CN112109453A - Digital printing machine - Google Patents

Abstract

The invention relates to the technical field of digital printing, in particular to a digital printing machine, which comprises a printing bearing table component, a bearing connecting and lifting device, a bearing connecting telescopic component, a digital printing component, a bearing linkage component, a printing paper placing table component, a linkage rotating device and an extrusion lifting device, wherein the bearing connecting and lifting device is fixedly connected above the left end of the printing bearing table component, the bearing connecting and lifting device is connected with the bearing connecting telescopic component, the bearing connecting telescopic component is connected with the digital printing component, the printing bearing table component is connected with the bearing linkage component, the printing paper placing table component and the linkage rotating device are respectively provided with four printing paper placing table components, the four printing paper placing table components are uniformly and fixedly connected around the bearing linkage component, and the device can automatically discharge processed products, and the full-automatic production is realized.

Description

Digital printing machine

Technical Field

The invention relates to the technical field of digital printing, in particular to a digital printing machine.

Background

Digital printers are an industry of large format printers, such as plotters, which are similar in the CAD field, and have ink characteristics of aqueous dispersion inks. Is printed on transfer paper and then transferred to cloth (artificial chemical fiber cloth) by high temperature. The method is mainly applied to printing and dyeing of clothing and cloth. Most of the existing digital printing machines can not discharge the processed products, so that the design of the digital printing machine capable of automatically discharging the products is particularly important.

Disclosure of Invention

The invention relates to the technical field of digital printing, in particular to a digital printing machine which comprises a printing bearing table component, a bearing connecting lifting device, a bearing connecting telescopic component, a digital printing component, a bearing linkage component, a printing paper placing table component, a linkage rotating device and an extrusion lifting device.

A digital printing machine comprises a printing bearing table component, a bearing connection lifting device, a bearing connection telescopic component, a digital printing component, a bearing linkage component, a printing paper placing table component, a linkage rotating device and an extrusion lifting device, wherein the upper part of the left end of the printing bearing table component is fixedly connected with the bearing connection lifting device, the bearing connection lifting device is connected with the bearing connection telescopic component, the bearing connection telescopic component is connected with the digital printing component, the printing bearing table component is connected with the bearing linkage component, the printing paper placing table component and the linkage rotating device are respectively provided with four, the four printing paper placing table components are uniformly and fixedly connected around the bearing linkage component, the four linkage rotating devices are uniformly and fixedly connected around the bearing linkage component, and the four linkage rotating devices are respectively meshed with the four printing paper placing table components, the stamp bearing table component is fixedly connected with an extrusion lifting device, and the extrusion lifting device is in contact with one of the four linkage rotating devices.

As a further optimization of the technical scheme, the printing bearing table component of the digital printing machine comprises a bearing transverse plate, inclined supporting legs, a motor I and a bevel gear I, wherein the inclined supporting legs are fixedly connected to the front end and the rear end of the lower portion of the bearing transverse plate, the motor I is fixedly connected to the lower portion of the bearing transverse plate, and the bevel gear I is fixedly connected to an output shaft of the motor I.

As a further optimization of the technical scheme, the bearing connection lifting device of the digital printing machine comprises a bottom fixing plate, a connection sliding cavity and two electric telescopic rods, wherein the bottom fixing plate is fixedly connected above the left end of the bearing transverse plate, the connection sliding cavity is fixedly connected to the bottom fixing plate, and the two electric telescopic rods are respectively and fixedly connected to the front end and the rear end above the bottom fixing plate.

As a further optimization of the technical scheme, the bearing connection telescopic member of the digital printing machine comprises a lifting sliding plate, a linkage top plate, a motor II and a telescopic screw rod, wherein the lifting sliding plate is slidably connected in the connection sliding cavity, the linkage top plate is fixedly connected above the lifting sliding plate, two electric telescopic rods are respectively and fixedly connected to the front end and the rear end below the linkage top plate, the motor II is fixedly connected to the lifting sliding plate, an output shaft of the motor II is rotatably connected with the lifting sliding plate, and the telescopic screw rod is fixedly connected to an output shaft of the motor II.

