CN112456124A

CN112456124A - Dry buffer memory machine

Info

Publication number: CN112456124A
Application number: CN202011380910.9A
Authority: CN
Inventors: 周先进; 庾健彬
Original assignee: Allegro Technology Ltd
Current assignee: Dongguan Allegro Intelligent Technology Co Ltd
Priority date: 2020-12-01
Filing date: 2020-12-01
Publication date: 2021-03-09

Abstract

The invention provides a drying cache machine which comprises a feeding device, a natural air drying device and a discharging device, wherein the natural air drying device is positioned between the feeding device and the discharging device, the natural air drying device comprises an X-axis conveying device and an Jiong-shaped track conveying device, the Jiong-shaped track conveying device comprises a circular lifting mechanism, a material moving mechanism and a circular descending mechanism, the circular lifting mechanism and the circular descending mechanism are sequentially arranged on the X-axis conveying device along the conveying direction of the X-axis conveying device, and the material moving mechanism is arranged on the circular lifting mechanism and the circular descending mechanism in a crossing manner along the X-axis direction. According to the invention, automatic feeding and automatic discharging are respectively realized through the feeding equipment and the discharging equipment, materials are conveyed to enter and exit the Jiong-shaped track conveying device through the X-axis conveying device, and a plurality of materials are contained in a longitudinal space and are driven to move along the Jiong-shaped track through the Jiong-shaped track conveying device, so that the moving stroke of the materials is prolonged, the occupied area is saved, and the yield is ensured.

Description

Dry buffer memory machine

Technical Field

The invention relates to the field of drying equipment, in particular to a drying cache machine for realizing natural air drying.

Background

Along with the progress of science and technology, the electronic product of installation is more and more abundant on the car, and a current section installs display device on car B post, and it includes drain pan and glass board, in the production process of drain pan and glass board, the drain pan and the glass board that accomplish priming paint spraying process need carry out the natural air-dry process together, and it is accomplished through dry buffer memory machine.

The existing drying buffer memory machine comprises a carrier positioning device and a speed-multiplying chain conveying line, wherein the carrier positioning device is arranged in a plurality of modes along the conveying track array of the speed-multiplying chain conveying machine, when natural air drying is carried out, a carrier provided with a bottom shell and a glass plate needs to be manually placed on the carrier positioning device, the speed-multiplying chain conveying line drives the carrier positioning device to drive the bottom shell and the glass plate to move through the carrier to realize natural air drying, the carrier needs to be manually taken out of the carrier positioning device after the natural air drying is completed, the natural air drying speed is low, the carrier positioning device is additionally arranged to increase the yield, the length of the speed-multiplying chain conveying line is long, and the occupied area of a field.

Disclosure of Invention

The present invention is directed to a dry buffer to solve the above problems.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a dry buffer memory, includes charging apparatus, natural air-dry equipment and unloading equipment, natural air-dry equipment is located between charging apparatus and the unloading equipment, natural air-dry equipment includes X axial conveyor and Jiong shape orbit conveyor, Jiong shape orbit conveyor sets up on X axial conveyor, Jiong shape orbit conveyor includes circulation hoist mechanism, removes material mechanism and circulation decline mechanism, circulation hoist mechanism and circulation decline mechanism set up on X axial conveyor along X axial conveyor's direction of delivery in proper order, remove material mechanism and span along the X axial and set up on circulation hoist mechanism and circulation decline mechanism.

Further, the feeding equipment comprises a lower rack I, a Y axial driving device, a lifting device and a clamping jaw device, wherein the Y axial driving device is installed on the lower rack I, the lifting device is installed on the Y axial driving device, the clamping jaw device is installed on the lifting device, the Y axial driving device drives the lifting device to drive the clamping jaw device to move back and forth, the lifting device drives the clamping jaw device to move up and down, and the clamping jaw device moves in an opening and closing mode.

Further, the lifting device comprises a Y-axis moving plate, a driving mechanism, a first guide mechanism, a second guide mechanism and a lifting plate, wherein the driving mechanism, the first guide mechanism and the second guide mechanism are all installed between the Y-axis moving plate and the lifting plate, and the driving mechanism lifting plate carries out lifting motion.

Furthermore, the clamping jaw device comprises a first buckling jaw mechanism and a second buckling jaw mechanism which are arranged in a mirror image mode, and the first buckling jaw mechanism and the second buckling jaw mechanism move oppositely or back to back along the Y-axis direction.

