CN215662433U - Automatic mark machine that scalds of superfine fiber glasses cloth - Google Patents

Abstract

The application relates to the field of trademark thermoprint, specifically discloses an automatic mark machine that scalds of superfine fiber glasses cloth, which comprises a frame, frame upper end fixedly connected with table surface, the table surface upper end is provided with the platform of placing that is used for placing glasses cloth, the table surface upper end is provided with the heating element who is used for heating the pyrograph mark, table surface is last to be provided with and to be used for the automatic material loading subassembly of placing the pyrograph mark, the material loading subassembly includes first vacuum chuck, first vacuum chuck and table surface swing joint. The hot-stamping efficiency of the glasses cloth can be improved. This application has the effect that can improve the mark efficiency of scalding to glasses cloth.

Description

Automatic mark machine that scalds of superfine fiber glasses cloth

Technical Field

The invention relates to the technical field of trademark hot stamping, in particular to an automatic hot stamping machine for superfine fiber glasses cloth.

Background

Trademarks are marks for distinguishing the brand of one operator from the brand of another operator, and the types, shapes, and sizes of trademarks vary widely, but they are printed on commodities or packages of the commodities.

Due to the special use scene, the glasses cloth is usually made of superfine fibers. When the glasses cloth is subjected to hot stamping, hot stamping can be completed by adopting a hot stamping mark, the hot stamping mark is a method that patterns are printed on special transfer paper by using common ink or pigment ink, and a layer of colloid on the transfer paper is melted by heat and is adhered to the surface of the glasses cloth together with the printed patterns by heating the transfer paper.

The existing label ironing process is that the label ironing is usually manually placed on the surface of the glasses cloth by production personnel, so that the label ironing efficiency is low.

SUMMERY OF THE UTILITY MODEL

In order to improve the mark efficiency of scalding to glasses cloth, this application provides an automatic mark machine that scalds of superfine fiber glasses cloth.

The application provides a pair of automatic mark machine that scalds of superfine fiber glasses cloth, which comprises a frame, frame upper end fixedly connected with table surface, the table surface upper end is provided with the platform of placing that is used for placing glasses cloth, the table surface upper end is provided with the heating element who is used for heating the pyrograph mark, table surface is last to be provided with and to be used for placing the material loading subassembly that the pyrograph mark was scalded automatically, the material loading subassembly includes first vacuum chuck, first vacuum chuck and table surface swing joint.

Through adopting above-mentioned technical scheme, when carrying out the thermoprint to glasses cloth, the producer at first places glasses cloth in placing the bench, the material loading subassembly carries out automatic feeding to the pyrograph mark, through the absorption of first vacuum chuck to the pyrograph mark, put the pyrograph label on glasses cloth automatically, place the completion back, heating element heats the pyrograph mark, the adhesion is on glasses cloth surface after the pattern on the pyrograph mark is heated, the completion is pyrograph, the setting up of material loading subassembly has realized the automatic feeding to the pyrograph mark, the efficiency of pyrograph is improved.

Optionally, be provided with the installation cover on the table surface, heating element includes scalable hydro-cylinder, scalable hydro-cylinder is connected with the protection casing through the linking arm, the piston rod end fixedly connected with heating block of scalable hydro-cylinder, the heating block is used for with the pyrograph mark inconsistent in order to with pattern rendition to glasses cloth.

Through adopting above-mentioned technical scheme, scalable hydro-cylinder provides the drive power for sliding of heating block, and scalable hydro-cylinder starts, and drive heating block removes, and the heating block contacts with the pyrograph mark, and the heating block passes through heat-conduction, makes the pattern printing on the pyrograph mark on the glasses cloth.

Optionally, the equal fixedly connected with guide block in both sides of scalable hydro-cylinder, be provided with the guide bar between heating block and the guide block, the one end and the heating block fixed connection of guide bar, the other end of guide bar is worn to establish in the guide block, the guide bar slides with the guide block and is connected.

Through adopting above-mentioned technical scheme, the heating block need slide certain stroke and the pyrograph mark contacts, and the setting of guide block and guide bar provides direction and spacing for the slip of heating block, makes the slip of heating block more stable.