As a further optimization of the technical scheme, the digital printing component of the digital printing machine comprises a bearing fixing plate, a printing machine head and telescopic sliding columns, wherein the printing machine head is fixedly connected below the bearing fixing plate, the telescopic sliding columns are connected to the front side and the rear side of the left end of the bearing fixing plate in a sliding manner, the two telescopic sliding columns are fixedly connected with a lifting sliding plate, and a telescopic lead screw is connected with the bearing fixing plate through threads.

As a further optimization of the technical scheme, the bearing linkage component of the digital printing machine comprises a shielding fixing plate, a connecting square block, a central rotating shaft and a bevel gear II, wherein the connecting square block is fixedly connected below the shielding fixing plate, the central rotating shaft is fixedly connected below the connecting square block, the central rotating shaft is rotatably connected with the bearing transverse plate, the bevel gear II is fixedly connected below the central rotating shaft, and the bevel gear II is in transmission connection with the bevel gear I.

As a further optimization of the technical scheme, the printing paper placing table component of the digital printing machine comprises a connecting bearing shaft, a connecting rotating cavity, a rotating gear, a fixed column and a placing table top, wherein the connecting bearing shaft is rotatably connected with the connecting rotating cavity, the connecting rotating cavity is fixedly connected with the rotating gear, the connecting rotating cavity is fixedly connected with the fixed column, the placing table top is fixedly connected with the fixed column, the four printing paper placing table components are respectively and fixedly connected to the periphery of the connecting square block.

As a further optimization of the technical scheme, the linkage rotating device of the digital printing machine comprises gear strips, contact curved plates, connecting sliders, fixed square plates, connecting square sliding columns and springs, wherein the contact curved plates are fixedly connected below the gear strips, the connecting sliders are fixedly connected on the gear strips, the connecting square sliding columns are fixedly connected on the fixed square plates, the connecting square sliding columns are slidably connected with the connecting sliders, the connecting square sliding columns are sleeved with the springs, the springs are located above the connecting sliders, the linkage rotating device is provided with four gear strips, the four gear strips are respectively in transmission connection with four rotating gears, the four fixed square plates are respectively and fixedly connected around the connecting squares, the upper portions of the four connecting square sliding columns are all fixedly connected with a shielding fixing plate, and the four springs are all located below the shielding fixing plate.

As a further optimization of the technical scheme, the linkage rotating device of the digital printing machine further comprises limiting curved bars, and the limiting curved bars are fixedly connected above the four gear bars.

As a further optimization of the technical scheme, the extrusion lifting device of the digital printing machine comprises a supporting vertical plate and a contact cylinder, wherein the supporting vertical plate is fixedly connected above the bearing transverse plate, the contact cylinder is fixedly connected to the supporting vertical plate, and one of the four contact curved plates is in contact with the contact cylinder.

The digital printing machine has the beneficial effects that:

utilize motor I's intermittent type to rotate four table surfaces of placing and carry out intermittent type and rotate, at this moment lie in artificial chemical fibre class cloth of placing on the table surface and also can be along with rotating, when one of them place the table surface and transfer to the printing machine head under, the printing machine head can print the pattern on artificial chemical fibre class cloth, at this moment four table surfaces of placing can continue to rotate, treat that next table surface of placing is located the printing machine head under, the printing machine head still can print the pattern on artificial chemical fibre class cloth, when one of them contact bent plate and contact cylinder contact, can drive the gear rack rebound, at this moment can drive through rotating gear and connect the chamber of transferring and rotate, at this moment lie in this moment and place the product on the table surface and can be discharged, the product discharge that finishes processing automatically, realize full automatic production.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

FIG. 1 is a schematic structural diagram of a digital printing machine according to the present invention;

FIG. 2 is a schematic structural view of a printed load-bearing table member;

FIG. 3 is a schematic view of a supporting connection elevator apparatus;

FIG. 4 is a schematic view of a structure of a support link telescoping member;

FIG. 5 is a schematic structural diagram of a digital printing member;

FIG. 6 is a schematic view of a structure of a load linkage member;

FIG. 7 is a schematic view of a structure of a printing paper placing table member;

FIG. 8 is a schematic view of a linkage rotating device;

fig. 9 is a schematic structural view of the extrusion lifting device.

