CN114701247A - Stripe pattern multicolor printing device for elliptical printing machine - Google Patents

Abstract

The invention belongs to the technical field of elliptical printing machines, and particularly relates to a stripe pattern multicolor printing device for an elliptical printing machine. This ellipse is stripe pattern polychrome stamp device for calico printing machine includes: the printing moving seat is suitable for sliding on the printing chassis; the distribution track is fixedly connected to the printing moving seat and is provided with a discharge hole; the slurry distribution mechanism comprises a plurality of slurry injection cylinders with different colors, and is suitable for sliding on the distribution track so as to switch the slurry injection cylinders aligned with the discharge holes and send out the slurry with the corresponding colors; the multi-roller coating mechanism is hung on the bottom surface of the distribution track, comprises coating rollers with the same number as the slurry injection cylinders, and is suitable for switching the coating rollers to imprint the slurry with corresponding colors. The device can realize that the printing moving seat moves once, and stripes with various colors can be printed on the surface of the printed object.

Description

Stripe pattern multicolor printing device for elliptical printing machine

Technical Field

The invention belongs to the technical field of elliptical printing machines, and particularly relates to a stripe pattern multicolor printing device for an elliptical printing machine.

Background

The elliptical printing machine is equipment integrating a printing mechanism, a pattern drying mechanism, a sorting mechanism and even a packaging mechanism, and is named because the mechanisms are sequentially arranged on an elliptical conveying belt along the conveying direction. Wherein, the printing mechanism can print color paste on the surfaces of articles such as clothing pieces, ready-made clothes and the like and simultaneously form various patterns. The printing mechanism can be divided into traditional screen printing and emerging digital printing according to the printing principle, the equipment cost and the consumable cost of the digital printing are much higher than those of the screen printing, the digital printing is more suitable for producing high-added-value products with complex patterns, and simpler stripe patterns such as the stripe patterns are more suitable for being obtained by the screen printing.

The silk screen printing is to cover a plate with a gap on a printed object, such as clothes, then pour the colored paste on one end of the plate, then use a scraper to scrape the colored paste towards the other end, and the colored paste is printed on the surface of the clothes when being scraped through the gap area, so as to form a pattern corresponding to the gap. The stripe pattern is a common pattern, and a certain aesthetic feeling can be generated through the thickness and the color of the stripe. When stripes with various colors are required to be printed on the clothes, because only one printing mechanism is provided with one plate at present, in order to prevent various color sizing agents from being mixed together, sizing agents with one color can be placed on the plate, and only one color can be printed in each printing, so that the number of printing mechanisms is required for the number of colors, and the design of stripe patterns, especially the matching of the stripe colors, is limited.

Disclosure of Invention

The invention aims to provide a stripe pattern multicolor printing device for an elliptical printing machine, which can print stripes with various colors by single printing.

Therefore, the invention provides a stripe pattern multicolor printing device for an elliptical printing machine, which comprises: the printing moving seat is suitable for sliding on the printing chassis; the distribution track is fixedly connected to the printing moving seat and is provided with a discharge hole; the slurry distribution mechanism comprises a plurality of slurry injection cylinders with different colors, and is suitable for sliding on the distribution track so as to switch the slurry injection cylinders aligned with the discharge holes and send out the slurry with the corresponding colors; the multi-roller coating mechanism is hung on the bottom surface of the distribution track, comprises coating rollers with the same number as the slurry injection cylinders, and is suitable for switching the coating rollers to imprint the slurry with corresponding colors.

The invention has the advantages that the printing moving seat is provided with the distribution track, the distribution track is provided with the slidable slurry distribution mechanism, the slurry distribution mechanism can switch the slurry injection tube aligned to the discharge hole by sliding on the distribution track when the printing moving seat moves relative to the printing base plate, so that slurry with corresponding color is guided to the surface of a printed object on the printing base plate, and slurry with each color can be printed by corresponding coating rollers in the multi-roller coating mechanism, so that the printing moving seat can move once, and stripes with various colors can be printed on the surface of the printed object.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the prior descriptions will be briefly described below, and it is obvious that the drawings in the following descriptions are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a first schematic view of a stripe pattern multicolor printing device for an elliptical printing machine of the present invention;

FIG. 2 is a schematic structural diagram II of a stripe pattern multicolor printing device for an elliptical printing machine according to the present invention;

FIG. 3 is an exploded view of a stripe pattern multicolor printing apparatus for an elliptical printer of the present invention;

FIG. 4 is an exploded view of a stripe pattern multicolor printing device for an elliptical printer of the present invention;

