CN209869706U - Multi-suspension-cage synchronous lifting mechanism of ceramic large-plate ink jet printer - Google Patents

Abstract

A multi-cage synchronous lifting mechanism of a ceramic large-plate ink jet machine at least comprises a cage lifting mechanism, wherein the cage lifting mechanism comprises a cage, a lifting plate, a fixing plate, a lifting assembly and a lifting driving assembly; the lifting plate is divided into a left lifting plate and a right lifting plate, and the fixed plate is divided into a left fixed plate and a right fixed plate; the left fixing plate and the right fixing plate are respectively positioned on the inner side of the left lifting plate and the inner side of the right lifting plate; two ends of the suspension cage are respectively fixed on the left lifting plate and the right lifting plate; the lifting assembly is divided into a left lifting assembly and a right lifting assembly, and the left lifting assembly and the right lifting assembly are respectively fixed on the left fixing plate and the right fixing plate; the left lifting part of the left lifting assembly is connected with the left lifting plate, and the right lifting part of the right lifting assembly is connected with the right lifting plate; the utility model provides a synchronous elevating system of many cages of pottery big board ink jet printer according to above-mentioned content can ensure that the cage can steadily rise and keep front and back end horizontal balance, highly uniform when can ensure the cage both ends lift.

Description

Multi-suspension-cage synchronous lifting mechanism of ceramic large-plate ink jet printer

Technical Field

The utility model relates to a pottery ink jet equipment field especially relates to a many cage synchronous lifting mechanism of big board ink jet machine of pottery.

Background

The cage lifting mechanism of the traditional ceramic large-plate ink jet machine is shown in the attached figure 1 of the specification, a plurality of cages are installed on the same lifting plate, an electric pole is driven by a lifting motor, and the electric pole pushes the lifting plate to enable the cages to move up and down. However, since the cage of the ceramic large plate inkjet printer requires a large printing width and a large number of heads, the span "L" of the cage is large. And follow with traditional mode, the cage only relies on the rear end to be fixed on the lifter plate and the front end lacks the support, can lead to cage front end downward sloping, influences the printing effect.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a synchronous elevating system of many cages of pottery big board ink jet printer can ensure that the cage can steadily rise and keep front and back end level balance, highly uniform when can ensure that the cage both ends go up and down.

To achieve the purpose, the utility model adopts the following technical proposal:

a multi-cage synchronous lifting mechanism of a ceramic large-plate ink jet machine at least comprises a cage lifting mechanism, wherein the cage lifting mechanism comprises a cage, a lifting plate, a fixing plate, a lifting assembly and a lifting driving assembly;

the lifting plate is divided into a left lifting plate and a right lifting plate, and the fixed plate is divided into a left fixed plate and a right fixed plate;

the left fixing plate and the right fixing plate are respectively positioned on the inner side of the left lifting plate and the inner side of the right lifting plate;

two ends of the suspension cage are respectively fixed on the left lifting plate and the right lifting plate;

the lifting assembly is divided into a left lifting assembly and a right lifting assembly, and the left lifting assembly and the right lifting assembly are respectively fixed on the left fixing plate and the right fixing plate;

the left lifting part of the left lifting assembly is connected with the left lifting plate, and the right lifting part of the right lifting assembly is connected with the right lifting plate;

the lifting driving assembly drives the left lifting portion of the left lifting assembly and the right lifting portion of the right lifting assembly to synchronously lift so as to drive the left lifting plate and the right lifting plate to synchronously lift.