In the figure: a printed load-bearing table member 1; a bearing transverse plate 1-1; an inclined leg 1-2; motor I1-3; bevel gear I1-4; the bearing is connected with a lifting device 2; a bottom fixed plate 2-1; the connecting sliding cavity 2-2; 2-3 of an electric telescopic rod; the support is connected with a telescopic component 3; a lifting sliding plate 3-1; linkage top plate 3-2; motor II 3-3; 3-4 parts of a telescopic lead screw; a digital printing member 4; a bearing fixed plate 4-1; 4-2 of a printing machine head; 4-3 of a telescopic sliding column; a load bearing linkage member 5; a shielding fixing plate 5-1; connecting the square blocks 5-2; 5-3 of a central rotating shaft; bevel gear II 5-4; a printing paper placing table member 6; connecting a bearing shaft 6-1; is connected with the rotary cavity 6-2; 6-3 of a rotating gear; 6-4 of a fixed column; 6-5 of a placing table top; a linkage rotation device 7; a gear rack 7-1; 7-2 of a limiting curved bar; contact curved plate 7-3; connecting a sliding block 7-4; 7-5 of a fixed square plate; connecting a square sliding column 7-6; 7-7 of a spring; an extrusion lifting device 8; a support vertical plate 8-1; contact cylinder 8-2.

Detailed Description

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1-9, the present invention relates to the technical field of digital printing, and more specifically to a digital printing machine, which comprises a printing carrying table member 1, a bearing connecting lifting device 2, a bearing connecting telescopic member 3, a digital printing member 4, a carrying linkage member 5, a printing paper placing table member 6, a linkage rotating device 7 and an extrusion lifting device 8, wherein the intermittent rotation of a motor I1-3 is used to drive four placing table surfaces 6-5 to intermittently rotate, at this time, the artificial chemical fiber cloth on the placing table surfaces 6-5 can also rotate along with the rotation, when one placing table surface 6-5 is transferred to the position right below the printing machine head 4-2, the printing machine head 4-2 can print patterns on the artificial chemical fiber cloth, at this time, the four placing table surfaces 6-5 can continue to rotate, when the next placing table top 6-5 is positioned right below the printing machine head 4-2, the printing machine head 4-2 can print patterns on artificial chemical fiber cloth, when one of the contact bent plates 7-3 is in contact with the contact cylinder 8-2, the gear strip 7-1 is driven to move upwards, the connecting rotating cavity 6-2 can be driven to rotate through the rotating gear 6-3, and then products positioned on the placing table top 6-5 can be discharged, so that the processed products are automatically discharged, and full-automatic production is realized;

