CN113276220A

CN113276220A - Online plate cutting and feeding system on large plate coating line

Info

Publication number: CN113276220A
Application number: CN202110629552.9A
Authority: CN
Inventors: 刘迎东; 杨江宁
Original assignee: Taizhou Rayard Wood Industry Co ltd
Current assignee: Taizhou Rayard Wood Industry Co ltd
Priority date: 2021-06-07
Filing date: 2021-06-07
Publication date: 2021-08-20

Abstract

The invention discloses an on-line plate cutting and feeding system on a large plate coating line, which comprises a plate stacking device, a cache transition translation device, a feeding device and an intelligent control system, wherein the cache transition translation device, the feeding device and the intelligent control system are positioned at the downstream of the plate stacking device, the feeding device is connected with a plate sawing device through a feeding plate, and the intelligent control system controls the operation of the plate stacking device, the cache transition translation device and the feeding device. The plate coating and cutting system can automatically convey coated plates to the cutting system, so that the labor of personnel for coating, blanking and cutting and loading large plates is saved; on the other hand, the damage to the surface of the plate in the feeding and discharging process is avoided; through the design laminator, can be the group with panel after the cladding and stack, by the program control who sets for, the panel quantity that every group stacked is unanimous, and the panel that every group stacked transports to material feeding unit through buffer memory transition translation device, and the panel that a plurality of groups stacked saw cuts together, when improving panel saw cuts efficiency, improves panel saw cuts the quality.

Description

Online plate cutting and feeding system on large plate coating line

Technical Field

The invention belongs to the technical field of intelligent processing of furniture boards, and particularly relates to an on-line board cutting and feeding system on a large board coating line.

Background

When the furniture board is processed, the board needs to be cut off after being coated, an existing large board coating production line is not connected with an electronic saw, and after the large board is coated, a blanking worker needs to convey the board to a roller table in a material preparation area and then the board is transported to the feeding position of the electronic saw by a worker in a material cutting process. The whole process does not increase the product value per se, and belongs to serious waste. Meanwhile, due to the sequence of processing, the production rhythm between the two working procedures needs to be matched, and the management cost is increased invisibly. The coating line and the cutting line are connected, so that the plate can directly enter the cutting saw to cut the material after being coated, manpower and material resources are saved, the efficiency is greatly improved, and meanwhile, the collision in the plate material rotating process, the material pouring and other dangerous factors are reduced, therefore, a novel automatic feeding system after the plate is coated needs to be researched and developed.

Disclosure of Invention

The purpose of the invention is as follows: the invention aims to provide an on-line plate cutting and feeding system on a large plate coating line, which has high operation stability and high intelligent degree aiming at the defects of the prior art.

The technical scheme is as follows: the invention relates to an on-line plate cutting and feeding system on a large plate coating line, which comprises a plate stacking device, a buffer memory transition translation device positioned at the downstream of the plate stacking device, a feeding device and an intelligent control system, wherein the feeding device is connected with a plate sawing device through a feeding plate;

the plate stacking device comprises a plate stacking rack, a first lifting table is arranged on the plate stacking rack, a pushing device is arranged on the first lifting table, a first position sensor is arranged at the front end of the first lifting table, the position of the buffer memory transition translation device is sensed by the first position sensor, and plates on the plate stacking rack are pushed to the buffer memory transition translation device by the pushing device;

the buffer transition translation device comprises a buffer rack, a buffer table and a plate translation device are arranged on the buffer rack, and the plate translation device translates the plate on the buffer table to the feeding device;

the feeding device comprises a feeding rack, a second lifting table is arranged on the feeding rack, a second position sensor is arranged at the front end of the second lifting table, a plate feeding device is arranged on the second lifting table, the position of the feeding plate is sensed by the second position sensor, and the plate is fed into the feeding plate by the plate feeding device;

the intelligent control system comprises a position sensor control module, a pushing device control module, a plate translation device control module, a plate feeding device control module, a signal processing module and a power supply control module, wherein the first position sensor and the second position sensor are wirelessly connected with the position sensor control module, and the position sensor control module is electrically connected with the signal processing module; the pushing device is electrically connected with the pushing device control module; the plate translation device is electrically connected with the plate translation device control module; the plate feeding device is electrically connected with the plate feeding device control module; and the intelligent control system controls the operation of the plate stacking device, the cache transition translation device and the feeding device according to a set program.

Further, as a preferred embodiment, the first lifting table is a hydraulic lifting table, the pushing device includes a bearing frame, at least one pair of slide rail assemblies and a pushing cylinder, the bearing frame is fixed on the lifting table, the pushing cylinder is fixed on a side edge of the lifting table, and a push plate is vertically fixed at a front end of a gas rod of the pushing cylinder; the sliding rail assemblies are symmetrically arranged on the bearing frame.