FIG. 5 is a bottom view of the dispensing track of the present invention;

FIG. 6 is a first cross-sectional view of a stripe pattern multi-color printing device for an elliptical printer according to the present invention;

FIG. 7 is a second cross-sectional view of a stripe pattern multi-color printing device for an elliptical printer according to the present invention;

FIG. 8 is a third cross-sectional view of a stripe pattern multicolor printing apparatus for an elliptical printer of the present invention;

FIG. 9 is a schematic structural diagram III of a stripe pattern multicolor printing device for an elliptical printing machine according to the present invention;

FIG. 10 is a schematic structural view of a distribution plate of the present invention;

FIG. 11 is a control block diagram of a stripe pattern multicolor printing apparatus for an elliptical printing machine of the present invention;

in the figure:

a printing moving seat 110 and a printing base plate 120;

the device comprises a distribution rail 200, a discharge hole 210, a rail body 220, a distribution chute 221, a rail body convex part 222, an upper residual slurry removing slide rail 231, a left upper residual slurry removing slide rail 232, a right upper residual slurry removing slide rail 233, a lower residual slurry removing slide rail 241, a left lower residual slurry removing slide rail 242, a right lower residual slurry removing slide rail 243, a sealing head 250, a waste slurry port 260, a residual slurry collecting through hole 270 and a residual slurry collecting box 280;

the slurry distribution mechanism 300, the slurry injection tube 310, the discharge tube 311, the box body 320, the containing cavity 321, the injection hole 322, the discharge electromagnetic valve 330, the discharge push rod 340, the box body slide bar 350, the distribution slide block 360 and the discharge channel 370;

the multi-roller coating mechanism 400, a lifting push rod 410, an arc-shaped guide rail 420, a switching slide block 430, a vertical rod 440, a switching strip 450, a sleeve 460, a switching push rod 470, a connecting rod 480, a horizontal rotating shaft 491 and a coating roller 492;

a residual slurry removing mechanism 500, a left removing slide rail 510, a left upper residual slurry removing slide bar 520, a left lower residual slurry removing slide bar 530, a right removing slide rail 540, a right lower residual slurry removing slide bar 550, and a right upper residual slurry removing slide bar 560;

the automatic washing and conducting mechanism 600, the suspension 610, the distribution disc 620, the sealing block 630, the rotating motor 640, the conducting channel 650, the conducting channel opening 651, the cleaning box 660, the automatic washing solenoid valve 661, the sealing ring 662, the waste liquid box assembly 670, the waste liquid box 671 and the suction filter nozzle 672;

the slurry is removed from the slide notch 710, the cross bar 720, and the slide rail base 730.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some, but not all embodiments of the present invention. All other embodiments based on the embodiments of the present invention, which can be realized by a person skilled in the art without any inventive step, are within the scope of the present invention.

As shown in fig. 1, the present invention provides a stripe pattern multicolor printing apparatus for an elliptical printing machine, comprising: a printing moving base 110 adapted to slide on the printing base plate 120; a distribution rail 200, which is fixedly connected to the printing moving base 110, is combined with fig. 5, and is provided with a discharge hole 210; the slurry distribution mechanism 300, which is combined with fig. 6, includes several slurry injection cylinders 310 of different colors, which are adapted to slide on the distribution rail 200 to switch the slurry injection cylinders 310 aligned with the discharge holes 210 to discharge the slurry of the corresponding color; the multi-roll coating mechanism 400, which is connected to the bottom surface of the distribution rail 200 in conjunction with fig. 2, includes the same number of coating rolls 492 as the number of the slurry injection tubes 310, and is adapted to switch the coating rolls 492 to imprint the slurry of the corresponding color. Specifically, the printing movable base 110 may be, but is not limited to, a linear guide, and the distribution rail 200 may be fixedly connected to the printing movable base 110 by a cross bar 720.

By arranging the distribution rail 200 on the printing moving seat 110, the slurry distribution mechanism 300 is slidable on the distribution rail 200, and when the printing moving seat 110 moves relative to the printing base plate 120, the slurry distribution mechanism 300 can slide on the distribution rail 200 to switch the slurry injection cylinder 310 aligned with the discharge hole 210, so that the slurry with the corresponding color is delivered to the surface of the printed object on the printing base plate 120, and the slurry with each color can be printed by the corresponding coating roller in the multi-roller coating mechanism 400, so that the printing moving seat 110 can move once, and stripes with multiple colors can be printed on the surface of the printed object.