a digital printing machine comprises a printing bearing table component 1, a bearing connecting lifting device 2, a bearing connecting telescopic component 3, a digital printing component 4, a bearing linkage component 5, a printing paper placing table component 6, a linkage rotating device 7 and an extrusion lifting device 8, wherein the printing bearing table component 1 plays a role of bearing connection and provides a fixed space for the whole device, an intermittent automatic artificial chemical fiber cloth transferring device is fixedly connected above the right end of the printing bearing table component 1, the artificial chemical fiber cloth can be automatically placed on four printing paper placing table components 6, the bearing connecting lifting device 2 is fixedly connected above the left end of the printing bearing table component 1, the bearing connecting lifting device 2 can be used for adjusting the height of the bearing connecting telescopic component 3, the height of the digital printing component 4 is finally adjusted, the bearing connecting lifting device 2 is connected with the bearing connecting telescopic component 3, the extension length of the digital printing component 4 can be adjusted by utilizing the support to connect the telescopic component 3, the support is connected with the digital printing component 4 on the telescopic component 3, the digital printing component 4 is utilized to print the artificial chemical fiber cloth positioned on the printing paper placing table component 6, the printing bearing table component 1 is connected with the bearing linkage component 5, the bearing linkage component 5 plays a role of bearing connection and provides a fixed space for other parts, the printing paper placing table component 6 and the linkage rotating device 7 are both provided with four, the four printing paper placing table components 6 are uniformly and fixedly connected around the bearing linkage component 5, the artificial chemical fiber cloth can be placed on the four printing paper placing table components 6, the printing paper placing table components 6 can realize automatic rotation, the artificial chemical fiber cloth after printing is unloaded, and the full-automatic production is realized, the four linkage rotating devices 7 are uniformly and fixedly connected around the bearing linkage member 5, the angle of the printing paper placing table-board member 6 is adjusted by utilizing the lifting of the linkage rotating devices 7, when the printing paper placing table-board member 6 inclines, the printed artificial chemical fiber cloth is unloaded, after the artificial chemical fiber cloth is unloaded, the linkage rotating devices 7 can be restored to the original position, the printing paper placing table-board member 6 can be restored to the horizontal state, the next printing is carried out when the next artificial chemical fiber cloth arrives, the four linkage rotating devices 7 are respectively meshed and connected with the four printing paper placing table-board members 6, the extrusion lifting device 8 is fixedly connected on the printing bearing table member 1, when the linkage rotating devices 7 rotate, the linkage rotating devices can be contacted with the extrusion lifting device 8, the extrusion lifting device 8 plays a limiting role, and at the moment, the linkage rotating devices 7 can move upwards, thereby realizing the rotation of the printing paper placing table-board component 6, and the extrusion lifting device 8 is contacted with one of the four linkage rotating devices 7.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-9, and the embodiment further describes the first embodiment, in which the printed supporting table member 1 includes a supporting horizontal plate 1-1, inclined legs 1-2, a motor I1-3 and bevel gears I1-4, the supporting horizontal plate 1-1 plays a role of supporting connection, the front and rear ends below the supporting horizontal plate 1-1 are fixedly connected with the inclined legs 1-2, the inclined legs 1-2 play a role of supporting, and provide a sliding space for the printed artificial chemical fiber cloth, a box can be placed on the inclined legs 1-2 to recycle the printed artificial chemical fiber cloth, the motor I1-3 is fixedly connected below the supporting horizontal plate 1-1, the motor I1-3 only intermittently rotates, and the angle of each rotation is ninety degrees, the motor I1-3 can drive the bevel gear I1-4 to rotate, the output shaft of the motor I1-3 is fixedly connected with the bevel gear I1-4, and the bevel gear I1-4 can drive the bevel gear II5-4 to rotate.

The third concrete implementation mode:

the following describes the embodiment with reference to fig. 1-9, and the embodiment further describes the second embodiment, the bearing connecting lifting device 2 includes a bottom fixing plate 2-1, a connecting sliding cavity 2-2 and an electric telescopic rod 2-3, the bottom fixing plate 2-1 is fixedly connected above the left end of the bearing transverse plate 1-1 by screws, the bottom fixing plate 2-1 plays a role of bearing connection, the bottom fixing plate 2-1 is fixedly connected with the connecting sliding cavity 2-2, the connecting sliding cavity 2-2 can provide a sliding space for the lifting sliding plate 3-1 and limit the sliding plate 3-1, so that the lifting sliding plate 3-1 can only slide up and down, the electric telescopic rods 2-3 are provided with two numbers, and the two electric telescopic rods 2-3 are respectively fixedly connected at the front and rear ends above the bottom fixing plate 2-1, the two electric telescopic rods 2-3 are used for driving the linkage top plate 3-2 to move up and down, so that the height of the printing machine head 4-2 is adjusted, the thickness of the artificial chemical fiber cloth is different, the degree of each expansion of the two electric telescopic rods 2-3 is also different, and the distance of each expansion of the two electric telescopic rods 2-3 is adjusted according to the thickness of the artificial chemical fiber cloth.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1-9, and the third embodiment is further described in the present embodiment, where the support connection telescopic member 3 includes a lifting slide plate 3-1, a linked top plate 3-2, a motor II3-3, and a telescopic screw 3-4, the lifting slide plate 3-1 is slidably connected in the connection slide cavity 2-2, the lifting slide plate 3-1 plays a role of bearing connection, the linked top plate 3-2 is fixedly connected above the lifting slide plate 3-1, the lifting slide plate 3-1 can be driven to lift by using the linked top plate 3-2, two electric telescopic rods 2-3 are respectively fixedly connected at front and rear ends below the linked top plate 3-2, the motor II3-3 is fixedly connected on the lifting slide plate 3-1, and the motor II3-3 can drive the telescopic screw 3-4 to rotate, an output shaft of the motor II3-3 is rotatably connected with the lifting sliding plate 3-1, an output shaft of the motor II3-3 is fixedly connected with a telescopic lead screw 3-4, and the rotary telescopic lead screw 3-4 can drive the bearing fixed plate 4-1 to slide left and right, so that the left and right sliding of the printing machine head 4-2 is realized.