Further, X axial conveyor includes conveyer belt mechanism and lower frame two, conveyer belt mechanism installs on lower frame two, conveyer belt mechanism's feed end and discharge end outwards extend lower frame two respectively, and feeding response mechanism, lift barrier mechanism one, material loading response mechanism, barrier mechanism, unloading response mechanism, lift barrier mechanism two and ejection of compact response mechanism turn right from a left side and install successively in the conveyer belt mechanism, feeding response mechanism and ejection of compact response mechanism are located conveyer belt mechanism's feed end and discharge end respectively, material loading response mechanism and unloading response mechanism are located circulation hoist mechanism and circulation decline mechanism respectively.

Further, circulation hoist mechanism includes frame, drive assembly, chain circulation subassembly one, chain circulation subassembly two, L shape layer board one and L shape layer board two, the interval between chain circulation subassembly one and the chain circulation subassembly two, chain circulation subassembly one and chain circulation subassembly two set up in last frame and all are connected with the drive assembly drive along Y axial symmetry, drive assembly drive chain circulation subassembly one and chain circulation subassembly two synchronous motion, the motion direction of chain circulation subassembly one and chain circulation subassembly two is opposite, L shape layer board one and L shape layer board two are installed respectively on chain circulation subassembly one and chain circulation subassembly two and are set up along Y axial symmetry, L shape layer board one and L shape layer board two are along the conveying orbit array of chain circulation subassembly one and chain circulation subassembly two a plurality ofly respectively.

Further, one of the chain circulation assemblies includes rotation axis, chain drive module, lower rotation axis and tensioning regulating plate, the one end and the drive assembly drive of going up the rotation axis are connected, the chain drive module sets up two sets ofly, go up rotation axis rotatable coupling and be connected with lower rotation axis in the top of last frame and through two sets of chain drive modules, the both ends of rotation axis are connected with the below of last frame through the tensioning regulating plate respectively down, L shape layer board is one and is spaned the setting on two sets of chain drive modules along the X axial.

The invention has the beneficial effects that:

the carrier is provided with a bottom shell and a glass plate which finish a primer spraying process, when a working line drives the carrier to move to a specific position, the carrier is taken out by a feeding device and is driven to move to a feeding end of an X axial conveying device, the carrier is driven by the X axial conveying device to move rightwards to a circulating lifting mechanism, the circulating lifting mechanism drives the carrier to move upwards for a certain height to vacate a space for a next carrier to enter, the processes are repeated, so that the circulating lifting mechanism contains a plurality of carriers, when the circulating lifting mechanism drives the carrier at the uppermost layer to move to the top of the circulating lifting mechanism, the carrier is taken out by a material removing mechanism and is driven to move to the top of a circulating blanking mechanism, the circulating blanking mechanism drives the carrier to move downwards for a certain height to vacate a space for placing the next carrier, and the processes are repeated, so that the circulating blanking mechanism contains a plurality of carriers, when the circulating blanking mechanism drives the carrier at the lowermost layer to move to the X axial conveying device, the X axial conveying device drives the carrier to move rightwards to the discharge end of the X axial conveying device, and the blanking equipment takes out the carrier and drives the carrier to move to the next station.

Compared with the prior art, the feeding device realizes the purpose of replacing manpower to complete feeding work, the X-axis conveying device realizes the purpose of conveying materials to enter and exit the Jiong-shaped track conveying device, the blanking device replaces the purpose of manually completing blanking work, and the Jiong-shaped track conveying device realizes the purposes of containing a plurality of materials by utilizing the longitudinal space and driving the plurality of materials to move along the Jiong-shaped track, so that the moving stroke of the materials is prolonged, the occupied area is saved, and the yield is ensured.

Drawings

FIG. 1: a schematic perspective view of a drying buffer.

FIG. 2: a schematic perspective view of a feeding device of a drying buffer.

FIG. 3: a schematic perspective view of a lifting device of a drying buffer.

FIG. 4: a three-dimensional schematic diagram of a clamping jaw device of a drying cache machine.

