CN113954512B - Steel belt mark printing device - Google Patents

Abstract

The invention relates to the technical field of stamping devices, in particular to a steel belt mark printing device which is fixedly connected with a mounting frame through a conveying component, a storage box is fixedly connected with the mounting frame, a first motor is fixedly connected with the storage box, a rotating shaft is fixedly connected with the output end of the first motor, a plurality of flow dividing plates are respectively fixedly connected with the rotating shaft, a sponge is fixedly connected with a discharge hole of the storage box, a hairbrush is fixedly connected with the sponge, an imprinting component is fixedly connected with the mounting frame, the rotating shaft is driven by the first motor to drive the flow dividing plates to rotate, a solution in the storage box is conveyed to the sponge of the discharge hole, the sponge uniformly distributes the solution on the hairbrush, the slower the rotating speed of the first motor is, the slower the solution is flowed to the discharge hole is, and the problem that excessive solution conveyed to the hairbrush is smeared on the imprinting component and the definition of patterns printed by the imprinting component is affected is solved.

Description

Steel belt mark printing device

Technical Field

The invention relates to the technical field of stamping devices, in particular to a steel belt marking device.

Background

The synchronous belt is one kind of conveyer belt, and the inner circumference of the belt is toothed to mesh with toothed belt wheel, so that the synchronous belt has the advantages of stable transmission, vibration absorption, low noise, etc., and after the synchronous belt is produced, the synchronous belt is required to be printed by a steel belt mark printing device, and the mark printing content comprises patterns, trademarks, etc.;

the existing steel belt mark printing device conveys the solution in the storage box to the hairbrush through the conveying pump, the hairbrush smears the solution on the stamping assembly, and the stamping assembly prints marks on the steel belt conveyed by the conveying assembly;

however, the amount of solution delivered by the delivery pump cannot be adjusted so that the solution delivered to the brush is excessively smeared on the imprinting assembly, thereby affecting the clarity of the pattern printed by the imprinting assembly.

Disclosure of Invention

The invention aims to provide a steel belt mark printing device, which aims to solve the problem that excessive solution conveyed to a hairbrush is smeared on an embossing assembly to influence the definition of a pattern printed by the embossing assembly.

In order to achieve the above purpose, the invention provides a steel belt mark printing device, which comprises a conveying mechanism and a mark printing mechanism;

the conveying mechanism comprises a mounting frame and a conveying assembly, and the conveying assembly is fixedly connected with the mounting frame and is positioned on the inner side wall of the mounting frame;

the mark printing mechanism comprises a storage box, a first motor, a rotating shaft, a plurality of flow dividing plates, a sponge, a hairbrush and an embossing assembly, wherein the storage box is fixedly connected with the mounting frame and penetrates through the mounting frame, the first motor is fixedly connected with the storage box and is positioned on the outer side wall of the storage box, the rotating shaft is fixedly connected with the output end of the first motor and penetrates through the storage box, the flow dividing plates are respectively fixedly connected with the rotating shaft and are all positioned on the outer side wall of the rotating shaft, the storage box is provided with a discharge hole, the sponge is fixedly connected with the storage box and is positioned at the discharge hole, the hairbrush is fixedly connected with the sponge and is positioned on one side far away from the storage box, and the embossing assembly is fixedly connected with the mounting frame and is positioned on one side close to the hairbrush.

The first motor drives the rotating shaft to drive the flow dividing plate to rotate, the solution in the storage box is conveyed to the sponge of the discharge port, the sponge uniformly distributes the solution on the brush, and the slower the rotating speed of the first motor is, the slower the speed of the solution flowing to the discharge port is.

The mark printing mechanism further comprises a bearing, wherein the outer ring of the bearing is fixedly connected with the storage box, the inner ring of the bearing is fixedly connected with the rotating shaft and is positioned between the storage box and the rotating shaft.

The bearing is used for fixing one side, far away from the first motor, of the rotating shaft on the storage box, so that stability of the rotating shaft during rotation is improved.

The seal gasket is fixedly connected with the flow dividing plates and is positioned at one side close to the storage box.

The sealing ring fills gaps between the flow dividing plate and the storage box, so that the efficiency of the flow dividing plate for blocking solution is improved.