Further, as a better embodiment, the slide rail assembly comprises a slide rail, the slide rail is arranged along the plate translation direction, a strip groove with an upward opening is formed in the slide rail, and a plurality of groups of pulleys are arranged in the strip groove.

Furthermore, in order to adjust the neatness of the stacked plates in time, a correction assembly is further arranged on the first lifting platform and comprises at least two pairs of correction cylinders, each pair of correction cylinders are symmetrically fixed on the plate stacking rack upwards, correction plates are fixed on gas rods of the correction cylinders, gaps for the correction plates to extend out are formed in the bearing frame, the correction cylinders drive the correction plates to extend out of the bearing frame upwards in the operating state, and a plate stacking area is formed between each group of correction plates.

Further, as a preferred embodiment, a pair of fine adjustment assemblies is arranged at the bottom of the plate stacking rack, each fine adjustment assembly comprises a fine adjustment motor, a fine adjustment screw rod, a pair of fine adjustment sliders and a pair of fine adjustment guide rails, the fine adjustment motor is fixed on the plate stacking rack, a rotating shaft of the fine adjustment motor is connected with the fine adjustment screw rods through a coupler, the pair of fine adjustment guide rails are symmetrically fixed on two sides of the fine adjustment screw rods, the pair of fine adjustment sliders comprises a left fine adjustment slider and a right fine adjustment slider, both the left fine adjustment slider and the right fine adjustment slider are provided with screw holes matched with the screw rods and guide holes matched with the fine adjustment guide rails, the screw holes of the left fine adjustment slider are opposite to the screw holes of the right fine adjustment slider in direction, and the fine adjustment sliders are fixed with the correction cylinders; the fine tuning motor drives the fine tuning screw rod to rotate, the fine tuning screw rod drives the left fine tuning slide block and the right fine tuning slide block to reversely run along the direction of the fine tuning guide rail, and the left fine tuning slide block and the right fine tuning slide block drive the correction cylinder to run to adjust the position of the correction assembly.

Further, as a preferred embodiment, the plate translation device comprises a translation motor, a translation driving rotating shaft, a translation driven rotating shaft and a plurality of translation conveying belts, wherein the rotating shaft of the translation motor is connected with the translation driving rotating shaft through a coupler, and the plurality of translation conveying belts are arranged on the translation driving rotating shaft and the translation driven rotating shaft in parallel.

Further, as a preferred embodiment, the plate feeding device comprises a plate feeding frame fixed at the top of the second lifting table, roller assemblies and a plate feeding conveyor belt are alternately arranged on the plate feeding frame, the roller assemblies are driven by a rolling motor to drive plates to be arranged along the plate feeding frame, and the running direction of the roller assemblies is the same as that of the translation conveyor belt; the plate conveying belt is driven by a plate conveying motor to run towards the direction of the feeding plate; the running direction of the plate conveying belt is vertical to the running direction of the roller assembly.

Has the advantages that: (1) the plate coating and cutting system can automatically convey coated plates to the cutting system, so that the labor of personnel for coating, blanking and cutting and loading large plates is saved; on the other hand, the damage to the surface of the plate in the feeding and discharging process is avoided; (2) by designing the plate stacking machine, the coated plates can be stacked in groups and controlled by a set program, the number of the stacked plates in each group is consistent, the stacked plates in each group are conveyed to the feeding device through the buffer transition translation device, and a plurality of groups of the stacked plates are sawed together, so that the sawing efficiency of the plates is improved, and the sawing quality of the plates is improved; (3) through design revision subassembly and fine setting subassembly, the panel regularity that in time the adjustment was piled up improves the panel precision of saw cutting.

Drawings

FIG. 1 is a schematic view of the overall structure of the apparatus;

FIG. 2 is a top view of the pushing device of the present device;

FIG. 3 is a schematic view of a fine adjustment assembly of the present apparatus;

wherein: 1. the plate stacking device comprises a plate stacking device body 11, a plate stacking rack body 12, a pushing device body 121, a bearing frame 122, a sliding rail assembly 1221, a sliding rail 1222, a strip groove 1223, a pulley 123, a pushing cylinder 124, an air rod 125, a pushing plate 13, a fine adjustment assembly 131, a fine adjustment motor 132, a fine adjustment screw rod 133, a left fine adjustment slider 134, a right fine adjustment slider 135, a fine adjustment guide rail 2, a buffer transition translation device 21, a buffer rack body 211, a buffer platform 22, a translation conveying belt 3, a feeding device body 31, a feeding rack body 32, a plate feeding device body 321, a plate feeding rack body 322, a roller assembly 323, a plate feeding conveying belt 4 and a feeding plate.

Detailed Description

The technical solution of the present invention is described in detail below with reference to the accompanying drawings, but the scope of the present invention is not limited to the embodiments.