FIG. 5: a partial three-dimensional schematic diagram of natural air drying equipment of a drying cache machine.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

referring to fig. 1, a drying and caching machine includes a feeding device 1, a natural air drying device 2, and a discharging device 3, where the natural air drying device 2 is located between the feeding device 1 and the discharging device 3, the natural air drying device 2 is arrayed in a plurality along an X axis, the natural air drying device 2 includes an X axis conveying device 21 and an Jiong-shaped track conveying device 22, the Jiong-shaped track conveying device 22 is disposed on the X axis conveying device 21, the Jiong-shaped track conveying device 22 includes a circular lifting mechanism 221, a material carrying mechanism 222, and a circular descending mechanism 223, the circular lifting mechanism 221 and the circular descending mechanism 223 are sequentially disposed on the X axis conveying device 21 along a conveying direction of the X axis conveying device 21, and the material carrying mechanism 222 is disposed on the circular lifting mechanism 221 and the circular descending mechanism 223 in a crossing manner along the X axis.

Feeding equipment 1, natural air-dry equipment 2 and unloading equipment 3 all are connected with PLC control electricity and all control through the PCL controller, and feeding equipment 1, natural air-dry equipment 2, unloading equipment 3 and PLC controller all are connected with the power electricity.

Referring to fig. 2, the feeding device 1 includes a lower frame i 11, a Y-axis driving device 12, a lifting device 13, and a clamping jaw device 14, the Y-axis driving device 12 is installed on the lower frame i 11, the lifting device 13 is installed on the Y-axis driving device 12, the clamping jaw device 14 is installed on the lifting device 13, the Y-axis driving device 12 drives the lifting device 13 to drive the clamping jaw device 14 to move back and forth, the lifting device 13 drives the clamping jaw device 14 to move up and down, and the clamping jaw device 14 moves in an opening and closing manner.

The structure of charging equipment 1 is the same with unloading equipment 3, and the working process of charging equipment 1 is opposite with unloading equipment 3, and the working process of charging equipment 1: the lifting device 13 drives the clamping jaw device 14 to move downwards, the clamping jaw device 14 performs combined movement to clamp the carrier, the lifting device 13 drives the clamping jaw device 14 to drive the carrier to move upwards, the Y-axis driving device 12 drives the lifting device 13 to drive the carrier to move backwards to the position above the feeding end of the X-axis conveying device 21 through the clamping jaw device 14, the lifting device 13 drives the clamping jaw device 14 to drive the carrier to move downwards to the feeding end, the clamping jaw device 14 performs opening movement to release blocking of the carrier, and the lifting device 13 and the Y-axis mechanism perform resetting movement successively to grab the next carrier.

The Y-axis driving device 12 includes a first bracket 121 and a first Y-axis linear module 122 mounted on the first bracket 121.

Referring to fig. 3, the lifting device 13 includes a Y-axis moving plate 131, a driving mechanism 132, a first guiding mechanism 133, a second guiding mechanism 134, and a lifting plate 135, wherein the driving mechanism 132, the first guiding mechanism 133, and the second guiding mechanism 134 are all installed between the Y-axis moving plate 131 and the lifting plate 135, and the driving mechanism 132 lifts the lifting plate 135.

Referring to fig. 4, the clamping jaw device 14 includes a first fastening jaw mechanism 141 and a second fastening jaw mechanism 142 arranged in a mirror image manner, and the first fastening jaw mechanism 141 and the second fastening jaw mechanism 142 move in opposite directions or in a back-to-back direction along the Y axis;

referring to fig. 4, the first buckling claw mechanism 141 includes two buckling claw units 14-1, which are distributed in an array along the X axis, the buckling claw units 14-1 include Y axis driving modules 14-11 and claw plates 14-12, protrusions 14-121 are provided below the clamping surfaces of the claw plates 14-12, and the protrusions 14-121 are used for matching with grooves formed on the side walls of the carrier, so as to ensure the clamping stability of the clamping jaw device 14 and prevent the carrier from falling off during the movement.

The X-axis conveying device 21 comprises a conveying belt mechanism and a second lower frame, the conveying belt mechanism is installed on the second lower frame, the feeding end and the discharging end of the conveying belt mechanism respectively extend outwards to form the second lower frame, the feeding sensing mechanism, the first lifting blocking mechanism, the feeding sensing mechanism, the blocking mechanism, the discharging sensing mechanism, the second lifting blocking mechanism and the discharging sensing mechanism are installed in the conveying belt mechanism from left to right in sequence, the feeding sensing mechanism and the discharging sensing mechanism are located in the feeding end and the discharging end of the conveying belt mechanism respectively, and the feeding sensing mechanism and the discharging sensing mechanism are located in the circulating lifting mechanism 221 and the circulating descending mechanism 223 respectively.