Optionally, the feeding assembly further comprises a horizontal driving portion, the horizontal driving portion comprises a first air cylinder, the first air cylinder is located in the installation cover and fixedly connected with the working table surface, a piston rod of the first air cylinder is arranged in the horizontal direction, and the first air cylinder is used for driving the first vacuum chuck to move in the horizontal direction.

Through adopting above-mentioned technical scheme, first cylinder provides drive power for first vacuum chuck along the removal of horizontal direction, has realized the motion of first vacuum chuck along the horizontal direction.

Optionally, the feeding assembly further comprises a vertical driving portion, the vertical driving portion comprises a second cylinder, the second cylinder is fixedly connected with the end of the piston rod of the first cylinder through an adapter plate, the piston rod of the second cylinder is arranged in the vertical direction, and the second cylinder is used for driving the first vacuum chuck to move in the vertical direction.

Through adopting above-mentioned technical scheme, the second cylinder provides drive power for first vacuum chuck along vertical direction's removal, has realized the motion of first vacuum chuck along vertical direction.

Optionally, the first vacuum chuck is connected with the end of the piston rod of the second air cylinder through a first mounting plate, and the first vacuum chuck is detachably connected with the first mounting plate.

Through adopting above-mentioned technical scheme, setting up of first mounting panel can make that first vacuum chuck is more stable link to each other with the second cylinder, and first vacuum chuck can be dismantled with first mounting panel and be connected and made things convenient for the dismouting to first vacuum chuck.

Optionally, a blanking assembly is further arranged on the workbench surface and comprises a second vacuum sucker, the second vacuum sucker is used for adsorbing the thermoprint marks finished by thermoprinting, and the second vacuum sucker is movably connected with the workbench surface.

Through adopting above-mentioned technical scheme, the unloading subassembly will use the pyrograph mark after the automation take away from glasses cloth, and second vacuum chuck adsorbs the pyrograph mark that uses the excess thickness, has realized the automatic unloading of pyrograph mark.

Optionally, the blanking assembly further comprises a third air cylinder, the third air cylinder is a rotary air cylinder, the third air cylinder is fixedly connected with the working table, and the second vacuum chuck is connected with the end of the piston rod of the third air cylinder through a second mounting plate.

Through adopting above-mentioned technical scheme, the third cylinder provides drive power for the removal of second vacuum chuck, has realized second vacuum chuck's automatic movement.

In summary, the present application includes at least one of the following beneficial technical effects:

1. when the glasses cloth is subjected to hot stamping, a producer firstly places the glasses cloth on a placing table, a feeding assembly automatically feeds a hot-stamping label, the hot-stamping label is adsorbed by a first vacuum chuck and automatically placed on the glasses cloth, after the placement is completed, a heating assembly heats the hot-stamping label, a pattern on the hot-stamping label is adhered to the surface of the glasses cloth after being heated, the hot-stamping label is completed, the automatic feeding of the hot-stamping label is realized by the arrangement of the feeding assembly, and the efficiency of the hot-stamping label is improved;

2. the automatic unloading of pyrograph mark after unloading subassembly will use is taken away from the glasses cloth is automatic, and second vacuum chuck adsorbs the pyrograph mark that uses the excess thickness, has realized the automatic unloading of pyrograph mark.

Drawings

Fig. 1 is a schematic diagram for embodying the overall structure of the present embodiment.

Fig. 2 is an exploded view for embodying the overall structure of the present embodiment.

Fig. 3 is a schematic diagram for embodying the structure of the charging assembly.

FIG. 4 is a schematic diagram illustrating the connection of the first vacuum chuck to the first mounting plate.

Fig. 5 is a schematic diagram for embodying the structure of the heating assembly.

Fig. 6 is a schematic diagram for embodying the structure of the blanking assembly.

