CN215321544U - Synchronous driving structure of high-speed ink-jet type net making machine - Google Patents

Abstract

The utility model provides a synchronous driving structure of a high-speed ink-jet type net making machine, belonging to the field of ink jet. The novel steel wire rope support comprises a frame, wherein two sides of the frame are respectively provided with a transverse moving motor, an output shaft of each transverse moving motor is provided with a lead screw which is rotatably connected with the frame, the two lead screws are parallel, the frame is connected with two supporting blocks in a sliding mode, each supporting block is provided with a screw sleeve, the two screw sleeves are respectively screwed on the two lead screws, and a main beam is connected between the two supporting blocks. The ink jet device has the advantages that the two transverse moving motors work simultaneously, so that the two supporting blocks move synchronously, and the influence of asynchronous stride on ink jet precision is prevented.

Description

Synchronous driving structure of high-speed ink-jet type net making machine

Technical Field

The utility model belongs to the field of ink jet, and particularly relates to a synchronous driving structure of a high-speed ink jet type net making machine.

Background

In the ink jetting process, the ink jetting device continuously reciprocates on a cross bar and performs ink jetting work, and the cross bar reciprocates on the frame, so that the position of the ink jetting device is continuously moved from the X-axis direction and the Y-axis direction to perform ink jetting work. In the prior art, in order to save cost, a driver is usually connected to one end of the cross bar to move the cross bar, but due to the length of the cross bar, in the process of moving the cross bar, the other end of the cross bar is not connected with the driver, so that the ink jet precision caused by the fact that the cross bar is inclined in the moving process is not high enough.

For example, chinese patent literature discloses an inkjet printing method and apparatus using radiation curable ink [ patent application No.: CN1826230A ], the apparatus comprising a sensor for detecting the amount of radiation emitted by the radiation source. A controller is connected to the sensor and is operable to vary the amount of radiation emitted by the radiation source in accordance with a signal received from the sensor. A drive mechanism moves the radiation source to a position at which the sensor is disposed, the position being laterally offset relative to the substrate.

Disclosure of Invention

The utility model aims to solve the problems and provides a synchronous driving structure of a high-speed ink-jet type net making machine.

In order to achieve the purpose, the utility model adopts the following technical scheme:

the synchronous driving structure of the high-speed ink-jet type net making machine comprises a frame, wherein two sides of the frame are respectively provided with a transverse moving motor, an output shaft of each transverse moving motor is provided with a lead screw which is connected with the frame in a rotating mode, the two lead screws are parallel, the frame is connected with two supporting blocks in a sliding mode, each supporting block is provided with a wire sleeve, the two wire sleeves are respectively screwed on the two lead screws, and a main beam is connected between the two supporting blocks.

In the synchronous driving structure of the high-speed ink-jet type screen making machine, the frame is further provided with two guide rails which are arranged in parallel with the screw rod, and the two support blocks respectively slide on the two guide rails.

In the above synchronous driving structure of the high-speed ink-jet type screen making machine, the frame is further provided with a plurality of reinforcing rods.

In foretell high-speed inkjet formula net making machine's synchronous drive structure, still erect the auxiliary girder on two supporting shoes, girder and auxiliary girder between have the clearance and form the sliding channel, sliding channel sliding connection have a plurality of slide, slide and auxiliary girder sliding connection, and each slide supports on the girder through detachable latch mechanism.

In the synchronous driving structure of the high-speed ink-jet type net making machine, the auxiliary beam is at least provided with an auxiliary beam guide groove, the sliding plate is provided with a plurality of auxiliary beam guide blocks matched with the auxiliary beam guide grooves, and the auxiliary beam guide blocks extend into the corresponding auxiliary beam guide grooves and are in sliding connection with the auxiliary beam guide grooves.

In foretell synchronous drive structure of high-speed inkjet formula net making machine, detachable latch mechanism including sliding the backup pad on the girder, the slide on slide and wear to be equipped with a plurality of fixing bolt, fixing bolt and backup pad spiro union.