Referring to fig. 5, the cyclic lifting mechanism 221 and the cyclic lowering mechanism 223 have the same structure, the cyclic lifting mechanism 221 includes an upper frame 2211, a driving assembly 2212, a first chain circulating assembly 2213, a second chain circulating assembly 2214, a first L-shaped support plate 2215 and a second L-shaped support plate 2216, the first chain circulating assembly 2213 and the second chain circulating assembly 2214 are spaced apart from each other, the first chain circulating assembly 2213 and the second chain circulating assembly 2214 are symmetrically arranged on the upper frame 2211 along the Y-axis direction and are both drivingly connected to the driving assembly 2212, the driving assembly 2212 is mounted on the upper frame 2211, the driving assembly 2212 drives the first chain circulating assembly 2213 and the second chain circulating assembly 2214 to move synchronously, the moving directions of the first chain circulating assembly 2213 and the second chain circulating assembly 2214 are opposite, the first L-shaped support plate 2215 and the second L-shaped support plate 2216 are respectively mounted on the first chain circulating assembly 2213 and the second chain circulating assembly 2214 and are symmetrically arranged along the Y, the first L-shaped support plate 2215 and the second L-shaped support plate 2216 are respectively arrayed in a plurality of rows along the conveying tracks of the first chain circulation assembly 2213 and the second chain circulation assembly 2214.

When a carrier enters the first chain circulation assembly 2213 and the second chain circulation assembly 2214, the driving assembly 2212 drives the first chain circulation assembly 2213 and the second chain circulation assembly 2214 to drive the carrier to move upwards through the first L-shaped supporting plate 2215 and the second L-shaped supporting plate 2216 respectively.

And an in-place sensing assembly for detecting whether a carrier is on the top of the circulating lifting mechanism, wherein the in-place sensing assembly is mounted on the upper machine frame 2211.

Referring to fig. 5, the driving assembly 2212 comprises a first commutator 2212-1, a double-output-shaft motor 2212-2 and a second commutator 2212-3, an output shaft at one end of the double-output-shaft motor 2212-2 is in driving connection with a first chain circulation assembly 2213 through the first commutator 2212-1, and an output shaft at the other end of the double-output-shaft motor 2212-2 is in driving connection with a second chain circulation assembly 2214 through the second commutator 2212-3.

The first chain circulation assembly 2213 and the second chain circulation assembly 2214 are identical in structure, the first chain circulation assembly 2213 comprises an upper rotating shaft, a chain transmission module, a lower rotating shaft and a tensioning adjusting plate, one end of the upper rotating shaft is in driving connection with the driving assembly 2212, the chain transmission module is provided with two groups, the upper rotating shaft is rotatably connected above the upper rack 2211 and is connected with the lower rotating shaft through the two groups of chain transmission modules, an L-shaped supporting plate stretches across the two groups of chain transmission modules along the X axial direction, the tensioning adjusting plates are respectively rotatably connected at two ends of the lower rotating shaft, two ends of the lower rotating shaft are respectively connected with the lower part of the upper rack 2211 through the tensioning adjusting plate, the tensioning degree of a chain in the chain transmission module can be adjusted through the tensioning adjusting plate, and the normal work of the.

Remove material mechanism 222 and include Y axial drive assembly, lifting unit and clamping jaw subassembly, Y axial drive assembly installs on last frame 2211, and lifting unit installs on Y axial drive assembly, and clamping jaw subassembly installs on lifting unit, and Y axial drive assembly drives lifting unit and drives clamping jaw subassembly and do the side-to-side movement, and lifting unit drives clamping jaw subassembly and does the elevating movement, and clamping jaw subassembly is opened and shut the motion.

The Y-axis driving assembly comprises a second support and a second Y-axis linear module, and the second Y-axis linear module is arranged on the second support; the lifting assembly and the jaw assembly are identical in structure to the lifting device 13 and the jaw device 14, respectively.

The operation process of the material handling mechanism 222 is as follows: the lifting assembly drives the clamping jaw assembly to move downwards, the clamping jaw assembly performs combined movement to clamp a carrier positioned at the top of the circulating lifting mechanism 221, the lifting assembly drives the clamping jaw assembly to drive the carrier to move upwards, the Y-axis driving assembly drives the lifting assembly to drive the carrier to move rightwards to the top of the circulating descending mechanism 223 through the clamping jaw assembly, the lifting assembly drives the clamping jaw assembly to drive the carrier to move to the top of the circulating descending mechanism 223, the clamping jaw assembly performs opening movement to release blocking of the carrier, and the lifting assembly and the Y-axis driving assembly perform resetting movement successively.