Description of reference numerals:

1. a frame; 2. a work table; 3. a placing table; 4. mounting a cover; 41. a sliding groove; 5. a feeding assembly; 51. a first cylinder; 52. an adapter plate; 53. a second cylinder; 54. a first mounting plate; 55. a first vacuum chuck; 551. a suction hood; 552. an air duct; 553. an air inlet pipe; 56. a limiting ring; 57. locking the nut; 6. a connecting arm; 7. a heating assembly; 71. a telescopic oil cylinder; 72. a heating block; 73. a guide block; 74. a guide bar; 8. a blanking assembly; 81. a third cylinder; 82. a second mounting plate; 83. a second vacuum chuck.

Detailed Description

The present application is described in further detail below with reference to figures 1-6.

The embodiment of the application discloses automatic mark machine that scalds of superfine fiber glasses cloth.

Referring to fig. 1 and 2, an automatic mark machine that scalds of superfine fiber glasses cloth includes frame 1, 1 upper end fixedly connected with table surface 2 of frame, table surface 2 is last fixedly connected with to be used for placing the platform 3 of placing of glasses cloth, still be provided with installation cover 4 on table surface 2, be provided with in the installation cover 4 and be used for automatic feeding to scald the marked material loading subassembly 5 of painting, it is provided with heating element 7 that is used for heating to scald the marked material to place the platform 3 top, one side society that installation cover 4 is close to placing platform 3 is provided with and is used for automatic unloading to scald the marked unloading subassembly 8 of painting.

Referring to fig. 1 and 2, when scalding glasses cloth, the producer places glasses cloth on placing platform 3, material loading subassembly 5 will scald the automatic surface of placing at glasses cloth of drawing mark, the completion back is placed to the pyrography mark, heating element 7 heats the pyrography mark, the pattern adhesion on the pyrography mark is on glasses cloth surface, the completion scalds the mark, the automatic tak away of pyrography mark that unloading subassembly 8 will scald the mark and accomplish is accomplished, equipment has realized automatic feeding and unloading to the pyrography mark, the efficiency of scalding the mark is improved.

Referring to fig. 3, the mounting cover 4 is a cover body with an opening at the lower end, the mounting cover 4 is fixedly connected with the working table 2, the feeding assembly 5 includes a first air cylinder 51 and a second air cylinder 53, the first air cylinder 51 and the second air cylinder 53 are both located in the mounting cover 4, the cylinder body of the first air cylinder 51 is fixedly connected with the working table 2, the piston rod of the first air cylinder 51 is arranged along the horizontal direction, the end of the piston rod of the first air cylinder 51 is arranged towards the placing table 3, the end of the piston rod of the first air cylinder 51 is fixedly connected with an adapter plate 52, the cylinder body of the second air cylinder 53 is fixedly connected with the adapter plate 52, the piston rod of the second air cylinder 53 is arranged vertically upwards, the end of the piston rod of the second air cylinder 53 is connected with a first mounting plate 54, the first mounting plate 54 is arranged along the horizontal direction, one end of the first mounting plate 54 is fixedly connected with the end of the piston rod of the second air cylinder 53, the other end of the first mounting plate 54 extends out of the mounting cover 4, the mounting cover 4 is close to and has seted up the corresponding chute 41 of first mounting panel 54 on placing the lateral wall of platform 3, and first mounting panel 54 slides and sets up in chute 41, and material loading subassembly 5 still includes first vacuum chuck 55, and first vacuum chuck 55 sets up in the outer one end of first mounting panel 54 position in mounting cover 4, and first vacuum chuck 55 can dismantle with first mounting panel 54 and be connected.

Referring to fig. 3, the first cylinder 51 provides a driving force for the movement of the first vacuum chuck 55 in the horizontal direction, and the movement of the first vacuum chuck 55 in the horizontal direction is achieved. The second cylinder 53 provides a driving force for the movement of the first vacuum chuck 55 in the vertical direction, and the movement of the first vacuum chuck 55 in the vertical direction is realized. When material loading subassembly 5 carries out the material loading to the pyrograph mark, the piston rod withdrawal of second cylinder 53, first vacuum chuck 55 downstream adsorbs the pyrograph mark, adsorb and accomplish the back, and the second piston rod stretches out, and the piston rod of first cylinder 51 stretches out afterwards, and the first vacuum chuck 55 of drive moves to glasses cloth top, and the piston rod withdrawal of second cylinder 53, first vacuum chuck 55 will scald the pyrograph mark and place glasses cloth on the surface, accomplish the automatic feeding to the pyrograph mark.