Further, the left lifting assembly comprises a left lifting part, an upper bearing seat, a lower bearing seat, a lifting screw, a lifting wave box, a sliding rail and a sliding block;

the left lifting part comprises a lifting nut and a lifting nut seat, the lifting nut is arranged on the lifting nut seat, and one end of the lifting nut seat is connected with the left lifting plate;

the upper bearing seat and the lower bearing seat are respectively fixed on the inner side of the left fixing plate, the lifting screw penetrates through the upper bearing seat, the lower bearing seat, the lifting nut and the lifting nut seat, one end of the lifting screw is fixed on the upper bearing seat, and the other end of the lifting screw is fixed on the output end of the lifting wave box;

the slide rail is fixed in the outside of left fixed plate, the slider install in the slide rail, the slider still with the inboard of left lifter plate is connected.

Further, the left lifting assembly and the right lifting assembly are identical in structure.

Further, the lifting driving assembly comprises a coupler, a commutator, a lifting motor and a lifting power connecting shaft;

the lifting motor drives the commutator to work, the left end and the right end of the commutator are both provided with lifting power connecting shafts, one end of each lifting power connecting shaft is connected with the commutator through a coupler, and the other end of each lifting power connecting shaft is connected with the lifting wave box through a coupler.

Further, a plurality of cage lifting mechanisms are included;

the commutator of the lifting driving component of each cage lifting mechanism is provided with four couplings, two horizontal couplings are connected with two lifting power connecting shafts of the same cage lifting mechanism, and two longitudinal couplings are connected with the commutator of the adjacent cage lifting mechanism through the connecting shafts.

According to the above, the utility model provides a synchronous elevating system of many cages of pottery big board ink jet printer can ensure that the cage can steadily rise and keep front and back end horizontal balance, highly uniform when can ensure that the cage both ends go up and down.

Cage elevating system is applied to ceramic big board ink jet printer, and it is big that ceramic big board ink jet printer requires to print the width, and the shower nozzle of loading is in large quantity, because the both ends of cage are fixed in respectively the inboard of left lifter plate and right lifter plate, consequently the both ends of cage are by supporting, make when left side lifter plate and right lifter plate go up and down in step, so the cage can steadily rise and keep front and back end horizontal balance, highly uniform when can guaranteeing the cage both ends lift, avoids the one end downward sloping of cage, can guarantee that the operating condition of cage is stable to guarantee to print the good of effect.

Drawings

FIG. 1 is a schematic structural diagram of a conventional cage lifting mechanism;

FIG. 2 is a schematic structural diagram of one embodiment of the present invention;

fig. 3 is a partial enlarged view at a of fig. 2;

fig. 4 is a partial schematic view of one embodiment of the present invention.

Wherein: the lifting cage comprises a lifting cage lifting mechanism 101, a lifting cage 1, a left lifting plate 21, a right lifting plate 22, a left fixing plate 31, a right fixing plate 32, a left lifting assembly 41, a left lifting part 411, a lifting nut 4111, a lifting nut base 4112, an upper bearing base 412, a lower bearing base 413, a lifting screw 414, a lifting bellows 415, a slide rail 416, a slide block 417, a right lifting assembly 42, a right lifting part 421, a lifting driving assembly 5, a coupler 51, a commutator 52, a lifting motor 53 and a lifting power connecting shaft 54.

Detailed Description

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

As shown in fig. 1-4, the multi-cage synchronous lifting mechanism of the ceramic large-plate inkjet printer at least comprises a cage lifting mechanism 101, wherein the cage lifting mechanism 101 comprises a cage 1, a lifting plate, a fixing plate, a lifting assembly and a lifting driving assembly 5;

the lifting plate is divided into a left lifting plate 21 and a right lifting plate 22, and the fixing plate is divided into a left fixing plate 31 and a right fixing plate 32;

the left fixing plate 31 and the right fixing plate 32 are respectively positioned on the inner side of the left lifting plate 21 and the inner side of the right lifting plate 22;

two ends of the suspension cage 1 are respectively fixed on the left lifting plate 21 and the right lifting plate 22;

the lifting assembly is divided into a left lifting assembly 41 and a right lifting assembly 42, and the left lifting assembly 41 and the right lifting assembly 42 are respectively fixed on the left fixing plate 31 and the right fixing plate 32;

the left lifting part 411 of the left lifting assembly 41 is connected with the left lifting plate 21, and the right lifting part 421 of the right lifting assembly 42 is connected with the right lifting plate 22;

the lifting driving assembly 5 drives the left lifting part 411 of the left lifting assembly 41 and the right lifting part 421 of the right lifting assembly 42 to synchronously lift so as to drive the left lifting plate 21 and the right lifting plate 22 to synchronously lift.

