc of the outer edge of the driving thumb wheel 206 is formed in the outer edge part of the intermittent driving wheel 203 between the adjacent radial sliding grooves 205, the arc avoiding cavity is designed to have a transmission work function similar to a meshing effect between the driving thumb wheel 206 and the intermittent driving wheel 203, and the rotation is smoother and smoother. The outer end face center of the driving thumb wheel 206 is provided with a driven belt pulley 209, the driven belt pulley 209 is sleeved on a wheel shaft of the driving thumb wheel 206 and rotates synchronously with the driving thumb wheel 206, the driving belt pulley is fixed on the transmission shaft, a transmission belt 210 is arranged between the driving belt pulley and the driven belt pulley, the purpose of outputting the same power in two sections is achieved through the connection of the transmission belt, the cost is saved, and the consistency of action can be kept by attaching a power execution part to the same power action.

The workflow of the evaluation test production line provided by the embodiment is as follows: after the die forming, the plate materials are sequentially conveyed to the feed inlet 7 through the feeding system and slide onto the bearing plate 10, the plate materials sequentially slide onto the first drum machine 3 through the landslide plate 11 under the action of the power assembly, the power assembly has the advantages that the first drum machine 3 is started and then moves, the first drum machine 3 is stopped and then stops, and a large amount of control cost is saved. The plate material conveyed on the first roller machine 3 is punched at the blanking avoidance opening 15, the profile material is transferred to the rotary connecting cylinder 20 from the conveying channel 18 and finally slides onto the second roller machine 4, and the waste material is directly conveyed to other working procedures by the first conveyor 3. The section material is directly conveyed to the printing system 2 after being subjected to edge alignment and arrangement through the aligning mechanism 21, the mark and the pattern are directly conveyed to the image pickup mechanism of the evaluation system 5 by the belt conveyor after being printed to be directly subjected to point location acquisition, and finally whether the mark and the pattern meet the standard of high-grade packaging is judged after comparison.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention. It should be noted that structures or components illustrated in the drawings are not necessarily drawn to scale, and descriptions of well-known components and processing techniques and procedures are omitted to avoid unnecessarily limiting the invention.

Claims (10)

1. A comprehensive high-grade packaging evaluation test production line comprises a feeding system, a cutting system, a printing system and an evaluation system which are sequentially connected, and is characterized in that the cutting system comprises a cutting chamber and a roller conveying mechanism arranged in the cutting chamber, the roller conveying mechanism comprises a first roller and a second roller which are arranged one above the other, a feeding hole connected with the feeding system is formed in the cutting chamber, and a feeding mechanism located between the feeding hole and the first roller is arranged in the cutting chamber; be provided with blanking mechanism in the cutting chamber, it dodges the mouth to be provided with the blanking on the first cylinder machine, the blanking dodges the mouth and is located under blanking mechanism's blanking end, be provided with receiving mechanism between first cylinder machine and the second cylinder machine, receiving mechanism is used for transmitting the type material after the blanking to the second cylinder machine on, the output of second cylinder machine with printing system connects, just install the material all in one piece mechanism of neat type material on the second cylinder machine, material all in one piece mechanism is located receiving mechanism is close to one side of printing system.

2. The integrated high-grade packaging evaluation and test production line according to claim 1, wherein the feeding mechanism comprises a bearing plate and a power assembly, the bearing plate is connected with the top wall of the cutting chamber through a plurality of hanging rods and is suspended below the feeding port, a landslide plate for discharging is formed on one side of the bearing plate, a chute is processed on the bearing plate, one end of the chute is in contact with the landslide plate, the other end of the chute penetrates through the side wall of the bearing plate, a slide rail is mounted on the lower surface of the bearing plate on one side of the chute, the length direction of the slide rail is consistent with the length direction of the chute, the power assembly comprises a swing rod, a slide block and a rotating rod, the slide block is in sliding fit with the slide rail, a material pushing rod is fixed on one side of the slide block, the upper end of the material pushing rod penetrates into the chute, and a telescopic material pushing head is arranged at the upper end, the surface mounting of frame of first cylinder machine has erect the support, pendulum rod one end with the slider is articulated, and the other end articulates in erecting the support lower part, just the middle part processing of pendulum rod has the bar hole of arranging along its length direction, the both ends in bar hole are located the upper and lower both sides of first cylinder machine frame respectively, the roller of one of them cylinder of first cylinder machine wears out first cylinder machine frame, bull stick one end with the roller of cylinder wears out end fixed connection, and the other end is provided with penetrate to the bar is downthehole and with bar hole sliding fit's sliding pin.