The fifth concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 9, and the digital printing component 4 further described in the fourth embodiment includes a support fixing plate 4-1, a printing head 4-2 and a telescopic sliding column 4-3, the support fixing plate 4-1 can provide a fixed space for the printing head 4-2 and drive the printing head to move, the printing head 4-2 is fixedly connected below the support fixing plate 4-1, the printing head 4-2 is used to print on artificial chemical fiber cloth, the telescopic sliding columns 4-3 are slidably connected to the front and back sides of the left end of the support fixing plate 4-1, the two telescopic sliding columns 4-3 are fixedly connected to the lifting sliding plate 3-1, the telescopic screw 3-4 is connected to the support fixing plate 4-1 through a screw, the two telescopic sliding columns 4-3 can limit the support fixing plate 4-1, the bearing fixing plate 4-1 can only slide left and right but can not rotate.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1-9, and the fifth embodiment is further described in the present embodiment, in which the bearing linkage member 5 includes a shielding fixing plate 5-1, a connecting block 5-2, a central rotating shaft 5-3 and a bevel gear II5-4, the shielding fixing plate 5-1 plays a role of shielding, and can provide a fixed space for four connecting square sliding columns 7-6, the connecting block 5-2 is fixedly connected below the shielding fixing plate 5-1, the connecting block 5-2 can provide a fixed space for other parts, the central rotating shaft 5-3 is fixedly connected below the connecting block 5-2, the central rotating shaft 5-3 can provide a rotating space for the connecting block 5-2, and the central rotating shaft 5-3 is rotatably connected with the bearing transverse plate 1-1, a bevel gear II5-4 is fixedly connected below the central rotating shaft 5-3, the central rotating shaft 5-3 can be driven to rotate by the bevel gear II5-4, and the bevel gear II5-4 is in transmission connection with the bevel gear I1-4.

The seventh embodiment:

the present embodiment is described below with reference to fig. 1 to 9, and the fifth embodiment is further described in the present embodiment, in which the printing paper placing table component 6 includes a connecting bearing shaft 6-1, a connecting rotating cavity 6-2, a rotating gear 6-3, a fixing column 6-4 and a placing table 6-5, the connecting bearing shaft 6-1 can provide a rotating space for the connecting rotating cavity 6-2, the connecting bearing shaft 6-1 is rotatably connected with the connecting rotating cavity 6-2, the connecting rotating cavity 6-2 is used to drive the fixing column 6-4 to rotate, the connecting rotating cavity 6-2 is fixedly connected with the rotating gear 6-3, the rotating gear 6-3 can drive the connecting rotating cavity 6-2 to rotate, the connecting rotating cavity 6-2 is fixedly connected with the fixing column 6-4, and the fixing column 6-4 can provide a fixed space for the placing table 6-5 and drive the placing table 6-5 to rotate The fixed column 6-4 is fixedly connected with a placing table top 6-5, artificial chemical fiber cloth can be placed on the placing table top 6-5, the placing table top 6-5 can rotate to realize the unloading of the processed artificial chemical fiber cloth, the printing paper placing table top component 6 is provided with four connecting bearing shafts 6-1 which are respectively and fixedly connected with the periphery of the connecting square 5-2.