As shown in fig. 2, a residual slurry removing mechanism 500 is disposed in the distribution track 200, and is adapted to remove slurry stuck in the discharge hole 210 after the slurry distribution mechanism 300 stops delivering the current slurry; the self-washing guide mechanism 600, which is hung on the bottom surface of the distribution track 200, is combined with fig. 6, and includes two non-communicated guide channels 650, which are adapted to guide the slurry discharged from the discharge hole 210 to the surface of the printed object through one guide channel 650, stop the slurry distribution mechanism 300 from conveying the current slurry, and switch another guide channel 650 to guide the next slurry after the residual slurry removal mechanism 500 finishes removing, and wash the guide channel 650 through which the slurry is guided.

As shown in fig. 3, the distribution track 200 may include: a rail body 220; a pair of distribution chutes 221, which are opened on the upper surface of the rail body 220 and form a rail body protrusion 222 between the two distribution chutes 221, as shown in fig. 4; as shown in fig. 3, a discharge hole 210, which is opened on the rail body convex portion 222, combines with fig. 5, and extends to the bottom surface of the rail body 220; as shown in fig. 3, the slurry dispensing mechanism 300 may include: a box body 320, on which a plurality of accommodating cavities 321 are formed, and with reference to fig. 6, the bottom of each accommodating cavity 321 is formed with an injection hole 322; as shown in fig. 6, a slurry injection tube 310 is disposed in each receiving chamber 321, and an outlet pipe 311 of the slurry injection tube 310 extends into a corresponding injection hole 322; a discharge solenoid valve 330 provided on the discharge pipe 311; an outlet push rod 340, which is arranged on each accommodating cavity 321 and is suitable for pushing the corresponding slurry injection cylinder 310; as shown in fig. 3, a pair of box body sliding strips 350, which are disposed at the bottom of the box body 320 and fit with the distribution chute 221, are combined with fig. 4, and the box body sliding strips 350 are higher than the rail body convex part 222 to form a residual slurry removing slide track 231 with the bottom surface of the box body 320; as shown in fig. 4, a distribution slide 360 fixedly connected to the box body 320 and adapted to slide on the distribution chute 221; the dispensing slide 360 may take the form of, but is not limited to, an iron core linear motor; as shown in fig. 4, a left upper residual slurry removing slide 232, which is fitted with the upper residual slurry removing slide 231, is provided with a sealing head 250 at the right end to form a dynamic seal, and is combined with fig. 5, and the right end of the left upper residual slurry removing slide is initially arranged close to the left side of the discharge hole 210; as shown in fig. 4, a right upper residual slurry removing slide 233, which is fitted with the upper residual slurry removing slide 231, and whose left end is provided with a sealing head 250 to form a dynamic seal, in conjunction with fig. 5, and whose left end is initially arranged close to the right side of the discharging hole 210; the sealing head 250 may be, but is not limited to, a hydrogenated nitrile sealing head; the pair of box body sliding strips 350, the discharging hole 210, the left upper residual slurry removing sliding strip 232 and the right upper residual slurry removing sliding strip 233 form a discharging channel 370; as shown in fig. 11, the control module is adapted to control the dispensing slider 360 to drive the cartridge body 320 to slide on the dispensing chute 221, so as to switch the slurry injection tube 310 aligned with the discharging channel 370, and control the corresponding discharging solenoid valve 330 to open and control the corresponding discharging push rod 340 to start, so as to feed the slurry of the corresponding color into the discharging channel 370, and control the discharging push rod 340 to stop, and control the discharging solenoid valve 330 to close, so as to stop feeding the current slurry. The control module may be, but is not limited to being, a PLC module.

