CN219600548U - Edge-covering deviation correcting device for side wing leather shell - Google Patents

Abstract

The utility model relates to the technical field of printing and packaging equipment, in particular to a deviation correcting device for edge covering of a lateral wing leather shell; the utility model comprises a mounting rack, a sliding rail, a sliding block, a mounting seat, a motor and a belt, wherein the mounting rack is arranged on the sliding rail in a sliding way; according to the utility model, the motor drives the belt to drive the sliding block to move along the sliding rail, so that the angle between the mounting frame and the sliding block can be adjusted, the deviation correcting effect is realized, the gray plate can still be accurately sucked and placed on the leather shell when the position of the leather shell deviates, the product pasting precision is ensured, and meanwhile, the production efficiency is high.

Description

Edge-covering deviation correcting device for side wing leather shell

Technical Field

The utility model relates to the technical field of printing and packaging equipment, in particular to a deviation correcting device for edge covering of a lateral wing leather shell.

Background

With the development of the age, the packaging box is widely applied to the life of people. The presence of a folded box, relative to a common box type in general, is due to the fact that it has: easy storage, low logistics and transportation cost, free folding, repeated use, environmental protection and the like. The finished folding carton is generally made up of a leather shell plus two side flaps. Therefore, the side flap skin packaging is particularly important.

The wing skin has been produced for a long time in the past from purely manual production to semi-automated man-machine bonding to recent machine production. The existing machine is generally used as a shell machine, and transfer debugging is carried out on the basis of the shell machine. According to the size debugging, the glue is coated on a cover table, paper is pushed, the long and short sides are wrapped in a cross-shaped wrapping mode after an aircraft head ash suction plate is arranged, and then the aircraft head ash suction plate is pulled out by a pulling gun, compacted by two sections of rollers, defoamed and molded.

Disadvantages of existing machines:

(1) When the existing leather shell machine is used for making the side wing leather shell, the plate transfer and the edge covering knife replacement are needed, so that the labor cost and the time cost are increased. Meanwhile, the procedures of the ash placing plate, the long edge wrapping, the short edge wrapping and the like are all carried out at the same station, so that the time cost is further increased, and the production speed and the production efficiency of the lateral wing leather shell are reduced.

(2) In the process of making the side wings, if the cover is slightly askew in the processes of cover pulling and glue passing, the precision of the finished product finally obtained is affected.

(3) And according to the size of the lateral wing leather shell, a corresponding machine head mould is needed to be manufactured before the leather shell is manufactured. In order to prevent the cover from moving in the process of wrapping the shell, a bottom table die with a suction nozzle is also needed, so that the cost is increased.

Accordingly, based on the above-described drawbacks of the existing hemming devices, improvements to the existing hemming devices are needed.

Disclosure of Invention

The utility model aims to provide a side wing leather shell edge-covering deviation correcting device which solves the problems of the existing edge-covering equipment and aims to overcome the defects of the prior art: the leather shell may have defects such as skew affecting the precision of the finished product.

In order to achieve the above object, the present utility model is achieved by the following technical scheme.

The utility model provides a flank leather shell correction device that bordures, includes mounting bracket, slide rail, slider, mount pad, motor, belt, and the mounting bracket slides and locates on the slide rail, and the slide rail is slided and is equipped with the slider, has the mount pad on the mounting bracket, and the mount pad is articulated with the slider, and the belt is connected to the slider, motor drive belt.

Further, a plurality of mobile suction nozzles are arranged on the mounting frame. The plasterboard is sucked up by the mobile suction nozzle and placed onto the crust.

Further, the motor is arranged at one end of the sliding rail, and the belt is positioned on the side face of the sliding rail. The motor drives the belt and then pulls the sliding block to move.

Further, each sliding rail is provided with a motor and a belt. The sliding blocks can be controlled to move along the sliding rails respectively, and angles between two ends of the mounting frame and the sliding blocks can be controlled respectively.