The embossing assembly comprises a first support, a second motor, an embossing roller and a second support, wherein the first support is fixedly connected with the mounting frame and is located near one side of the storage box, the second motor is fixedly connected with the mounting frame and located on the outer side wall of the mounting frame, the embossing roller is fixedly connected with the output end of the second motor and penetrates through the first support, the second support is fixedly connected with the mounting frame and located near one side of the first support, and the embossing roller is rotatably connected with the second support.

The second motor on the first support of the embossing assembly drives the embossing roller to rotate on the second support, so that the embossing roller contacts the hairbrush to smear solution when rotating, and then patterns are printed on the steel belt.

The stamping assembly further comprises two connecting rods and a scraping plate, the two connecting rods are respectively fixedly connected with the first support and the second support, the connecting rods are respectively located on the outer side walls of the first support and the second support, and the scraping plate is fixedly connected with the two connecting rods and located between the two connecting rods.

The scraping plate on the connecting rod can scrape the solution on the embossing roller, so that the solution on the embossing roller is uniformly distributed.

The stamping assembly further comprises two outer cylinders, two inner cylinders, two sliding modules and two damping springs, wherein the two connecting rods are respectively provided with a sliding groove, the two outer cylinders are respectively fixedly connected with the scraping plates and are respectively located on one sides of the connecting rods, the two inner cylinders are respectively and slidably connected with the two outer cylinders and respectively penetrate through the outer cylinders, the two sliding modules are respectively and respectively fixedly connected with the two inner cylinders and respectively in the sliding grooves, one sides of the two damping springs are respectively and fixedly connected with the outer cylinders, and the other sides of the two damping springs are respectively and respectively fixedly connected with the two inner cylinders and respectively located in the outer cylinders.

The damping spring in the outer cylinder pushes the sliding module on the inner cylinder to be in contact with the sliding groove on the connecting rod, the damping spring absorbs vibration generated when the scraping plate scrapes the solution on the embossing roller, and the inner cylinder correspondingly slides in the sliding groove under the deformation condition that the sliding module generates when the damping spring absorbs the vibration.

The sliding module comprises a rotating rod and balls, wherein the rotating rod is fixedly connected with the inner cylinder and is positioned on the inner side wall of the inner cylinder, and the balls are rotationally connected with the rotating rod and are all positioned in the sliding groove.

The deformation produced when the damping spring absorbs vibration drives the inner cylinder to move, and the balls on the inner cylinder follow the moving direction of the inner cylinder, rotate on the inner cylinder through the rotating rod and slide on the sliding groove.

According to the steel belt mark printing device, the first motor drives the rotating shaft to drive the flow dividing plate to rotate, the solution in the storage box is conveyed to the sponge of the discharge port, the sponge uniformly distributes the solution on the hairbrush, the slower the rotating speed of the first motor is, the slower the speed of the solution flowing to the discharge port is, and the problem that too much solution conveyed to the hairbrush is smeared on the printing assembly to influence the definition of patterns printed by the printing assembly is solved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a steel strip marking device according to the present invention;

FIG. 2 is a cross-sectional view of a steel strip marking device along the direction of a rotating shaft;

fig. 3 is an enlarged view at detail a of fig. 2;

FIG. 4 is a cross-sectional view of a steel strip marking device along the direction of a damper spring according to the present invention;

fig. 5 is an enlarged view at detail B of fig. 4.

1-conveying mechanism, 2-seal mark mechanism, 3-mounting bracket, 4-conveying component, 5-storage box, 6-first motor, 7-pivot, 8-flow dividing plate, 9-discharge gate, 10-sponge, 11-brush, 12-seal mark component, 13-bearing, 14-sealing pad, 15-first support, 16-second motor, 17-seal mark roller, 18-second support, 19-connecting rod, 20-scraper blade, 21-spout, 22-urceolus, 23-inner tube, 24-sliding module, 25-damping spring, 26-bull stick, 27-ball, 28-damping sleeve, 29-lifter, 30-mounting plate, 31-conveying roller.

Detailed Description

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present invention and should not be construed as limiting the invention.