The specific implementation mode is eight:

this embodiment will be described below with reference to fig. 1 to 9, and this embodiment will further describe embodiment six: the linkage rotating device 7 comprises a gear strip 7-1, a contact curved plate 7-3, a connecting slide block 7-4, a fixed square plate 7-5, a connecting square sliding column 7-6 and a spring 7-7, the rotation of the rotating gear 6-3 is realized by utilizing the lifting of the gear strip 7-1, the rotation of the placing table surface 6-5 is finally driven, the automatic discharge of the processed product is realized, the full-automatic production is ensured, the contact curved plate 7-3 is fixedly connected below the gear strip 7-1, the gear strip 7-1 is driven to move upwards by utilizing the rotating contact of the contact curved plate 7-3 and the contact cylindrical column 8-2, the connecting slide block 7-4 is fixedly connected on the gear strip 7-1, and the gear strip 7-1 is limited by utilizing the connecting slide block 7-4, the gear rack 7-1 can only move up and down, the connecting square sliding column 7-6 is fixedly connected to the fixed square plate 7-5, the fixed square plate 7-5 can provide a fixed space for the connecting square sliding column 7-6, the connecting square sliding column 7-6 is utilized, when the connecting square sliding column 7-6 is in sliding connection with the connecting sliding block 7-4, the gear rack 7-1 is limited and can only move up and down, the connecting square sliding column 7-6 is sleeved with the spring 7-7, the spring 7-7 is positioned above the connecting sliding block 7-4, the elastic force generated by the spring 7-7 acts on the connecting sliding block 7-4, the connecting sliding block 7-4 is contacted with the fixed square plate 7-5, the gear rack 7-1 is in the correct height at the moment, and the placing table top 6-5 is also in the horizontal state, when the placing table top 6-5 is required to rotate, the springs 7-7 are required to be extruded, so that the placing table top 6-5 can be in a horizontal state under the condition of no external force, four linkage rotating devices 7 are arranged, four gear bars 7-1 are respectively in transmission connection with four rotating gears 6-3, four fixed square plates 7-5 are respectively and fixedly connected to the periphery of a connecting square block 5-2, the upper parts of four connecting square sliding columns 7-6 are respectively and fixedly connected with a shielding fixed plate 5-1, and the four springs 7-7 are all positioned below the shielding fixed plate 5-1.

The specific implementation method nine:

the embodiment is described below with reference to fig. 1 to 9, and the linkage rotating device 7 further described in the second embodiment further includes a limiting curved bar 7-2, the limiting curved bars 7-2 are fixedly connected above the four gear bars 7-1, the gear bar 7-1 can be further limited after the limiting curved bars 7-2 are provided, and when the limiting curved bars 7-2 contact the rotating gear 6-3, the gear bar 7-1 is located at the lowest point and cannot move downward.

The detailed implementation mode is ten:

the present embodiment is described below with reference to fig. 1 to 9, and the squeezing lifting device 8 further described in the present embodiment to the ninth embodiment includes a supporting vertical plate 8-1 and a contact cylinder 8-2, the supporting vertical plate 8-1 is fixedly connected above the load-bearing horizontal plate 1-1, the supporting vertical plate 8-1 can provide a fixed space for the contact cylinder 8-2, the contact cylinder 8-2 is fixedly connected to the supporting vertical plate 8-1, when the four contact curved plates 7-3 rotate, one of the four contact curved plates will contact, and when the contact curved plate 7-3 continues to rotate, the contact curved plate will move upward, so as to drive the gear rack 7-1 to move upward, and one of the four contact curved plates 7-3 will contact with the contact cylinder 8-2.

The working principle of the digital printing machine of the invention is as follows:

a device for intermittently and automatically transferring artificial chemical fiber cloth is fixedly connected above the right end of the bearing transverse plate 1-1, the artificial chemical fiber cloth can be automatically placed on four placing table boards 6-5, a starting motor I1-3 is in transmission connection with a bevel gear I1-4 through a bevel gear II5-4 to drive a central rotating shaft 5-3 to intermittently rotate, the four placing table boards 6-5 are finally driven to intermittently rotate, the rotating angle is ninety degrees each time, the artificial chemical fiber cloth on the placing table boards 6-5 stops for a period of time after being rotated ninety degrees, the artificial chemical fiber cloth on the placing table boards 6-5 can also rotate and move along with the placing table boards 6-5, when one placing table board 6-5 is transferred to the position under the printing machine head 4-2, the printing machine head 4-2 can print patterns on the artificial chemical fiber cloth, the height of the printing machine head 4-2 can be adjusted by using two electric telescopic rods 2-3, the extending distance of the printing head 4-2 can be adjusted by utilizing the threaded connection of the telescopic screw rod 3-4 and the bearing fixed plate 4-1, during printing, the moving track of the printing head 4-2 firstly descends to be contacted with the artificial chemical fiber cloth, the printing head 4-2 transversely moves, then the complete printing can be printed on the artificial chemical fiber cloth, after printing is finished, the four placing table boards 6-5 can continuously rotate intermittently, when the next placing table board 6-5 is positioned right below the printing head 4-2, the printing head 4-2 can print patterns on the artificial chemical fiber cloth, when one of the contacting curved plates 7-3 is contacted with the contacting cylinder 8-2, the gear strip 7-1 can be driven to move upwards, and at the moment, the connecting rotating cavity 6-2 can be driven to rotate through the rotating gear 6-3, at the moment, products on the placing table top 6-5 can be discharged, after the rotation is finished, the elastic force generated by the spring 7-7 is utilized to act on the connecting slide block 7-4, the connecting slide block 7-4 is contacted with the fixed square plate 7-5, the gear strip 7-1 is in the correct height, the placing table top 6-5 is also in the horizontal position to be restored to the original position, next printing is carried out when next artificial chemical fiber cloth comes, the device can automatically discharge the processed products, the full-automatic production is realized, and the workload of workers is reduced.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (10)

1. The utility model provides a digital printing machine, includes that the stamp bears table component (1), the elevating gear (2) is connected to the bearing, telescopic member (3) is connected to the bearing, digital printing component (4), bears linkage component (5), mesa component (6), linkage rotary device (7) and extrusion elevating gear (8) are placed to the seal paper, its characterized in that: the printing bears the weight of the top fixedly connected with bearing of the left end of the table component (1) and connects the elevating gear (2), the bearing connect the elevating gear (2) on be connected with the bearing and connect flexible component (3), the bearing connect flexible component (3) on be connected with digital printing component (4), the printing bear the weight of the table component (1) on be connected with and bear linkage component (5), the printing paper place mesa component (6) and linkage rotary device (7) all be provided with four, four the printing paper place mesa component (6) even fixed connection bear around linkage component (5), four linkage rotary device (7) respectively with four printing paper place mesa component (6) meshing connection, printing bear table component (1) on fixedly connected with extrusion elevating gear (8), the extrusion lifting device (8) is in contact with one of the four linkage rotating devices (7).

2. A digital printing machine as claimed in claim 1, wherein: the printing bearing table component (1) comprises a bearing transverse plate (1-1), inclined supporting legs (1-2), a motor I (1-3) and bevel gears I (1-4), wherein the inclined supporting legs (1-2) are fixedly connected to the front end and the rear end of the lower portion of the bearing transverse plate (1-1), the motor I (1-3) is fixedly connected to the lower portion of the bearing transverse plate (1-1), and the bevel gears I (1-4) are fixedly connected to output shafts of the motor I (1-3).

3. A digital printing machine according to claim 2, wherein: the bearing connection lifting device (2) comprises a bottom fixing plate (2-1), a connection sliding cavity (2-2) and electric telescopic rods (2-3), wherein the bottom fixing plate (2-1) is fixedly connected above the left end of the bearing transverse plate (1-1), the bottom fixing plate (2-1) is fixedly connected with the connection sliding cavity (2-2), the number of the electric telescopic rods (2-3) is two, and the two electric telescopic rods (2-3) are respectively and fixedly connected at the front end and the rear end above the bottom fixing plate (2-1).

4. A digital printing machine as claimed in claim 3, wherein: the bearing connecting telescopic component (3) comprises a lifting sliding plate (3-1) and a linkage top plate (3-2), the lifting device comprises a motor II (3-3) and a telescopic lead screw (3-4), a lifting sliding plate (3-1) is connected in a connecting sliding cavity (2-2) in a sliding mode, a linkage top plate (3-2) is fixedly connected above the lifting sliding plate (3-1), two electric telescopic rods (2-3) are respectively and fixedly connected to the front end and the rear end below the linkage top plate (3-2), the motor II (3-3) is fixedly connected to the lifting sliding plate (3-1), an output shaft of the motor II (3-3) is rotatably connected with the lifting sliding plate (3-1), and the telescopic lead screw (3-4) is fixedly connected to an output shaft of the motor II (3-3).