Example (b): an online plate cutting and feeding system on a large plate coating line comprises a plate stacking device 1, a buffer memory transition translation device 2 positioned at the downstream of the plate stacking device, a feeding device 3 and an intelligent control system, wherein the feeding device 3 is connected with a plate sawing device through a feeding plate 4;

the plate stacking device 1 comprises a plate stacking rack 11, a first lifting table is arranged on the plate stacking rack 11, a pushing device 12 is arranged on the first lifting table, a first position sensor is arranged at the front end of the first lifting table, the position of the cache transition translation device 2 is sensed by the first position sensor, and plates on the plate stacking rack are pushed to the cache transition translation device by the pushing device;

the buffer transition translation device 2 comprises a buffer rack 21, a buffer table 211 and a plate translation device are arranged on the buffer rack 21, and the plate translation device translates the plate on the buffer table to the feeding device;

the feeding device 3 comprises a feeding rack 31, a second lifting table is arranged on the feeding rack 31, a second position sensor is arranged at the front end of the second lifting table, a plate feeding device 32 is arranged on the second lifting table, the position of the feeding plate 4 is sensed by the second position sensor, and the plate is fed into the feeding plate 4 by the plate feeding device 32 and then enters the plate sawing device for cutting off;

The first lifting platform is a hydraulic lifting platform, the pushing device 12 comprises a bearing frame 121, a pair of sliding rail assemblies 122 and a pushing cylinder 123, the bearing frame 121 is fixed on the lifting platform, the pushing cylinder 123 is fixed on the side edge of the lifting platform, and a pushing plate 125 is vertically fixed at the front end of an air rod 124 of the pushing cylinder 123; the sliding rail assemblies 122 are symmetrically disposed on the carrying frame 121.

The slide rail assembly 122 includes a slide rail 1221, the slide rail 1221 is disposed along a plate translation direction, a strip groove 1222 with an upward opening is disposed on the slide rail 1221, and a plurality of sets of pulleys 1223 are disposed in the strip groove 1222.

The first lifting platform is further provided with a correction assembly, the correction assembly comprises two pairs of correction cylinders, each pair of correction cylinders are symmetrically fixed on the plate stacking rack 11 upwards, correction plates are fixed on air rods of the correction cylinders, gaps for the correction plates to extend out are formed in the bearing frame, the correction cylinders drive the correction plates to extend out of the bearing frame upwards in an operating state, and a plate stacking area is formed between each group of correction plates.

The bottom of the plate stacking rack 11 is provided with a pair of fine adjustment assemblies 13, each fine adjustment assembly 13 comprises a fine adjustment motor 131, a fine adjustment screw rod 132, a pair of fine adjustment sliders and a pair of fine adjustment guide rails 135, the fine adjustment motor 131 is fixed on the plate stacking rack 11, a rotating shaft of the fine adjustment motor 131 is connected with the fine adjustment screw rod 132 through a coupler, the pair of fine adjustment guide rails are symmetrically fixed on two sides of the fine adjustment screw rod 132, the pair of fine adjustment sliders comprise a left fine adjustment slider 133 and a right fine adjustment slider 134, screw holes matched with the fine adjustment screw rod 132 and guide holes matched with the fine adjustment guide rails are formed in the left fine adjustment slider 133 and the right fine adjustment slider 134, the screw holes of the left fine adjustment slider 133 are opposite to the screw holes of the right fine adjustment slider 134, and the fine adjustment cylinders are fixed on the fine adjustment sliders; the fine tuning motor 131 drives the fine tuning screw 132 to rotate, the fine tuning screw 132 drives the left fine tuning slider 133 and the right fine tuning slider 134 to reversely run along the fine tuning guide rail 135, and the left fine tuning slider 133 and the right fine tuning slider 134 drive the correction cylinder to run to adjust the position of the correction assembly.

The plate translation device comprises a translation motor, a translation driving rotating shaft, a translation driven rotating shaft and a plurality of translation conveying belts 22, wherein the rotating shaft of the translation motor is connected with the translation driving rotating shaft through a coupler, and the plurality of translation conveying belts are arranged on the translation driving rotating shaft and the translation driven rotating shaft in parallel.

The plate conveying device 32 comprises a plate conveying frame 321 fixed at the top of the second lifting table, roller assemblies 322 and a plate conveying belt 323 are alternately arranged on the plate conveying frame 321, the roller assemblies 322 are driven by a rolling motor to drive plates to be arranged along the plate conveying frame, and the running direction of the roller assemblies 322 is the same as that of the translation conveying belt; the plate conveying belt 323 is driven by a plate conveying motor to move towards the direction of the feeding plate; the plate conveying belt 323 runs in a direction perpendicular to the running direction of the roller assembly.