In the description of the present invention, it should be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present invention and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present invention. Furthermore, in the description of the present invention, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

Referring to fig. 1 to 5, the present invention provides a steel strip marking device, which includes a conveying mechanism 1 and a marking mechanism 2;

the conveying mechanism 1 comprises a mounting frame 3 and a conveying assembly 4, wherein the conveying assembly 4 is fixedly connected with the mounting frame 3 and is positioned on the inner side wall of the mounting frame 3;

the mark printing mechanism 2 comprises a storage box 5, a first motor 6, a rotating shaft 7, a plurality of flow dividing plates 8, a sponge 10, a hairbrush 11 and an embossing component 12, wherein the storage box 5 is fixedly connected with a mounting frame 3 and penetrates through the mounting frame 3, the first motor 6 is fixedly connected with the storage box 5 and is positioned on the outer side wall of the storage box 5, the rotating shaft 7 is fixedly connected with the output end of the first motor 6 and penetrates through the storage box 5, the flow dividing plates 8 are respectively and fixedly connected with the rotating shaft 7 and are all positioned on the outer side wall of the rotating shaft 7, the storage box 5 is provided with a discharge hole 9, the sponge 10 is fixedly connected with the storage box 5 and is positioned at the discharge hole 9, the hairbrush 11 is fixedly connected with the sponge 10 and is positioned on one side far away from the storage box 5, and the embossing component 12 is fixedly connected with the mounting frame 3 and is positioned on one side close to the hairbrush 11.

In this embodiment, the mounting frame 3 of the conveying mechanism 1 provides mounting conditions for the conveying component 4 and the marking mechanism 2, the conveying component 4 is used for conveying a steel belt to the position of the brush 11 of the marking mechanism 2, the storage box 5 is used for storing the solution, the flow dividing plate 8 is used for dividing the solution in the storage box 5 from the discharge hole 9, the rotating shaft 7 is driven by the first motor 6 to drive the flow dividing plate 8 to rotate, the solution in the storage box 5 can be conveyed to the sponge 10 of the discharge hole 9, the sponge 10 uniformly distributes the solution on the brush 11, the brush 11 is used for smearing the solution on the imprinting component 12, the imprinting component 12 is based on the solution smeared by the brush 11, the pattern can be printed on the steel belt, the slower the rotating speed of the first motor 6 is, the slower the speed of the solution flowing to the discharge hole 9 is, the first motor 6 is composed of a motor body and a speed reducer, the motor body is used for outputting the solution to the rotating shaft 7, and the problem that the pattern is further smeared by the brush 11 is affected by the motor body, and the pattern is further smeared on the imprinting component 12 is clearly.

Further, the marking mechanism 2 further comprises a bearing 13, an outer ring of the bearing 13 is fixedly connected with the storage box 5, and an inner ring of the bearing 13 is fixedly connected with the rotating shaft 7 and is positioned between the storage box 5 and the rotating shaft 7; the marking mechanism 2 further comprises a plurality of sealing gaskets 14, wherein the sealing gaskets 14 are respectively and fixedly connected with the plurality of flow dividing plates 8 and are positioned at one side close to the storage box 5; the embossing assembly 12 comprises a first bracket 15, a second motor 16, an embossing roller 17 and a second bracket 18, wherein the first bracket 15 is fixedly connected with the mounting frame 3 and is positioned at one side close to the storage box 5, the second motor 16 is fixedly connected with the mounting frame 3 and is positioned on the outer side wall of the mounting frame 3, the embossing roller 17 is fixedly connected with the output end of the second motor 16 and penetrates through the first bracket 15, the second bracket 18 is fixedly connected with the mounting frame 3 and is positioned at one side close to the first bracket 15, and the embossing roller 17 is rotatably connected with the second bracket 18; the imprinting assembly 12 further comprises two connecting rods 19 and a scraper 20, wherein the two connecting rods 19 are respectively and fixedly connected with the first bracket 15 and the second bracket 18, and are positioned on the outer side walls of the first bracket 15 and the second bracket 18, and the scraper 20 is fixedly connected with the two connecting rods 19 and is positioned between the two connecting rods 19; the imprinting assembly 12 further comprises two outer cylinders 22, two inner cylinders 23, two sliding modules 24 and two damping springs 25, wherein the two connecting rods 19 are respectively provided with a sliding chute 21, the two outer cylinders 22 are respectively and fixedly connected with the scraping plates 20 and are respectively positioned at one side close to the connecting rods 19, the two inner cylinders 23 are respectively and slidably connected with the two outer cylinders 22 and penetrate through the outer cylinders 22, the two sliding modules 24 are respectively and fixedly connected with the two inner cylinders 23 and are respectively arranged in the sliding chute 21, one sides of the two damping springs 25 are respectively and fixedly connected with the outer cylinders 22, and the other sides of the two damping springs 25 are respectively and fixedly connected with the two inner cylinders 23 and are respectively positioned in the outer cylinders 22; the sliding module 24 comprises a rotating rod 26 and a ball 27, the rotating rod 26 is fixedly connected with the inner cylinder 23 and is positioned on the inner side wall of the inner cylinder 23, and the ball 27 is rotatably connected with the rotating rod 26 and is positioned in the sliding groove 21.