In foretell synchronous drive structure of high-speed inkjet formula net making machine, the girder be equipped with a plurality of girder spouts, detachable latch mechanism include the girder slider that a plurality of slided respectively in the girder spout, the girder slider set firmly in the backup pad, the notch department of each girder spout is equipped with two and supports the strip.

In the synchronous driving structure of the high-speed ink-jet type net making machine, the top of each supporting block is provided with a supporting plate, the two supporting plates are arranged in an opposite mode, and the main beam and the auxiliary beam are respectively abutted against two side faces of the supporting plates.

In the synchronous driving structure of the high-speed ink-jet type net making machine, the supporting plate is fixedly connected with the auxiliary beam, and the supporting plate is detachably connected with the main beam.

In the synchronous driving structure of the high-speed ink-jet type net making machine, the two sides of the secondary beam are respectively provided with a plurality of fixing holes formed in the supporting plate, the main beam sliding groove is connected with a plurality of fixing sliding blocks in a sliding mode, each fixing sliding block is fixedly provided with a screw rod, the screw rods penetrate through the notches of the main beam sliding groove and the corresponding fixing holes, and the screw rods are further connected with nuts abutted to the supporting plate in a threaded mode.

Compared with the prior art, the utility model has the advantages that:

1. the two transverse moving motors work simultaneously, so that the two supporting blocks move synchronously, and the influence of asynchronous stride on ink jet precision is prevented.

2. According to the utility model, the sliding plate is supported on the main beam in a sliding manner through the detachable clamping mechanism and slides in the auxiliary beam, so that the main beam is bent under the action of gravity in the long-term use process, the sliding plate can be inclined in the moving process, the inclined sliding plate can be clamped on the auxiliary beam to cause noise or speed reduction, and even can be directly clamped on the auxiliary beam, and a worker can be prompted that the main beam for bearing is bent, so that the main beam can be replaced. Thereby ensuring high ink-jet precision.

Drawings

FIG. 1 is a general schematic of the present invention;

FIG. 2 is a schematic view of FIG. 1 in another orientation;

FIG. 3 is a schematic top view of the hidden frame of FIG. 1;

FIG. 4 is a schematic cross-sectional view A-A of FIG. 3;

fig. 5 is a schematic cross-sectional view of B-B in fig. 3.

In the figure: the device comprises a support block 40, a main beam 41, a secondary beam 42, a sliding channel 43, a sliding plate 44, a detachable clamping mechanism 45, a secondary beam guide groove 46, a secondary beam guide block 47, a support plate 48, a fixing bolt 49, a main beam sliding groove 50, a resisting strip 51, a resisting plate 52, a fixing hole 53, a fixing slide block 54, a screw 55, a nut 56, a main beam slide block 57, a frame 60, a transverse moving motor 61, a screw rod 62, a screw sleeve 63, a guide rail 64 and a reinforcing rod 65.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1-5, a synchronous driving structure of a high-speed inkjet screen making machine includes a frame 60, two lateral moving motors 61 are respectively disposed on two sides of the frame 60, a lead screw 62 rotatably connected to the frame 60 is disposed on an output shaft of the lateral moving motor 61, the two lead screws 62 are parallel, two support blocks 40 are slidably connected to the frame 60, each support block 40 is provided with a thread sleeve 63, the two thread sleeves 63 are respectively screwed to the two lead screws 62, and a main beam 41 is connected between the two support blocks 40.

In this embodiment, the main beam 41 is used to support the ink ejection device, and the ink ejection device slides on the main beam 41 during operation. During the ink jetting process, the two support blocks 40 slide on the frame 60, thereby bringing the main beams 41 to slide on the frame 60. In the sliding process of the supporting block 40, the lead screw 62 is rotated by the operation of the transverse moving motor 61, so that the supporting block 40 is driven by the screw sleeve 63 to move through the screw connection, and the two transverse moving motors 61 work simultaneously, so that the two supporting blocks 40 move synchronously, and the influence of asynchronous stride on the ink jet precision is prevented.