Further, the front end of mounting bracket install the fixed slot, fixed slot movable mounting dead lever, the lower extreme of dead lever has the mounting panel, has seted up the mounting groove on the mounting panel, the mobile suction nozzle is installed in the mounting groove. Can be suitable for shells of various sizes

Further, the fixed slot is horizontally arranged, and the fixed rod is vertically arranged. The ash plate is conveniently sucked.

Further, the motor is externally connected with a control system, and the control system is connected with a camera. The position data is captured by the camera to provide information to the control system to control the motor.

Further, the sliding rail and the camera are arranged above the first conveyor belt. The camera is used to take a picture of the position of the skin on the first conveyor.

The utility model has the beneficial effects that: the motor drives the belt to drive the sliding block to move along the sliding rail, so that the angle between the mounting frame and the sliding block can be adjusted, the deviation rectifying effect is realized, the gray plate can still be accurately sucked and placed on the leather shell when the position of the leather shell deviates, the product pasting precision is ensured, and meanwhile, the production efficiency is high.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a schematic structural view of the present utility model and a push plate portion.

Fig. 3 is a schematic structural diagram of an edge covering device applied to the present utility model.

Fig. 4 is a schematic structural view of a hemming portion to which the present utility model is applied.

Fig. 5 is a partial schematic view of fig. 4.

Reference numerals and description:

a first conveyor belt 1, a clamping block 11 and a pressing plate 12;

a cover gluing machine 2;

the pushing plate part 3, the middle plate track 30, the side plate longitudinal conveying belt 31 and the side plate transverse conveying belt 32;

the mobile suction nozzle rack 4, the mounting rack 40, the mobile suction nozzle 41, the sliding rail 42, the sliding block 43, the mounting seat 44, the motor 45, the belt 46, the fixing groove 47, the fixing rod 48 and the mounting plate 49;

the edge covering part 5, the first edge covering suction nozzle 50, the second edge covering suction nozzle 51, the first edge covering station 52, the side brush 53, the second edge covering station 54, the front brush 55, the rear brush 56, the edge covering output conveyor belt 57, the press roller assembly 58 and the guide plate 59;

a second conveyor belt 6;

a third conveyor belt 7;

a discharge table 8;

and a receiving conveyor belt 9.

Detailed Description

The utility model is further described below with reference to the accompanying drawings.

Referring to fig. 1-3, the side wing leather shell edge-covering deviation correcting device of the utility model comprises: the device comprises a first conveyor belt 1, a cover laminator 2, a push plate part 3, a mobile suction nozzle frame 4, a binding part 5, a second conveyor belt 6, a third conveyor belt 7 and a discharging table 8.

The cover laminator 2 is positioned at one end of the first conveyor belt 1, and the cover laminator 2 is used for laminating leather shells, so that the leather shells are provided with glue for adhering ash plates.

The push plate part 3 of the present utility model is located at one side of the middle of the first conveyor 1 for feeding the gray plate to a designated position. The mobile suction nozzle holder 4 is movably located above the push plate part 3 and the first conveyor belt 1 for sucking and placing the ash plate from a designated position onto the leather sheath located on the first conveyor belt 1.

The wrapping portion 5 of the present utility model is located at the other end of the first conveyor 1 for wrapping the transferred leather sheath. To save space, the second conveyor belt 6 is located below the edge covering section 5 for transporting the leather sheath, the third conveyor belt 7 is located at the output end of the second conveyor belt 6, and the discharge table 8 is located at the output end of the third conveyor belt 7.

The first conveyor belt 1 is provided with a movable clamping block 11, the moving direction of the clamping block 11 is perpendicular to the moving direction of the first conveyor belt 1, and the clamping block 11 is used for pulling the leather shell from the cover laminator 2 to the first conveyor belt 1.

The first conveyor belt 1 is provided with a plurality of ventilation holes, and the air suction state is kept under the first conveyor belt 1 all the time in the conveying process, so that the leather shell can be adsorbed all the time, and the position is prevented from running.