3. The integrated high-grade packaging evaluation test production line according to claim 1, wherein the receiving mechanism comprises a receiving box and a rotary connecting cylinder, the receiving box is located below the blanking avoiding opening, a conveying channel for the section material is formed in the receiving box, the conveying channel comprises a sliding cavity and a leaking cavity, the sliding cavity is located between the leaking cavity and the blanking avoiding opening, the bottom wall of the sliding cavity is inclined downwards towards one side of the rotary connecting cylinder, the leaking cavity is connected to the lower side of the sliding cavity, the central axis of the leaking cavity is in a vertical state, and the rotary connecting cylinder is located below the leaking cavity of the receiving box and used for transferring the section material to the second roller machine.

4. The integrated high-grade packaging evaluation test production line according to claim 3, wherein the rotary connecting cylinder is rotatably arranged between the material receiving box and the second roller machine, the central axis of the rotary connecting cylinder is parallel to the central axis of the roller in the second roller machine, a plurality of material receiving grooves are arranged on the side wall of the rotary connecting cylinder, the plurality of material receiving grooves are uniformly arranged in the circumferential direction around the central axis of the rotary connecting cylinder, the length direction of each material receiving groove is consistent with the axial direction of the rotary connecting cylinder, one material receiving groove on the rotary connecting cylinder can be used for receiving the section materials falling from the material leaking cavity when the rotary connecting cylinder rotates, and the received section materials can be separated from the material receiving grooves to the second roller machine when the rotary connecting cylinder continues to rotate.

5. The integrated high-grade package evaluation and test production line according to claim 4, wherein the material-distributing mechanism comprises a motor, a motor seat, a transmission box and two material-distributing plates, the motor seat is mounted on the upper surface of one side of the second roller machine frame, the transmission box is mounted on the upper surface of the other side of the second roller machine frame, a transmission shaft connected with the input end of the transmission box is rotatably arranged on the motor seat, the motor is mounted on the motor seat, the output end of the motor is connected with the transmission shaft through a coupler, a support plate is fixed between the motor seat and the transmission box and positioned above the transmission shaft, the two material-distributing plates are respectively slidably arranged at two ends of the support plate, the lower end of each material-distributing plate is close to the roller surface of the second roller machine, the output end of the transmission box is provided with a linkage mechanism capable of enabling the material-distributing plate close to slide back and forth on the support plate, and the motor base is provided with an adjusting mechanism for adjusting the position of the other trimming plate.

6. The integrated high-grade package evaluation test production line according to claim 5, wherein the leveling plate comprises an upper cross beam, a lower cross beam and a vertical beam, the upper cross beam is slidably arranged on the support plate, the lower cross beam is positioned below the transmission shaft, and the vertical beam is fixed between the upper cross beam and the lower cross beam.

7. The integrated high-grade package evaluation and test production line according to claim 5, wherein the linkage mechanism comprises a rotary disc and an eccentric rod, the rotary disc is rotatably arranged on the upper surface of the transmission case, the center of the end surface of the rotary disc is fixedly connected with the output end of the transmission case, one end of the eccentric rod is hinged at the eccentric position of the upper end surface of the rotary disc, and the other end of the eccentric rod is hinged with the upper surface of the aligning plate.

8. The integrated high-grade packaging evaluation and test production line according to claim 5, wherein the adjusting mechanism comprises two adjusting screws, a support plate is formed on the upper surface of the motor base, the two adjusting screws penetrate through the support plate and are rotatably connected with the leveling plate, the two adjusting screws are parallel to each other, two adjusting nuts are matched on each adjusting screw, and the two adjusting nuts on each adjusting screw are respectively positioned on two sides of the support plate.

9. The integrated high-grade package evaluation test production line according to claim 5, one side of the material receiving box is fixedly connected with the frame of the first roller machine through a bracket, two side plates are fixed below the bracket, the rotary connecting cylinder is rotatably arranged between the two side plates through an inner rotating shaft, one end of the inner rotating shaft of the rotary connecting cylinder is fixed with an intermittent driving wheel, a plurality of radial chutes with the same number as the material receiving chutes are processed on the intermittent driving wheel, the plurality of radial chutes are uniformly distributed along the circumferential direction of the end surface center of the intermittent driving wheel, one side plate is rotatably provided with a driving thumb wheel which is positioned at one side of the intermittent driving wheel, and the outer end face of the driving dial wheel is provided with a dial rod which is provided with a dial pin which can be in sliding fit with the radial sliding groove, the intermittent driving wheel intermittently rotates under the action of the poking pin and the radial sliding groove; the outer end face center of the driving dial wheel is provided with a driven belt pulley, a driving belt pulley is fixed on the transmission shaft, and a transmission belt is arranged between the driving belt pulley and the driven belt pulley.

10. The integrated high-grade package evaluation and test production line according to claim 9, wherein an arc-shaped avoiding cavity matched with an arc of the outer edge of the driving thumb wheel is formed in the outer edge part of the intermittent driving wheel between the adjacent radial chutes.

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