The frame 60 is further provided with two guide rails 64 parallel to the screw 62, and the two support blocks 40 slide on the two guide rails 64 respectively.

In this embodiment, the supporting blocks 40 slide on the guide rails 64, and the guide rails 64 limit the moving direction of the supporting blocks 40, so that the two supporting blocks 40 always move in parallel, thereby further preventing the asynchronous stride from affecting the ink jetting precision.

The frame 60 is further provided with a plurality of reinforcing rods 65.

In this embodiment, the main beam 41 supports a plurality of ink jet devices thereon, and a plurality of reinforcing bars 65 reinforce the frame 60.

The two supporting blocks 40 are further provided with auxiliary beams 42, gaps are formed between the main beams 41 and the auxiliary beams 42 to form sliding channels 43, a plurality of sliding plates 44 are connected in the sliding channels 43 in a sliding mode, the sliding plates 44 are connected with the auxiliary beams 42 in a sliding mode, and each sliding plate 44 is supported on the main beam 41 through a detachable clamping mechanism 45.

In this embodiment, the main beam 41 and the sub beam 42 are arranged in parallel, the sliding plate 44 slides in the sliding channel 43, the ink jet device is arranged on the sliding plate 44, because the sliding plate 44 is slidably supported on the main beam 41 through the detachable clamping mechanism 45 and slides in the sub beam 42, in the process of long-term use, the main beam 41 bends under the action of gravity, so that the sliding plate 44 tilts in the moving process, and the tilted sliding plate 44 can be clamped on the sub beam 42 to cause noise or speed reduction, even directly clamped on the sub beam 42, so that a worker can be prompted that the main beam 41 for bearing bends, thereby replacing the main beam 41. In the replacement process, the slide plate 44 is detached from the main beam 41 through the detachable clamping mechanism 45 so as to replace the main beam 41, thereby ensuring high ink-jet precision.

The auxiliary beam 42 is provided with at least one auxiliary beam guide groove 46, the sliding plate 44 is provided with a plurality of auxiliary beam guide blocks 47 matched with the auxiliary beam guide grooves 46, and the auxiliary beam guide blocks 47 extend into the corresponding auxiliary beam guide grooves 46 and are in sliding connection with the auxiliary beam guide grooves 46.

In this embodiment, after the main beam 41 is bent due to long-term load-bearing, the secondary beam guide block 47 moving obliquely rubs against the upper and lower inner walls of the secondary beam guide groove 46, resulting in noise generation or speed reduction, and even directly seizes on the secondary beam 42. And because the sliding plate 44 slides in the plurality of auxiliary beam guide grooves 46 through the plurality of auxiliary beam guide blocks 47, once the sliding plate 44 tilts and moves, the plurality of auxiliary beam guide blocks 47 and the plurality of auxiliary beam guide grooves 46 rub with each other, so that the generated friction force is large, the phenomenon is obvious, and the bending of the main beam 41 can be found in time and the main beam 41 can be replaced.

Detachable latch mechanism 45 including sliding in the backup pad 48 on girder 41, slide 44 on slide and wear to be equipped with a plurality of fixing bolt 49, fixing bolt 49 and backup pad 48 spiro union.

In this embodiment, the fixing bolt 49 is screwed into the supporting plate 48, so that the head of the fixing bolt 49 abuts against the sliding plate 44 to fix the sliding plate 44 on the supporting plate 48, and the fixing bolt 49 is screwed out during disassembly, thereby facilitating disassembly and assembly.

In addition, it is preferable that the thickness of the main beam 41 is greater than that of the sub beam 42, and a plurality of fixing bolts 49 are respectively located on both sides of the sub beam 42.

In this embodiment, the fixing bolts 49 are provided on both sides of the sub-beam 42, and a screwdriver can directly operate the fixing bolts 49, which is more convenient.

The main beam 41 is provided with a plurality of main beam sliding grooves 50, the detachable clamping mechanism 45 comprises a plurality of main beam sliding blocks 57 which respectively slide in the main beam sliding grooves 50, the main beam sliding blocks 57 are fixedly arranged on the supporting plate 48, and two supporting strips 51 are arranged at the notch of each main beam sliding groove 50.