Referring to fig. 4, the first vacuum chuck 55 includes an air duct 552, a suction hood 551 and an air duct 553, one end of the air duct 552 is communicated with the suction hood 551, the suction hood 551 is located below the first mounting plate 54, the other end of the air duct 552 passes through the first mounting plate 54 and extends to the upper side of the first mounting plate 54, one end of the air duct 552 located above the first mounting plate 54 is not communicated with the outside, a limiting ring 56 is fixedly connected to the outer annular wall of the air duct 552, the limiting ring 56 is located below the first mounting plate 54, the air duct 553 is located below the first mounting plate 54 and is communicated with the air duct 552, a locking nut 57 is arranged above the first mounting plate 54, and the locking nut 57 is in threaded connection with the air duct 552.

Referring to fig. 4, the first vacuum chuck 55 is detachably connected to the first mounting plate 54, so that the first vacuum chuck 55 can be disassembled and assembled, when the first vacuum chuck 55 is mounted, the limiting ring 56 is abutted to the first mounting plate 54, and the locking nut 57 is screwed to lock the first vacuum chuck 55.

Referring to fig. 5, the mounting cover 4 is close to the connecting arm 6 fixedly connected to the side wall of the placing table 3, the heating assembly 7 includes a telescopic oil cylinder 71 and a heating block 72 for abutting and heating the pyrograph mark, the telescopic oil cylinder 71 and the connecting arm 6 are fixedly connected to one end far away from the mounting cover 4, the end of the piston rod of the telescopic oil cylinder 71 is arranged downward, the heating block 72 is fixedly connected to the end of the piston rod of the telescopic oil cylinder 71, and the heating block 72 is located right above the placing table 3.

Referring to fig. 5, two opposite sides of the telescopic cylinder 71 are provided with guide blocks 73, the guide blocks 73 are fixedly connected with the telescopic cylinder 71, a guide rod 74 is arranged between the heating block 72 and the guide blocks 73, the guide rod 74 is parallel to a piston rod of the telescopic cylinder 71, one end of the guide rod 74 is fixedly connected with the heating block 72, and the other end of the guide rod 74 is slidably arranged in the guide blocks 73.

Referring to fig. 5, the telescopic cylinder 71 provides a driving force for sliding the heating block 72, the telescopic cylinder 71 is started to drive the heating block 72 to move, the heating block 72 is in contact with the pyrograph, the heating block 72 enables the pattern on the pyrograph to be printed on the glasses cloth through heat conduction, and the guide block 73 and the guide rod 74 provide guidance and limit for sliding of the heating block 72, so that sliding of the heating block 72 is more stable.

Referring to fig. 5 and 6, the blanking assembly 8 includes a third cylinder 81 and a second vacuum chuck 83 for adsorbing the pyrograph, the third cylinder 81 is fixedly connected to the working table 2, a piston rod end of the third cylinder 81 is disposed upward, the third cylinder 81 is a rotary cylinder, the second vacuum chuck 83 is connected to the piston rod end of the third cylinder 81 through a second mounting plate 82, one end of the second mounting plate 82 is fixedly connected to the piston rod end of the third cylinder 81, the other end of the second mounting plate 82 is detachably connected to the second vacuum chuck 83, and the detachable structure of the second vacuum chuck 83 is completely consistent with the detachable structure of the first vacuum chuck 55.

Referring to fig. 6, after the hot stamping of the hot stamping label is completed, the third cylinder 81 is started, a piston rod of the third cylinder 81 drives the second mounting plate 82 to rotate and lift along the vertical direction, the second vacuum chuck is driven to move to the position above the hot stamping label, and the hot stamping label after the hot stamping is completed is blanked.