As shown in fig. 4 and 9, the self-washing delivery mechanism 600 may include: a suspension 610 fixed to the bottom surface of the rail body 220; a distribution plate 620 rotatably disposed in the suspension 610, referring to fig. 6, and abutting against the sealing blocks 630 on the bottom surface of the rail body 220 on both sides of the discharging passage 370 to form a dynamic seal; the sealing block 630 may be, but is not limited to, a hydrogenated nitrile sealing block; a rotary motor 640 which is arranged on the suspension 610 and is in transmission connection with the distribution plate 620; referring to fig. 10, the sidewall of the distribution plate 620 is opened with two non-communicating conducting channels 650, and the adjacent conducting channel ports 651 are spaced apart, so that only one conducting channel port 651 is aligned with the discharging channel 370; as shown in fig. 6, a cleaning box 660 fixed on the bottom surface of the rail 220 and connected to a self-cleaning solenoid valve 661, wherein a sealing ring 662 is disposed on one side of the opening of the cleaning box 660 to form a dynamic seal with the distribution plate 620; a waste liquid box assembly 670 fixed on the bottom surface of the rail body 220, which includes a waste liquid box 671 with an opening surface facing the distribution plate 620, wherein a sealing ring 662 is disposed on one surface of the waste liquid box 671 to form a dynamic seal with the distribution plate 620 so as to receive waste liquid injected from the cleaning box 660 into any one of the conducting channels 650; the seal 662 may be, but is not limited to, a hydrogenated nitrile seal; the control module is adapted to control the rotating motor 640 to drive the distribution plate 620 to rotate, so that one conducting channel 650 is aligned with the discharging channel 370, and when the slurry distribution mechanism 300 stops delivering the current slurry, and after the residual slurry removing mechanism 500 finishes removing, the rotating motor 640 is controlled to drive the distribution plate 620 to rotate, so that the other conducting channel 650 is aligned with the discharging channel 370, and the self-cleaning solenoid valve 661 is controlled to open, so as to clean the conducting channel 650 conducting the slurry.

As shown in fig. 6, the waste liquid box assembly 670 may include: a waste liquid tank 671; and a suction filter tip 672 which is arranged on the waste liquid box 671 and externally connected with a suction filter device.

As shown in fig. 4, the rail body convex portion 222 is provided with a lower residual slurry removing slide way 241 along the length direction thereof, and the lower residual slurry removing slide way 241 is located right below the upper residual slurry removing slide way 231; a left lower residual slurry removing slide bar 242 which is adapted to the lower residual slurry removing slide way 241, and the right end part of which is provided with a sealing head 250 to form a dynamic seal, and the right end of which is initially arranged close to the left side of the discharge hole 210 in combination with fig. 5; a right lower residual slurry removing slide bar 243 adapted to the lower residual slurry removing slide way 241, the left end of which is provided with a sealing head 250 to form a dynamic seal, with reference to fig. 5, and the left end of which is initially arranged close to the right side of the discharge hole 210; referring to fig. 7, a waste slurry port 260 communicated with a waste liquid box assembly 670 is formed on the bottom surface of the lower residual slurry removing slide 241; as shown in fig. 4, the residual slurry removing mechanism 500 may include: a left cleaning slide rail 510, which is fixedly connected to the printing moving base 110, and is provided with a left upper residual paste cleaning slide bar slider 520 and a left lower residual paste cleaning slide bar slider 530 in a sliding manner with reference to fig. 5; a right cleaning slide rail 540 fixedly connected to the printing moving base 110, and having a right lower residual paste cleaning slide bar slider 550 slidably disposed thereon, in combination with fig. 5; specifically, with reference to fig. 5 and fig. 1, the left clearing sled 510 and the right clearing sled 540 may be fixedly connected to the cross bar 720 through a sled base 730; a right upper residual pulp removing slide bar sliding block 560 is arranged on the distribution chute 221; the left upper residual slurry removing slide bar 520, the left lower residual slurry removing slide bar 530, the right lower residual slurry removing slide bar 550 and the right upper residual slurry removing slide bar 560 may be, but are not limited to, in the form of an iron core linear motor; referring to fig. 7, the control module is adapted to control the upper left slurry removing slider 520 to drive the upper left slurry removing slider 232 to leave the upper residual slurry removing slide 231 and control the upper right slurry removing slider 560 to drive the upper right slurry removing slider 233 to push left after the slurry dispensing mechanism 300 stops delivering the current slurry, to scrape the residual slurry on the upper portion of the discharging channel 370 and push it out of the upper residual slurry removing slide 231, to control the upper left slurry removing slider 520 and the upper right slurry removing slider 560 to reset, wherein the upper right slurry removing slider 233 can push left until it is attached to the upper left slurry removing slider 232 to push the residual slurry into the dispensing chute 221, and to control the lower left slurry removing slider 530 to drive the lower left slurry removing slider 242 to move to the left side of the waste slurry outlet 260, and to control the lower right slurry removing slider 550 to drive the lower right slurry removing slider 550 to push left, scrape the surplus thick liquid of the lower part of the discharging channel 370, and push it into the waste liquid box assembly 670 through the waste thick liquid port 260, control the left lower surplus thick liquid to clear away the slide bar slide block 530, the right lower surplus thick liquid clears away the slide bar slide block 550 and resets.

As shown in fig. 5, the bottom of the rail body 220 may be opened with a lower residual slurry removing slide notch 710, so that the left lower residual slurry removing slide block 530 can drive the left lower residual slurry removing slide 242 to the left side of the discharge hole 210, and the right lower residual slurry removing slide block 550 can drive the right lower residual slurry removing slide 243 to the right side of the discharge hole 210.