Referring to fig. 1, the mobile suction nozzle rack 4 of the present utility model includes a mounting frame 40, a mobile suction nozzle 41, a slide rail 42, a slider 43, a mounting base 44, a motor 45, and a belt 46. A plurality of mobile suction nozzles 41 are mounted on the mounting frame 40 for sucking up the dust plate. The mounting frame 40 is slidably disposed on the sliding rail 42, the mounting frame 40 moves along the sliding rail 42, and the sliding rail 42 is located above the first conveyor belt 1 and perpendicular to the moving direction of the first conveyor belt 1. The slide rail 42 is provided with a slide block 43 in a sliding manner, the mounting frame 40 is provided with a mounting seat 44, and the mounting seat 44 is pivoted with the slide block 43. The slider 43 is connected to the belt 46, and the motor 45 drives the belt 46. The motor 45 is mounted at one end of the rail 42 and the belt 46 is located at the side of the rail. Each slide rail 42 is fitted with a motor 45, a belt 46 so that both slides 43 can be pulled and rotated with the mounting 40.

The motor 45 drives the belt 46 to drive the mounting frame 40 to move, so that the mobile suction nozzle 41 sucks the ash plate and places the ash plate on the leather shell on the first conveyor belt 1. A camera may be arranged above the first conveyor belt 1 to take a picture of the position of the leather sheath, and the motor 45 is externally connected with a control system, and the control system is connected with the camera. If the position of the shell is deviated, the motor 45 can be controlled to rotate the mounting frame 40 and the sliding block 43 according to error data given by the camera, so that the deviation rectifying effect is realized, the unexpected error caused by the machine in the working process is solved, and the wing shell with higher quality is produced more rapidly.

The front end of the mounting frame 40 is provided with a fixing groove 47, the fixing groove 47 is movably provided with a fixing rod 48, the lower end of the fixing rod 48 is provided with a mounting plate 49, the mounting plate 49 is provided with a mounting groove, and the mobile suction nozzle 41 is arranged in the mounting groove. The position of the fixing rod 48 on the fixing groove 47 can be adjusted, and the position of the mobile suction nozzle 41 on the mounting plate can also be adjusted, so that the mobile suction nozzle can be conveniently applied to shells with various sizes.

Referring to fig. 2, the push plate part 3 includes a middle plate rail 30, a side plate longitudinal conveyor 31, and a side plate lateral conveyor 32, the side plate longitudinal conveyor 31 having two sets of two sides respectively located on the middle plate rail 30, the side plate lateral conveyor 32 being located outside the front end of the side plate longitudinal conveyor 31. The ash plate comprises a triangular side plate positioned at the rear, a triangular side plate positioned at the front and a square plate positioned in the middle, the middle square plate is pushed by an air cylinder to do linear motion along a middle plate track 30, and the triangular plates at two sides are respectively conveyed to a designated position by two groups of belts of a side plate longitudinal conveying belt 31 and a side plate transverse conveying belt 32.

Referring to fig. 4 and 5, the hemming section 5 of the present utility model includes a material receiving conveyor 9, a first hemming nozzle 50, a second hemming nozzle 51, a first hemming station 52, a side brush 53, a second hemming station 54, a front brush 55, a rear brush 56, a hemming output conveyor 57, a press roller assembly 58, and a guide plate 59.

The receiving conveyor 9 according to the utility model interfaces with the first conveyor 1, onto which the shells are transferred from the first conveyor 1.

The first edge-covering suction nozzle 50 is movably arranged above the material receiving conveyor belt 9 and the first edge-covering station 52, and the second edge-covering suction nozzle 51 is movably arranged above the first edge-covering station 52 and the second edge-covering station 54.

The material receiving conveyor belt 9, the first edge wrapping station 52 and the second edge wrapping station 54 are arranged in parallel. The first taping station 52 and the second taping station 54 are provided with suction nozzles for sucking the leather shells. The first edging station 52 and the second edging station 54 can be provided with a plurality of vent holes for connecting the suction nozzle, and the position of the suction nozzle is adjusted according to the actual size of the leather shell so as to realize quick adjustment.

The side brushes 53 are movably arranged on the two sides above the first edge covering station 52, and when the side brushes 53 move from outside to inside, the short edges on the side surfaces of the leather shells can be turned up and stuck to the ash plates.