5. A digital printing machine according to claim 4, wherein: the digital printing component (4) comprises a bearing fixing plate (4-1), a printing machine head (4-2) and a telescopic sliding column (4-3), the printing machine head (4-2) is fixedly connected to the lower portion of the bearing fixing plate (4-1), the telescopic sliding column (4-3) is connected to the front side and the rear side of the left end of the bearing fixing plate (4-1) in a sliding mode, the two telescopic sliding columns (4-3) are fixedly connected with the lifting sliding plate (3-1), and the telescopic lead screw (3-4) is connected with the bearing fixing plate (4-1) through threads.

6. A digital printing machine according to claim 5, wherein: the bearing linkage component (5) comprises a shielding fixing plate (5-1), a connecting square block (5-2), a central rotating shaft (5-3) and a bevel gear II (5-4), the connecting square block (5-2) is fixedly connected to the lower portion of the shielding fixing plate (5-1), the central rotating shaft (5-3) is fixedly connected to the lower portion of the connecting square block (5-2), the central rotating shaft (5-3) is rotatably connected with a bearing transverse plate (1-1), the bevel gear II (5-4) is fixedly connected to the lower portion of the central rotating shaft (5-3), and the bevel gear II (5-4) is in transmission connection with the bevel gear I (1-4).

7. A digital printing machine according to claim 6, wherein: the printing paper placing table board component (6) comprises a connecting bearing shaft (6-1), a connecting rotating cavity (6-2), a rotating gear (6-3), a fixing column (6-4) and a placing table board (6-5), wherein the connecting bearing shaft (6-1) is connected with the connecting rotating cavity (6-2) in a rotating mode, the connecting rotating cavity (6-2) is fixedly connected with the rotating gear (6-3), the connecting rotating cavity (6-2) is internally fixedly connected with the fixing column (6-4), the fixing column (6-4) is fixedly connected with the placing table board (6-5), the printing paper placing table board component (6) is provided with four connecting bearing shafts (6-1), and the four connecting bearing shafts (6-1) are respectively and fixedly connected around the connecting square block (5-2).

8. A digital printing machine as claimed in claim 7, wherein: the linkage rotating device (7) comprises gear bars (7-1), contact curved plates (7-3), connecting sliders (7-4), fixed square plates (7-5), connecting square sliding columns (7-6) and springs (7-7), the contact curved plates (7-3) are fixedly connected below the gear bars (7-1), the connecting sliders (7-4) are fixedly connected on the gear bars (7-1), the connecting square sliding columns (7-6) are fixedly connected on the fixed square plates (7-5), the connecting square sliding columns (7-6) are in sliding connection with the connecting sliders (7-4), the springs (7-7) are sleeved on the connecting square sliding columns (7-6), the springs (7-7) are located above the connecting sliders (7-4), four linkage rotating devices (7) are arranged, the four gear strips (7-1) are in transmission connection with the four rotating gears (6-3) respectively, the four fixed square plates (7-5) are fixedly connected to the periphery of the connecting square block (5-2) respectively, the upper parts of the four connecting square sliding columns (7-6) are fixedly connected with the shielding fixed plate (5-1), and the four springs (7-7) are located below the shielding fixed plate (5-1).

9. A digital printing machine as claimed in claim 8, wherein: the linkage rotating device (7) further comprises limiting curved bars (7-2), and the four gear bars (7-1) are fixedly connected with the limiting curved bars (7-2).

10. A digital printing machine as claimed in claim 8, wherein: the extrusion lifting device (8) comprises a supporting vertical plate (8-1) and a contact cylinder (8-2), the supporting vertical plate (8-1) is fixedly connected above the bearing transverse plate (1-1), the contact cylinder (8-2) is fixedly connected to the supporting vertical plate (8-1), and one of the four contact curved plates (7-3) is in contact with the contact cylinder (8-2).

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