As shown in fig. 4 and 9, the distribution chutes 221 are each opened with a residual slurry collecting through hole 270 to receive residual slurry scraped out of the upper portion of the discharging channel 370; the bottom surface of the rail body 220 is provided with a pair of residual slurry collecting boxes 280 to receive residual slurry falling from the residual slurry collecting through-holes 270, respectively.

As shown in fig. 4, the multi-roll coating mechanism 400 may include: a lifting push rod 410 arranged on the bottom surface of the rail body 220; an arc-shaped guide rail 420 fixedly connected to the extending end of the lifting push rod 410 and eccentrically arranged with the distribution plate 620, so that the lowest point of the arc-shaped guide rail 420 is positioned at the right side of the center of the circle of the distribution plate 620; the arc-shaped guide rail 420 is connected with switching sliding blocks 430 with the same color number as the size in a sliding manner, and each switching sliding block 430 is fixedly connected with a vertical rod 440; a plurality of sleeves 460 are arranged on the switching bar 450 and are suitable for being sleeved with the corresponding vertical rods 440; a switching push rod 470, which is hung on the bottom surface of the rail body 220, and the push-out end of which is fixedly connected with the switching bar 450; each switching slide block 430 is connected with a horizontal rotating shaft 491 through a connecting rod 480, and each horizontal rotating shaft 491 is rotatably connected with a coating roller 492; the control module is adapted to control the switching push rod 470 to extend out by a corresponding length, drive the corresponding coating roller 492 to the lowest point of the arc-shaped guide rail 420, and control the lifting push rod 410 to push out, so that the coating roller 492 is attached to the surface of the object to be printed, and the slurry sent out from the guide channel 650 is printed on the surface of the object to be printed.

The working process of the device is as follows: as shown in fig. 1, after the device is started, the printing moving seat 110 starts to move from one end of the printing chassis 120 to the other end; referring to fig. 6, the control module controls the distribution slider 360 to drive the box 320 to slide on the distribution chute 221 to a corresponding position, so that the corresponding slurry injector 310 is aligned with the discharge channel 370, after the alignment, the control module controls the rotating motor 640 to drive the distribution plate 620 to rotate, so that a guide channel 650 is aligned with the discharge channel 370, and then, referring to fig. 4, the control module controls the switching push rod 470 to extend out by a corresponding length, so as to drive the corresponding coating roller 492 to the lowest point of the arc-shaped guide rail 420, and controls the lifting push rod 410 to push out, so as to make the coating roller 492 fit to the surface of the object to be printed, and then, the control module controls the corresponding discharge solenoid valve 330 to open, and controls the corresponding discharge push rod 340 to start, so as to inject the slurry of a corresponding color into the discharge channel 370, and the slurry falls to the surface of the object to be printed through the guide channel 650, and is compacted by the coating roller 492 which rolls over subsequently; according to the length occupied by the stripes with the color, the printing moving seat 110 pauses when moving to the tail end; after the suspension, the control module controls the corresponding discharging push rod 340 to stop and controls the corresponding discharging electromagnetic valve 330 to close, that is, the slurry distribution mechanism 300 stops conveying the current slurry; subsequently, referring to fig. 7, the control module controls the left upper residual slurry removing slide bar 520 to drive the left upper residual slurry removing slide bar 232 to leave the residual slurry removing slide rail 231, controls the right upper residual slurry removing slide bar 560 to drive the right upper residual slurry removing slide bar 233 to push left, scrapes residual slurry on the upper part of the discharge channel 370, pushes the right upper residual slurry removing slide bar 233 to push left until the left upper residual slurry removing slide bar 232 is attached, pushes residual slurry into the distribution chute 221, and then controls the left upper residual slurry removing slide bar 520 and the right upper residual slurry removing slide bar 560 to reset; then, the control module controls the left lower residual slurry removing slide bar 530 to drive the left lower residual slurry removing slide bar 242 to move to the left side of the waste slurry port 260, controls the right lower residual slurry removing slide bar 550 to drive the right lower residual slurry removing slide bar 243 to push left, scrapes residual slurry at the lower part of the discharge channel 370, and pushes the residual slurry into the waste liquid box assembly 670 through the waste slurry port 260, and then controls the left lower residual slurry removing slide bar 530 and the right lower residual slurry removing slide bar 550 to reset, namely the residual slurry removing mechanism 500 finishes removing; then, the control module controls the rotating motor 640 to drive the distribution plate 620 to rotate, so that the other conducting channel 650 is aligned with the discharging channel 370, and controls the self-washing solenoid valve 661 to be opened to wash the conducting channel 650 conducting the slurry; then, the control module controls the distribution slider 360 to drive the cartridge 320 to slide, and in conjunction with fig. 8, another slurry injection tube 310 is aligned with the discharge channel 370, then the control module controls the lifting push rod 410 to retract, and controls the switching push rod 470 to extend by another stroke, so that another coating roller 492 moves to the lowest point of the arc-shaped guide rail 420, and at the same time, the printing moving seat 110 moves to the head end of another color stripe, the control module controls the lifting push rod 410 to push out, so that the coating roller 492 is attached to the surface of the object to be printed, and then the control module controls the corresponding discharge solenoid valve 330 to open, and controls the corresponding discharge push rod 340 to start, and at the same time, the printing moving seat 110 continues to move to the other end, and another color slurry is printed on the surface of the object to be printed as described above, so as to obtain another color stripe; thus, the printing moving base 110 moves from one end of the printing base 120 to the other end once, and stripes of various colors can be printed on the surface of the object to be printed.