In this embodiment, when the main beam 41 bends, the main beam sliding block 57 will rub against the upper and lower inner walls of the main beam sliding groove 50 and the bottom strip 51, further causing noise or speed reduction, or even directly locking.

The top of each supporting block 40 is provided with a resisting plate 52, the two resisting plates 52 are arranged oppositely, and the main beam 41 and the secondary beam 42 are respectively resisted against two sides of the resisting plate 52.

In this embodiment, the main beam 41 completely abuts against the two abutting plates 52 at the same time, and the secondary beam 42 simultaneously abuts against the two abutting plates 52 at the same time, so as to ensure that the remaining secondary beams 42 of the main beam 41 are arranged in parallel. Ensuring the ink jetting precision.

The support plate 52 is fixedly connected with the secondary beam 42, and the support plate 52 is detachably connected with the main beam 41.

In this embodiment, when the main beam 41 is bent, the main beam 41 can be detached from the butt plate 52 for replacement.

The two sides of the secondary beam 42 are respectively provided with a plurality of fixing holes 53 arranged on the abutting plate 52, the main beam sliding groove 50 is connected with a plurality of fixing sliding blocks 54 in a sliding manner, each fixing sliding block 54 is fixedly provided with a screw 55, the screw 55 penetrates through the notch of the main beam sliding groove 50 and the corresponding fixing hole 53, and the screw 55 is further screwed with a nut 56 abutting against the abutting plate 52.

In this embodiment, when replacing the main beam 41, the nut 56 is unscrewed to detach the main beam 41 from the butt plate 52. In addition, several fixing holes 53 are formed on both sides of the sub-beam 42 to allow easy and direct operation, and the screw 55 and the fixing block 54 can be directly slid out of the main beam slide groove 50 to be disconnected from the main beam 41.

The working principle of the utility model is as follows: during the ink jetting process, the two support blocks 40 slide on the frame 60, thereby bringing the main beams 41 to slide on the frame 60. In the sliding process of the supporting block 40, the lead screw 62 is rotated by the operation of the traverse motors 61, so that the wire sleeve 63 carries the supporting block 40 to move by screwing, and the two traverse motors 61 simultaneously operate to enable the two supporting blocks 40 to synchronously move.

The main beam 41 and the auxiliary beam 42 are arranged in parallel, the sliding plate 44 slides in the sliding channel 43, the ink jet device is arranged on the sliding plate 44, the auxiliary beam guide block 47 slides in the auxiliary beam guide groove 46 and the main beam sliding block 57 slides in the main beam sliding groove 50, the main beam 41 bends under the action of gravity in the long-term use process, the sliding plate 44 tilts in the moving process, the obliquely moving sliding plate 44 can cause large friction force between the auxiliary beam guide block 47 and the auxiliary beam guide groove 46, and the main beam sliding block 57 and the main beam sliding groove 50 generate large friction force, so that noise is generated or the speed is reduced, even the main beam 41 is directly clamped, and workers can be prompted that the main beam 41 for bearing is bent, so that the main beam 41 is replaced.

During the replacement of the main beam 41, the fixing bolt 49 is unscrewed and the nut 56 is unscrewed, thereby disconnecting the main beam 41 from the butt plate 52 and the slide plate 44.

The specific embodiments described herein are merely illustrative of the spirit of the utility model. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the utility model as defined in the appended claims.

Although the support block 40, the main beam 41, the sub beam 42, the slide passage 43, the slide plate 44, the detachable clamping mechanism 45, the sub beam guide groove 46, the sub beam guide block 47, the support plate 48, the fixing bolt 49, the main beam slide groove 50, the abutting strip 51, the abutting plate 52, the fixing hole 53, the fixing slider 54, the screw 55, the nut 56, the main beam slider 57, the frame 60, the traverse motor 61, the screw 62, the wire sleeve 63, the guide rail 64, the reinforcing bar 65, etc., are more used herein, these terms are used only for the convenience of describing and explaining the essence of the present invention; they are to be construed as being without limitation to any additional limitations that may be imposed by the spirit of the present invention.