The implementation principle of the embodiment of the application is as follows: the producer at first lays the glasses water distribution and establishes on placing platform 3, and the completion back is laid to the glasses cloth, and material loading subassembly 5 starts, and first vacuum chuck 55 will be scalded the drawing mark and place on the surface of glasses cloth. And then the heating component 7 is started, the heating block 72 compresses and heats the pyrograph, and after the pyrograph is heated, the pattern on the pyrograph is adhered to the surface of the glasses cloth. After the hot stamping is finished, the blanking assembly 8 is started, and the second vacuum chuck takes away the hot stamping mark finished by the hot stamping from the surface of the glasses cloth.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides an automatic mark machine that scalds of superfine fiber glasses cloth, includes frame (1), frame (1) upper end fixedly connected with table surface (2), table surface (2) upper end is provided with the platform (3) of placing that is used for placing glasses cloth, table surface (2) upper end is provided with and is used for heating to scald marked heating element (7), its characterized in that: be provided with on table surface (2) and be used for automatic material loading subassembly (5) of placing the pyrograph mark, material loading subassembly (5) include first vacuum chuck (55), first vacuum chuck (55) and table surface (2) swing joint.

2. The automatic ironing machine for the superfine fiber glasses cloth of claim 1, which is characterized in that: be provided with installation cover (4) on table surface (2), heating element (7) are including scalable hydro-cylinder (71), scalable hydro-cylinder (71) are connected with the protection casing through linking arm (6), the piston rod end fixedly connected with heating block (72) of scalable hydro-cylinder (71), heating block (72) are used for with the pyrograph mark inconsistent in order to with pattern transfer printing to glasses cloth.

3. The automatic ironing machine for the superfine fiber glasses cloth of claim 2 is characterized in that: the equal fixedly connected with guide block (73) in both sides of scalable hydro-cylinder (71), be provided with guide bar (74) between heating piece (72) and guide block (73), the one end and the heating piece (72) fixed connection of guide bar (74), the other end of guide bar (74) is worn to establish in guide block (73), guide bar (74) and guide block (73) are slided and are connected.

4. The automatic ironing machine for the superfine fiber glasses cloth of claim 3, which is characterized in that: the feeding assembly (5) further comprises a horizontal driving portion, the horizontal driving portion comprises a first air cylinder (51), the first air cylinder (51) is located in the installation cover (4), the first air cylinder (51) is fixedly connected with the working table top (2), a piston rod of the first air cylinder (51) is arranged along the horizontal direction, and the first air cylinder (51) is used for driving a first vacuum chuck (55) to move along the horizontal direction.

5. The automatic ironing machine for the superfine fiber glasses cloth of claim 4, which is characterized in that: the feeding assembly (5) further comprises a vertical driving portion, the vertical driving portion comprises a second air cylinder (53), the second air cylinder (53) is fixedly connected with the end of a piston rod of the first air cylinder (51) through an adapter plate (52), the piston rod of the second air cylinder (53) is arranged in the vertical direction, and the second air cylinder (53) is used for driving the first vacuum chuck (55) to move in the vertical direction.

6. The automatic ironing machine for the superfine fiber glasses cloth of claim 5, which is characterized in that: the first vacuum chuck (55) is connected with the end of the piston rod of the second air cylinder (53) through a first mounting plate (54), and the first vacuum chuck (55) is detachably connected with the first mounting plate (54).

7. The automatic ironing machine for the superfine fiber glasses cloth of claim 6, which is characterized in that: still be provided with unloading subassembly (8) on table surface (2), unloading subassembly (8) include second vacuum chuck (83), second vacuum chuck (83) are used for adsorbing the pyrograph mark that the thermoprint was accomplished, second vacuum chuck (83) link to each other with table surface (2) activity.

8. The automatic ironing machine for the superfine fiber glasses cloth of claim 7, which is characterized in that: unloading subassembly (8) still include third cylinder (81), third cylinder (81) are revolving cylinder, third cylinder (81) and table surface (2) fixed connection, second vacuum chuck (83) link to each other through the piston rod end of second mounting panel (82) and third cylinder (81).

Images