In summary, in the multi-color stripe pattern printing device for the elliptical printing machine, the distribution rail is arranged on the printing moving seat, the slurry distribution mechanism is arranged on the distribution rail in a sliding manner, and the slurry distribution mechanism can slide on the distribution rail in the process that the printing moving seat moves relative to the printing base plate to switch the slurry injection cylinder aligned with the discharge hole, so that the slurry with the corresponding color is conveyed to the surface of the printed object on the printing base plate through the self-washing conveying mechanism, and the slurry with each color can be printed by the corresponding coating roller in the multi-roller coating mechanism; after the stripes of one color are stamped, the residual slurry removing mechanism can remove residual slurry at the discharge hole, the self-washing and conveying mechanism can switch another conveying and guiding channel to convey slurry of another color, so that color mixing cannot be caused during conveying and guiding, the self-washing and conveying mechanism can also clean the conveying and guiding channel which is already conveyed and guided with slurry, so that the next switching can be performed, the multi-roller coating mechanism can also switch another coating roller, the slurry of the color is stamped, and color mixing cannot be caused during coating. Therefore, the printing moving seat can move once, and stripes with various colors can be printed on the surface of the object to be printed.

In the embodiments provided in the present application, it should be understood that the disclosed system and apparatus may be implemented in other ways. The above-described embodiments are merely illustrative, and for example, the division of the mechanism is merely a logical division, and there may be other divisions when actually implemented, and for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed.

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, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

In light of the foregoing description of the preferred embodiments of the present invention, it is to be understood that various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (8)

1. The utility model provides a stripe pattern polychrome stamp device for ellipse printing machine which characterized in that includes:

a printing moving seat (110) adapted to slide on the printing chassis (120);

the distribution track (200) is fixedly connected to the printing moving seat (110) and is provided with a discharge hole (210);

the slurry distribution mechanism (300) comprises a plurality of slurry injection cylinders (310) with different colors, and the slurry injection cylinders (310) are suitable for sliding on the distribution track (200) to switch and align with the discharge holes (210) to discharge the slurry with the corresponding colors;

the multi-roller coating mechanism (400) is hung on the bottom surface of the distribution track (200), comprises the same number of coating rollers (492) as the number of the slurry injection cylinders (310), and is suitable for switching the coating rollers (492) to imprint the slurry with the corresponding color.

2. A stripe pattern multicolor printing apparatus according to claim 1,

the residual slurry removing mechanism (500) is arranged in the distribution track (200) and is suitable for removing slurry stuck in the discharge hole (210) after the slurry distribution mechanism (300) stops conveying the current slurry;

the self-washing conveying and guiding mechanism (600) is hung on the bottom surface of the distribution rail (200) and comprises two conveying and guiding channels (650) which are not communicated, the two conveying and guiding channels are suitable for conveying the pulp sent out from the discharge hole (210) to the surface of the printed object through one conveying and guiding channel (650), the conveying of the current pulp is stopped at the pulp distribution mechanism (300), the other conveying and guiding channel (650) is switched to convey the next pulp after the residual pulp removing mechanism (500) finishes removing, and the conveying and guiding channel (650) which conveys the pulp is cleaned.