In this embodiment, the bearing 13 fixes one side of the rotating shaft 7 away from the first motor 6 on the storage tank 5, so as to increase the stability of the rotating shaft 7 during rotation, the sealing ring fills the gap between the flow dividing plate 8 and the storage tank 5, the efficiency of the flow dividing plate 8 for blocking solution is increased, the second motor 16 on the first support 15 of the embossing assembly 12 drives the embossing roller 17 to rotate on the second support 18, so that after the embossing roller 17 contacts the brush 11 during rotation, the pattern is printed on a steel belt, the scraper 20 on the connecting rod 19 can scrape the solution on the embossing roller 17, so that the solution on the embossing roller 17 is uniformly distributed, the damping spring 25 in the outer cylinder 22 pushes the sliding module 24 on the inner cylinder 23 to contact with the sliding groove 21 on the connecting rod 19, the damping spring 25 absorbs the solution generated by the inner cylinder scraper 20 during scraping the roller 17, and the rolling ball 21 is deformed during rotation by the sliding module 27, and the rolling ball 21 is deformed during rotation, and the rolling of the rolling groove 21 is reduced during the rolling of the rolling ball 21.

Further, the sliding module 24 further includes a damping sleeve 28, where the damping sleeve 28 is fixedly connected to the balls 27 and is located on an outer side wall of the balls 27.

In this embodiment, the damping sleeve 28 can absorb the shock generated when the balls 27 slide on the sliding groove 21.

Further, the conveying assembly 4 comprises two lifting rods 29, two mounting plates 30 and a conveying roller 31, the two lifting rods 29 are respectively fixedly connected with the mounting frames 3 and are respectively located at the bottoms of the mounting frames 3, the two mounting plates 30 are respectively fixedly connected with the two lifting rods 29 and are respectively located at one side far away from the mounting frames 3, and the conveying roller 31 is rotationally connected with the two mounting frames 3 and located between the two mounting frames 3.

In this embodiment, the conveying roller 31 on the mounting plate 30 rotates on the mounting plate 30 and conveys the steel strip toward the brush 11, and the lifting rod 29 can drive the conveying roller 31 to change the distance between the steel strip and the brush 11 through the mounting plate 30 so as to adapt to the steel strip with different thickness.

According to the steel belt marking device disclosed by the invention, the mounting frame 3 of the conveying mechanism 1 provides mounting conditions for the conveying component 4 and the marking mechanism 2, the conveying component 4 is used for conveying a steel belt to the hairbrush 11 of the marking mechanism 2, the storage box 5 is used for storing the solution, the flow dividing plate 8 is used for dividing the solution in the storage box 5 from the discharge hole 9, the first motor 6 drives the rotating shaft 7 to drive the flow dividing plate 8 to rotate, the solution in the storage box 5 can be conveyed to the sponge 10 of the discharge hole 9, the sponge 10 uniformly distributes the solution on the hairbrush 11, the hairbrush 11 is used for smearing the solution on the marking component 12, the marking component 12 is used for printing the solution on the hairbrush 11 in a pattern mode, the slower the rotating speed of the first motor 6 is, the slower the speed of the solution flowing to the discharge hole 9 is, the first motor 6 is composed of the motor body and the speed reducer, the motor body is used for conveying the solution on the rotating shaft 7, and the hairbrush 11 is further clearly influenced by the fact that the pattern is printed on the hairbrush 11 is printed on the printing component 12.