The operation process of the device is as follows: the plates coated by the coating lines are directly released onto the plate stacking device to be stacked, and in the stacking process, the stacked plates are corrected in time by the correction assembly, so that the problem of unsmooth translation caused by the fact that the plates are not piled up; when panel piles up to setting for the volume, the first elevating platform of intelligence control system control moves to and flushes with the buffer memory frame, then starts pusher, with the panel flat push that piles up on the first elevating platform to buffer memory transition translation device on, then transport panel to material feeding unit by panel translation device, the panel that piles up is at the translation under roller assembly's effect earlier, arrange in order on sending the grillage, until arranging to setting for the width, start and send the board motor, send the board conveyer belt to drive the panel of arranging and get into the delivery sheet, the unified program of cutting that gets into absolutely.

As noted above, while the present invention has been shown and described with reference to certain preferred embodiments, it is not to be construed as limited thereto. Various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. The utility model provides an online disconnected feeding system that cuts of panel on big board cladding operation line which characterized in that: the plate stacking device comprises a plate stacking device, a caching transition translation device positioned at the downstream of the plate stacking device, a feeding device and an intelligent control system, wherein the feeding device is connected with a plate sawing device through a feeding plate;

2. The on-line plate cutting and feeding system on the large plate coating line according to claim 1, characterized in that: the first lifting table is a hydraulic lifting table, the pushing device comprises a bearing frame, at least one pair of sliding rail assemblies and a pushing cylinder, the bearing frame is fixed on the lifting table, the pushing cylinder is fixed on the side edge of the lifting table, and a push plate is vertically fixed at the front end of an air rod of the pushing cylinder; the sliding rail assemblies are symmetrically arranged on the bearing frame.

3. The on-line plate cutting and feeding system on the large plate coating line according to claim 2, characterized in that: the sliding rail assembly comprises a sliding rail, the sliding rail is arranged along the plate translation direction, a strip groove with an upward opening is formed in the sliding rail, and a plurality of groups of pulleys are arranged in the strip groove.

4. The on-line plate cutting and feeding system on the large plate coating line according to claim 3, characterized in that: the plate stacking machine is characterized in that a correcting assembly is further arranged on the first lifting table and comprises at least two pairs of correcting cylinders, each pair of correcting cylinders are symmetrically fixed on the plate stacking rack upwards, a correcting plate is fixed on an air rod of each correcting cylinder, a notch for the extending of the correcting plate is formed in the bearing frame, the correcting cylinders drive the correcting plates to extend upwards out of the bearing frame in an operating state, and a plate stacking area is formed between each group of the correcting plates.

5. The on-line plate cutting and feeding system on the large plate coating line according to claim 4, characterized in that: the bottom of the plate stacking rack is provided with a pair of fine adjustment assemblies, each fine adjustment assembly comprises a fine adjustment motor, a fine adjustment screw rod, a pair of fine adjustment sliding blocks and a pair of fine adjustment guide rails, the fine adjustment motors are fixed on the plate stacking rack, a rotating shaft of each fine adjustment motor is connected with the fine adjustment screw rods through a coupler, the pair of fine adjustment guide rails are symmetrically fixed on two sides of each fine adjustment screw rod, each pair of fine adjustment sliding blocks comprises a left fine adjustment sliding block and a right fine adjustment sliding block, each of the left fine adjustment sliding block and the right fine adjustment sliding block is provided with a screw hole matched with the screw rod and a guide hole matched with the fine adjustment guide rails, the screw hole of the left fine adjustment sliding block is opposite to the screw hole of; the fine tuning motor drives the fine tuning screw rod to rotate, the fine tuning screw rod drives the left fine tuning slide block and the right fine tuning slide block to reversely run along the direction of the fine tuning guide rail, and the left fine tuning slide block and the right fine tuning slide block drive the correction cylinder to run to adjust the position of the correction assembly.

6. The on-line plate cutting and feeding system on the large plate coating line according to claim 5, characterized in that: the plate translation device comprises a translation motor, a translation driving rotating shaft, a translation driven rotating shaft and a plurality of translation conveying belts, wherein the rotating shaft of the translation motor is connected with the translation driving rotating shaft through a coupler, and the plurality of translation conveying belts are arranged on the translation driving rotating shaft and the translation driven rotating shaft in parallel.

7. The on-line plate cutting and feeding system on the large plate coating line according to claim 6, characterized in that: the plate feeding device comprises a plate feeding frame fixed at the top of the second lifting table, roller assemblies and a plate feeding conveyor belt are alternately arranged on the plate feeding frame, the roller assemblies are driven by a rolling motor to drive plates to be distributed along the plate feeding frame, and the running direction of the roller assemblies is the same as that of the translation conveyor belt; the plate conveying belt is driven by a plate conveying motor to run towards the direction of the feeding plate; the running direction of the plate conveying belt is vertical to the running direction of the roller assembly.