3. A stripe pattern multicolor printing apparatus according to claim 2,

the distribution track (200) comprises:

a rail body (220);

a pair of distribution chutes (221) which are opened on the upper surface of the rail body (220) and form a rail body convex part (222) between the two distribution chutes (221);

the discharge hole (210) is formed in the rail body convex part (222) and extends to the bottom surface of the rail body (220);

the slurry dispensing mechanism (300) comprises:

the box body (320) is provided with a plurality of accommodating cavities (321), and the bottom of each accommodating cavity (321) is provided with an injection hole (322);

the slurry injection barrels (310) are arranged in the containing cavities (321), and discharge pipes (311) of the slurry injection barrels (310) extend into the corresponding injection holes (322);

a discharge solenoid valve (330) which is provided on the discharge pipe (311);

a discharge push rod (340) arranged on each accommodating cavity (321) and suitable for pushing the corresponding slurry injection cylinder (310);

the box body sliding strips (350) are arranged at the bottom of the box body (320) and are matched with the distribution chute (221), and the box body sliding strips (350) are higher than the rail body convex part (222) so as to form a residual sizing removing slide way (231) by enclosing with the bottom surface of the box body (320);

the distribution sliding block (360) is fixedly connected with the box body (320) and is suitable for sliding on the distribution sliding chute (221);

the left upper residual slurry removing slide bar (232) is matched with the upper residual slurry removing slide way (231), the right end part of the left upper residual slurry removing slide bar is provided with a sealing head (250) to form dynamic sealing, and the right end of the left upper residual slurry removing slide bar is initially arranged close to the left side of the discharge hole (210);

the right upper residual slurry removing slide bar (233) is matched with the upper residual slurry removing slide way (231), the left end part of the right upper residual slurry removing slide bar is provided with a sealing head (250) to form dynamic sealing, and the left end of the right upper residual slurry removing slide bar is initially arranged close to the right side of the discharge hole (210);

the pair of box body sliding strips (350) and the discharge hole (210), the left upper residual slurry removing sliding strip (232) and the right upper residual slurry removing sliding strip (233) form a discharge channel (370);

and the control module is suitable for controlling the distribution slide block (360) to drive the box body (320) to slide on the distribution chute (221) so as to switch the slurry injection cylinder (310) aligned with the discharge channel (370), and controlling the corresponding discharge electromagnetic valve (330) to be opened and the corresponding discharge push rod (340) to be started, so that slurry with the corresponding color is sent to the discharge channel (370), the discharge push rod (340) is controlled to be stopped, and the discharge electromagnetic valve (330) is controlled to be closed so as to stop sending the current slurry.

4. A stripe pattern multicolor printing apparatus according to claim 3,

the self-washing delivery mechanism (600) comprises:

a suspension (610) fixed to the bottom surface of the rail body (220);

a distribution plate (620) which is rotatably arranged in the suspension (610) and is abutted with sealing blocks (630) on the bottom surface of the rail body (220) at two sides of the discharging channel (370) to form dynamic sealing;

a rotating motor (640) which is arranged on the suspension (610) and is in transmission connection with the distribution disk (620);

two non-communicated conducting channels (650) are formed in the side wall of the distribution plate (620), and adjacent conducting channel openings (651) are arranged at intervals;

a cleaning box (660) which is fixedly connected with the bottom surface of the rail body (220) and is communicated with the self-cleaning electromagnetic valve (661), and a sealing ring (662) is arranged on one surface of an opening of the cleaning box (660) so as to form dynamic seal with the distribution plate (620);

the waste liquid box assembly (670) is fixedly connected to the bottom surface of the rail body (220) and comprises a waste liquid box (671) with an opening surface facing the distribution plate (620), and a sealing ring (662) is arranged on one opening surface of the waste liquid box (671) to form dynamic seal with the distribution plate (620) so as to receive waste liquid injected into any one of the transportation and guide channels (650) from the cleaning box (660);

the control module is suitable for controlling the rotating motor (640) to drive the distribution disc (620) to rotate so as to enable one guide channel (650) to be aligned with the discharge channel (370), stop conveying the current slurry at the slurry distribution mechanism (300), and control the rotating motor (640) to drive the distribution disc (620) to rotate so as to enable the other guide channel (650) to be aligned with the discharge channel (370) after the residual slurry cleaning mechanism (500) finishes cleaning, and control the self-cleaning electromagnetic valve (661) to be opened so as to clean the guide channel (650) which is conveyed with the slurry.

5. A stripe pattern multicolor printing apparatus according to claim 4,

the waste box assembly (670) includes:

a waste liquid tank (671);

a suction filter tip (672) disposed on the waste liquid tank (671) to externally attach a suction filter device.