A front brush 55 and a rear brush 56 are movably arranged above the second binding station 54, and the front brush 55 and the rear brush 56 can move back and forth, so that corresponding long binding can be turned up and stuck on an ash plate during movement.

The middle part of the second edging station 54 is provided with an edging output conveyor belt 57, after the edges on the front side, the rear side and the two sides of the leather shell are well pasted, the second edging station 54 does not suck the leather shell any more, and the edging output conveyor belt 57 rotates and drives the leather shell to output.

The press roller assembly 58 is arranged above the edge wrapping output conveyor belt 57, so that the leather shell and the ash plate can be further pressed and finally molded.

The output end of the hemming output conveyor 57 is provided with a guide plate 59, the guide plate 59 is obliquely arranged, the leather sheath is led out from top to bottom, and the second conveyor 6 is positioned below the guide plate 59.

The utility model firstly conveys the leather shell, the surface of the leather shell is glued by the cover gluing machine 2, then the leather shell is pulled onto the first conveyor belt 1 by the clamping block 11, and the first conveyor belt 1 drives the leather shell to the next station.

The triangular side plates positioned at the rear are longitudinally conveyed to a designated position by the side plate longitudinal conveying belt 31, the triangular side plates positioned at the front are transversely conveyed to the designated position by the side plate transverse conveying belt 32, the two side plates form a square, and the square plate positioned in the middle is directly conveyed to the designated position by the middle plate rail 30.

The suction nozzle of the mobile suction nozzle holder 4 sucks up the dust plate delivered to the specified position and places it on the leather case.

The first conveyor belt 1 drives the leather shell to move, and a pressing plate 12 positioned above the first conveyor belt 1 presses downwards to adhere the ash plate and the leather shell together.

The first conveyor belt 1 drives the leather shell to move into the edge wrapping part 5 to finish edge wrapping; the leather shell with the edge covered falls onto a second conveyor belt 6, the second conveyor belt 6 drives the leather shell to move onto a third conveyor belt 7, and the third conveyor belt 7 outputs the leather shell onto a discharging table 8.

The utility model has the advantages that:

1. the production speed is faster, a plurality of stations which are not interfered with each other are connected by the conveying part, and the multi-station work simultaneously increases the speed;

2. the precision is higher, the leather shell can also keep high precision in the continuous transmission process due to the deviation correcting system, and the error is obviously improved.

It is understood that the above-described embodiments are merely preferred examples of the present utility model and are not intended to limit the scope of the present utility model, so that all equivalent changes or modifications of the structure, features and principles described in the claims are intended to be included in the scope of the present utility model.

Claims (8)

1. The utility model provides a flank leather shell correction device that bordures which characterized in that: including mounting bracket, slide rail, slider, mount pad, motor, belt, the mounting bracket slides and locates on the slide rail, and the slide rail is slided and is equipped with the slider, has the mount pad on the mounting bracket, mount pad and slider pin joint, and the belt is connected to the slider, motor drive belt.

2. The flank skin-shell hemming deviation-correcting device according to claim 1, wherein: the mounting frame is provided with a plurality of mobile suction nozzles.

3. The flank skin-shell hemming deviation-correcting device according to claim 1, wherein: the motor is arranged at one end of the sliding rail, and the belt is positioned on the side face of the sliding rail.

4. A wing skin shell hemming correction device according to claim 3 wherein: and each sliding rail is provided with a motor and a belt.

5. The flank skin-shell hemming deviation-correcting device according to claim 2, wherein: the front end of mounting bracket install the fixed slot, fixed slot movable mounting dead lever, the lower extreme of dead lever has the mounting panel, has seted up the mounting groove on the mounting panel, the mobile suction nozzle is installed in the mounting groove.

6. The flap skin covering deviation correcting device according to claim 5, wherein: the fixed slot is horizontally arranged, and the fixed rod is vertically arranged.

7. The flank skin-shell hemming deviation-correcting device according to claim 1, wherein: the motor is externally connected with a control system, and the control system is connected with a camera.

8. The flap skin covering deviation correcting device according to claim 7, wherein: the sliding rail and the camera are arranged above the first conveyor belt.