Claims (10)

1. The utility model provides a synchronous drive structure of high-speed inkjet formula net making machine, includes frame (60), its characterized in that, the both sides of frame (60) respectively be equipped with a sideslip motor (61), the output shaft of sideslip motor (61) on be equipped with lead screw (62) of being connected with frame (60) rotation, two lead screw (62) are parallel form, frame (60) on sliding connection have two supporting shoe (40), be equipped with silk braid (63) on each supporting shoe (40), two silk braid (63) spiro union are respectively on two lead screw (62), be connected with girder (41) between two supporting shoe (40).

2. A synchronous drive arrangement for a high speed inkjet web-making machine according to claim 1, wherein the frame (60) is further provided with two guide rails (64) arranged parallel to the screw (62), and the two support blocks (40) slide on the two guide rails (64), respectively.

3. A synchronous drive arrangement for a high-speed inkjet web-making machine according to claim 2, characterized in that the frame (60) is further provided with a plurality of reinforcement bars (65).

4. A synchronous driving structure of a high-speed inkjet net making machine according to claim 3, wherein a secondary beam (42) is further erected on the two supporting blocks (40), a gap is formed between the primary beam (41) and the secondary beam (42) to form a sliding channel (43), a plurality of sliding plates (44) are slidably connected in the sliding channel (43), the sliding plates (44) are slidably connected with the secondary beam (42), and each sliding plate (44) is supported on the primary beam (41) through a detachable clamping mechanism (45).

5. A synchronous drive structure of a high-speed ink-jet net making machine according to claim 4, characterized in that the secondary beam (42) is provided with at least one secondary beam guide groove (46), the slide plate (44) is provided with a plurality of secondary beam guide blocks (47) matched with the secondary beam guide grooves (46), and the secondary beam guide blocks (47) extend into the corresponding secondary beam guide grooves (46) and are connected with the secondary beam guide grooves (46) in a sliding manner.

6. The synchronous driving structure of a high-speed inkjet net making machine according to claim 5, wherein the detachable clamping mechanism (45) comprises a support plate (48) sliding on the main beam (41), a plurality of fixing bolts (49) are slidably arranged on the sliding plate (44) in a penetrating manner, and the fixing bolts (49) are in threaded connection with the support plate (48).

7. The synchronous driving structure of a high-speed inkjet net making machine according to claim 6, wherein the main beam (41) is provided with a plurality of main beam sliding grooves (50), the detachable clamping mechanism (45) comprises a plurality of main beam sliding blocks (57) which respectively slide in the main beam sliding grooves (50), the main beam sliding blocks (57) are fixedly arranged on the supporting plate (48), and two abutting strips (51) are arranged at the notch of each main beam sliding groove (50).

8. The synchronous driving structure of a high-speed inkjet net making machine according to claim 7, wherein a butt plate (52) is provided at the top of each supporting block (40), the two butt plates (52) are disposed oppositely, and the main beam (41) and the sub-beam (42) are respectively abutted against two sides of the butt plate (52).

9. The synchronous driving structure of a high-speed inkjet net making machine according to claim 8, wherein the supporting plate (52) is fixedly connected with the secondary beam (42), and the supporting plate (52) is detachably connected with the primary beam (41).

10. The synchronous driving structure of a high-speed inkjet net making machine according to claim 9, wherein two sides of the secondary beam (42) are respectively provided with a plurality of fixing holes (53) arranged on the abutting plate (52), the main beam sliding chute (50) is connected with a plurality of fixing sliding blocks (54) in a sliding manner, each fixing sliding block (54) is fixedly provided with a screw rod (55), the screw rod (55) penetrates through a notch of the main beam sliding chute (50) and the corresponding fixing hole (53), and the screw rod (55) is further screwed with a nut (56) abutting against the abutting plate (52).

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