6. A stripe pattern multicolor printing apparatus according to claim 5,

the rail body convex part (222) is provided with a lower residual slurry removing slide way (241) along the length direction, and the lower residual slurry removing slide way (241) is positioned right below the upper residual slurry removing slide way (231);

the left lower residual slurry removing slide bar (242) is matched with the lower residual slurry removing slide way (241), the right end part of the left lower residual slurry removing slide bar is provided with a sealing head (250) to form dynamic sealing, and the right end of the left lower residual slurry removing slide bar is initially arranged close to the left side of the discharge hole (210);

a right lower residual slurry removing slide bar (243) which is matched with the lower residual slurry removing slide way (241), the left end part of the right lower residual slurry removing slide bar is provided with a sealing head (250) to form dynamic sealing, and the left end of the right lower residual slurry removing slide bar is initially arranged close to the right side of the discharge hole (210);

the bottom surface of the lower residual pulp removing slide way (241) is provided with a waste pulp opening (260) communicated with the waste liquid box assembly (670);

the residual slurry removing mechanism (500) comprises:

the left cleaning slide rail (510) is fixedly connected to the printing moving seat (110), and a left upper residual paste cleaning slide bar sliding block (520) and a left lower residual paste cleaning slide bar sliding block (530) are arranged on the left cleaning slide rail in a sliding manner;

a right cleaning slide rail (540) which is fixedly connected on the printing moving seat (110) and is provided with a right lower residual paste cleaning slide bar sliding block (550) in a sliding way;

a right upper residual pulp removing slide bar sliding block (560) is arranged on the distribution chute (221);

the control module is suitable for controlling a left upper residual slurry removing slide bar sliding block (520) to drive a left upper residual slurry removing slide bar (232) to leave an upper residual slurry removing slide way (231) after the slurry distribution mechanism (300) stops conveying the current slurry, controlling a right upper residual slurry removing slide bar sliding block (560) to drive a right upper residual slurry removing slide bar (233) to push left, removing residual slurry on the upper part of the discharge channel (370), pushing the residual slurry out of the upper residual slurry removing slide way (231), controlling a left upper residual slurry removing slide bar sliding block (520) and a right upper residual slurry removing slide bar sliding block (560) to reset, controlling a left lower residual slurry removing slide bar sliding block (530) to drive a left lower residual slurry removing slide bar (242) to move to the left side of the waste slurry opening (260), controlling a right lower residual slurry removing slide bar sliding block (550) to drive a right lower residual slurry removing slide bar sliding block (243) to push left, removing residual slurry on the lower part of the discharge channel (370), and pushing the residual slurry into a waste liquid box (670) through the waste slurry opening (260), and controlling the left lower residual slurry removing slide bar sliding block (530) and the right lower residual slurry removing slide bar sliding block (550) to reset.

7. A stripe pattern multicolor printing apparatus according to claim 6,

the distribution chutes (221) are all provided with residual slurry collecting through holes (270) to receive residual slurry scraped out of the upper part of the discharge channel (370);

the bottom surface of the rail body (220) is provided with a pair of residual slurry collecting boxes (280) for respectively receiving residual slurry falling from the residual slurry collecting through holes (270).

8. A stripe pattern multicolor printing apparatus according to claim 7,

the multi-roll coating mechanism (400) comprises:

a lifting push rod (410) arranged on the bottom surface of the rail body (220);

the arc-shaped guide rail (420) is fixedly connected to the extending end of the lifting push rod (410) and is eccentrically arranged with the distribution disc (620), so that the lowest point of the arc-shaped guide rail (420) is positioned on the right side of the circle center of the distribution disc (620);

the arc-shaped guide rail (420) is connected with switching sliding blocks (430) with the same color number as the size in a sliding manner, and each switching sliding block (430) is fixedly connected with a vertical rod (440);

the switching strip (450) is provided with a plurality of sleeves (460) which are suitable for being sleeved with corresponding vertical rods (440);

the switching push rod (470) is hung on the bottom surface of the rail body (220), and the push-out end of the switching push rod is fixedly connected with the switching strip (450);

each switching slide block (430) is connected with a horizontal rotating shaft (491) through a connecting rod (480), and each horizontal rotating shaft (491) is rotatably connected with a coating roller (492);

the control module is suitable for controlling the switching push rod (470) to extend out by a corresponding length, driving the corresponding coating roller (492) to the lowest point of the arc-shaped guide rail (420), and controlling the lifting push rod (410) to push out, so that the coating roller (492) is attached to the surface of the printed object, and the pulp sent out from the guide channel (650) is printed on the surface of the printed object.

Images