The above disclosure is merely illustrative of a preferred embodiment of the steel strip marking device of the present invention, and it is not intended to limit the scope of the invention, and those skilled in the art will understand that all or part of the above embodiments may be implemented and equivalent changes may be made according to the claims of the present invention while still falling within the scope of the invention.

Claims (3)

1. The steel belt marking device is characterized by comprising a conveying mechanism (1) and a marking mechanism (2); the conveying mechanism (1) comprises a mounting frame (3) and a conveying assembly (4), wherein the conveying assembly (4) is fixedly connected with the mounting frame (3) and is positioned on the inner side wall of the mounting frame (3);

the mark printing mechanism (2) comprises a storage box (5), a first motor (6), a rotating shaft (7), a plurality of flow dividing plates (8), a sponge (10), a hairbrush (11) and an embossing assembly (12), wherein the storage box (5) is fixedly connected with the mounting frame (3) and penetrates through the mounting frame (3), the first motor (6) is fixedly connected with the storage box (5) and is positioned on the outer side wall of the storage box (5), the rotating shaft (7) is fixedly connected with the output end of the first motor (6) and penetrates through the storage box (5), the flow dividing plates (8) are respectively and fixedly connected with the rotating shaft (7) and are all positioned on the outer side wall of the rotating shaft (7), the storage box (5) is provided with a discharge hole (9), the hairbrush (11) is fixedly connected with the storage box (5) and is positioned at the position of the discharge hole (9), the hairbrush (11) is fixedly connected with the sponge (10) and is positioned on one side far away from the storage box (5), and the hairbrush assembly (12) is positioned on one side close to the embossing assembly (3) and is fixedly connected with the hairbrush (11).

The marking mechanism (2) further comprises a plurality of sealing gaskets (14), and the sealing gaskets (14) are fixedly connected with the plurality of flow dividing plates (8) respectively and are positioned at one side close to the storage box (5);

the embossing assembly (12) comprises a first support (15), a second motor (16), an embossing roller (17) and a second support (18), wherein the first support (15) is fixedly connected with the mounting frame (3) and is positioned at one side close to the storage box (5), the second motor (16) is fixedly connected with the mounting frame (3) and is positioned on the outer side wall of the mounting frame (3), the embossing roller (17) is fixedly connected with the output end of the second motor (16) and penetrates through the first support (15), the second support (18) is fixedly connected with the mounting frame (3) and is positioned at one side close to the first support (15), and the embossing roller (17) is rotationally connected with the second support (18);

the embossing assembly (12) further comprises two connecting rods (19) and a scraping plate (20), the two connecting rods (19) are fixedly connected with the first bracket (15) and the second bracket (18) respectively, and are positioned on the outer side walls of the first bracket (15) and the second bracket (18), and the scraping plate (20) is fixedly connected with the two connecting rods (19) and is positioned between the two connecting rods (19);

the embossing assembly (12) further comprises two outer cylinders (22), two inner cylinders (23), two sliding modules (24) and two damping springs (25), wherein two connecting rods (19) are respectively provided with sliding grooves (21), two outer cylinders (22) are respectively fixedly connected with the scraping plates (20) and are respectively located close to one sides of the connecting rods (19), two inner cylinders (23) are respectively connected with two outer cylinders (22) in a sliding mode and respectively penetrate through the outer cylinders (22), the two sliding modules (24) are respectively connected with two inner cylinders (23) in a fixed mode and respectively connected with one sides of the sliding grooves (21), two damping springs (25) are respectively connected with the outer cylinders (22), and the other sides of the damping springs (25) are respectively connected with the two inner cylinders (23) in a fixed mode and are respectively located in the outer cylinders (22).

2. The steel strip marking device according to claim 1, wherein the marking mechanism (2) further comprises a bearing (13), an outer ring of the bearing (13) is fixedly connected with the storage box (5), and an inner ring of the bearing (13) is fixedly connected with the rotating shaft (7) and is positioned between the storage box (5) and the rotating shaft (7).

3. The steel strip marking device according to claim 1, wherein the sliding module (24) comprises a rotating rod (26) and balls (27), the rotating rod (26) is fixedly connected with the inner cylinder (23) and is positioned on the inner side wall of the inner cylinder (23), and the balls (27) are rotatably connected with the rotating rod (26) and are positioned in the sliding groove (21).