The cage elevating system of this embodiment is applied to ceramic big board ink jet printer, and it is big that ceramic big board ink jet printer requires to print the width, and the shower nozzle of loading is in large quantity, because the both ends of cage 1 are fixed in respectively left lifter plate 21 and right lifter plate 22's inboard, consequently the both ends of cage 1 are by supporting, make when left lifter plate 21 and right lifter plate 22 go up and down in step, so cage 1 can steadily rise and keep front and back end level balance, and highly uniform when can guaranteeing the cage both ends lift avoids the one end downward sloping of cage 1, can guarantee that cage 1's operating condition is stable to the assurance prints the good of effect.

Further, the left lifting assembly 41 comprises a left lifting part 411, an upper bearing seat 412, a lower bearing seat 413, a lifting screw 414, a lifting bellows 415, a slide rail 416 and a slide block 417;

the left lifting part 411 comprises a lifting nut 4111 and a lifting nut base 4112, the lifting nut 4111 is arranged on the lifting nut base 4112, and one end of the lifting nut base 4112 is connected with the left lifting plate 21;

the upper bearing seat 412 and the lower bearing seat 413 are respectively fixed on the inner side of the left fixing plate 31, the lifting screw 414 passes through the upper bearing seat 412, the lower bearing seat 413, the lifting nut 4111 and the lifting nut seat 4112, one end of the lifting screw 414 is fixed on the upper bearing seat 412, and the other end of the lifting screw 414 is fixed on the output end of the lifting bellows 415;

the slide rail 416 is fixed to the outer side of the left fixing plate 31, the slide block 417 is mounted on the slide rail 416, and the slide block 417 is further connected to the inner side of the left lifting plate 21.

The lifting screw 414 is driven by the lifting wave box 415 to rotate, the lifting nut 4111 drives the lifting nut base 4112 to move up and down, so that the left lifting plate 21 is driven to move up and down, and the left lifting plate 21 is more stable when moving up and down under the matching of the sliding rail 416 and the sliding block 417; similarly, because the left lifting assembly 41 and the right lifting assembly 42 have the same structure and are installed in the same manner, the lifting of the right lifting plate 22 and the lifting of the left lifting plate 21 are synchronous, so that the heights of the two ends of the suspension cage 1 can be ensured to be the same when lifting.

Further, the left lifting assembly 41 and the right lifting assembly 42 have the same structure.

Further, the lifting driving assembly 5 comprises a coupler 51, a commutator 52, a lifting motor 53 and a lifting power connecting shaft 54;

the lifting motor 53 drives the commutator 52 to work, the left end and the right end of the commutator 52 are both provided with lifting power connecting shafts 54, one end of each lifting power connecting shaft 54 is connected with the commutator 52 through a coupler 51, and the other end of each lifting power connecting shaft 54 is connected with the lifting wave box 415 through the coupler 51.

The lifting motor 53 is a servo motor, the lifting motor 53 drives the lifting power connecting shaft 54 to rotate through the commutator 52, the lifting power connecting shaft 54 drives the lifting wave box 415 to work, and the lifting wave box 415 drives the lifting screw 414 to rotate, so that the lifting nut 4111 drives the lifting nut base 4112 to move up and down.

Further, a plurality of cage lifting mechanisms 101 are included;

the commutator 52 of the lifting driving assembly 5 of each cage lifting mechanism 101 is provided with four couplings 51, two horizontal couplings 51 are connected with two lifting power connecting shafts 54 of the same cage lifting mechanism 101, and two longitudinal couplings 51 are connected with the commutator 52 of the adjacent cage lifting mechanism 101 through the connecting shafts.

In this embodiment, four cage lifting mechanisms 101 are provided, and the lifting power connecting shafts 54 rotate at the same speed by uniformly driving the plurality of commutators 52 by the lifting motor 53, so as to achieve the effect of synchronous lifting and consistent height of the cages 1. And because the servo motor has the advantage of high control accuracy, the lifting height of the suspension cage 1 can be accurately controlled.

The technical principle of the present invention is described above with reference to specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without any inventive effort, which would fall within the scope of the present invention.

Claims (5)

1. The utility model provides a many cage synchronous lifting mechanism of big board ink jet printer of pottery which characterized in that: the lifting cage lifting mechanism comprises a lifting cage, a lifting plate, a fixing plate, a lifting assembly and a lifting driving assembly;

the lifting plate is divided into a left lifting plate and a right lifting plate, and the fixed plate is divided into a left fixed plate and a right fixed plate;

the left fixing plate and the right fixing plate are respectively positioned on the inner side of the left lifting plate and the inner side of the right lifting plate;

two ends of the suspension cage are respectively fixed on the left lifting plate and the right lifting plate;

the lifting assembly is divided into a left lifting assembly and a right lifting assembly, and the left lifting assembly and the right lifting assembly are respectively fixed on the left fixing plate and the right fixing plate;

the left lifting part of the left lifting assembly is connected with the left lifting plate, and the right lifting part of the right lifting assembly is connected with the right lifting plate;

the lifting driving assembly drives the left lifting portion of the left lifting assembly and the right lifting portion of the right lifting assembly to synchronously lift so as to drive the left lifting plate and the right lifting plate to synchronously lift.

2. The multi-cage synchronous lifting mechanism of the ceramic large plate ink jet machine as claimed in claim 1, wherein: the left lifting assembly comprises a left lifting part, an upper bearing seat, a lower bearing seat, a lifting screw rod, a lifting wave box, a sliding rail and a sliding block;

the left lifting part comprises a lifting nut and a lifting nut seat, the lifting nut is arranged on the lifting nut seat, and one end of the lifting nut seat is connected with the left lifting plate;

the upper bearing seat and the lower bearing seat are respectively fixed on the inner side of the left fixing plate, the lifting screw penetrates through the upper bearing seat, the lower bearing seat, the lifting nut and the lifting nut seat, one end of the lifting screw is fixed on the upper bearing seat, and the other end of the lifting screw is fixed on the output end of the lifting wave box;

the slide rail is fixed in the outside of left fixed plate, the slider install in the slide rail, the slider still with the inboard of left lifter plate is connected.

3. The multi-cage synchronous lifting mechanism of the ceramic large plate ink jet machine as claimed in claim 1, wherein: the left lifting assembly and the right lifting assembly are identical in structure.

4. The multi-cage synchronous lifting mechanism of the ceramic large plate ink jet machine as claimed in claim 2, wherein: the lifting driving assembly comprises a coupler, a commutator, a lifting motor and a lifting power connecting shaft;

the lifting motor drives the commutator to work, the left end and the right end of the commutator are both provided with lifting power connecting shafts, one end of each lifting power connecting shaft is connected with the commutator through a coupler, and the other end of each lifting power connecting shaft is connected with the lifting wave box through a coupler.

5. The multi-cage synchronous lifting mechanism of the ceramic large plate ink jet machine as claimed in claim 4, wherein: comprises a plurality of cage lifting mechanisms;

the commutator of the lifting driving component of each cage lifting mechanism is provided with four couplings, two horizontal couplings are connected with two lifting power connecting shafts of the same cage lifting mechanism, and two longitudinal couplings are connected with the commutator of the adjacent cage lifting mechanism through the connecting shafts.