The working principle of the invention is as follows:

the carrier is provided with a bottom shell and a glass plate which finish a primer spraying process, when a working line drives the carrier to move to a specific position, the loading device 1 takes out the carrier to drive the carrier to move to a feeding end of a conveying belt mechanism, at the moment, a feeding sensing mechanism detects the presence of a material, at the moment, if the feeding sensing mechanism detects the absence of the material, a lifting blocking mechanism moves downwards to remove the blocking of the carrier, the conveying belt mechanism drives the carrier to move rightwards to a circulating lifting mechanism 221, the blocking mechanism blocks the carrier to prevent the carrier from moving out of the circulating lifting mechanism 221, at the moment, the feeding sensing mechanism detects the presence of the material, and the circulating lifting mechanism 221 drives the carrier to lift by a certain height to vacate a space for the next carrier;

repeating the above processes to accommodate a plurality of carriers in the cyclic lifting mechanism 221, when the uppermost carrier in the cyclic lifting mechanism 221 moves upwards to the top position of the cyclic lifting mechanism 221, the in-place sensing component detects the existence of the material, the material moving mechanism 222 takes out the carrier and drives the carrier to move to the top position of the cyclic lowering mechanism 223, at this time, the in-place sensing component of the cyclic blanking mechanism detects the existence of the material, and the cyclic lowering mechanism 223 drives the carrier to move downwards for a certain height to vacate a space for placing the next carrier;

repeating the above process to accommodate a plurality of carriers in the circulating blanking mechanism 223, when the circulating descending mechanism 223 drives the carrier at the lowest layer to move to the conveying belt mechanism, the blanking sensing mechanism detects the presence of the material, at this time, if the discharging sensing mechanism detects that the material is absent, the lifting blocking mechanism moves downwards to release the blocking of the carrier, the conveying belt mechanism drives the carrier to move rightwards to the discharging end of the conveying belt mechanism, the discharging sensor detects the presence of the material, the conveying belt mechanism stops working, the blanking device 3 takes out the carrier and drives the carrier to move to the next station, and the conveying belt mechanism continues working.

The technical scope of the present invention is not limited to the above embodiments, and any modifications, equivalent variations and modifications made to the above embodiments according to the technical spirit of the present invention still fall within the technical scope of the present invention.

Claims

1. A dry buffer memory machine which characterized in that: including material loading equipment, natural air-dry equipment and unloading equipment, natural air-dry equipment is located between material loading equipment and the unloading equipment, natural air-dry equipment includes X axial conveyor and Jiong shape orbit conveyor, Jiong shape orbit conveyor includes circulation hoist mechanism, removes material mechanism and circulation descending mechanism, circulation hoist mechanism and circulation descending mechanism set up on X axial conveyor along X axial conveyor's direction of delivery successively, it crosses the setting on circulation hoist mechanism and circulation descending mechanism along X axial to remove material mechanism.

2. A dry buffer according to claim 1, wherein: the feeding equipment comprises a lower frame I, a Y axial driving device, a lifting device and a clamping jaw device, wherein the Y axial driving device is installed on the lower frame I, the lifting device is installed on the Y axial driving device, the clamping jaw device is installed on the lifting device, the Y axial driving device drives the lifting device to drive the clamping jaw device to move back and forth, the lifting device drives the clamping jaw device to move up and down, and the clamping jaw device moves in an opening and closing mode.

3. A dry buffer according to claim 2, wherein: the lifting device comprises a Y-axis moving plate, a driving mechanism, a first guide mechanism, a second guide mechanism and a lifting plate, wherein the driving mechanism, the first guide mechanism and the second guide mechanism are all installed between the Y-axis moving plate and the lifting plate, and the driving mechanism lifting plate is in lifting motion.

4. A dry buffer according to claim 2, wherein: the clamping jaw device comprises a first buckling jaw mechanism and a second buckling jaw mechanism which are arranged in a mirror image mode, and the first buckling jaw mechanism and the second buckling jaw mechanism move oppositely or back to back along the Y-axis direction.

5. A dry buffer according to claim 1, wherein: the X axial conveying device comprises a conveying belt mechanism and a second lower frame, the conveying belt mechanism is installed on the second lower frame, the feeding end and the discharging end of the conveying belt mechanism respectively extend out of the second lower frame, the feeding sensing mechanism, the first lifting blocking mechanism, the feeding sensing mechanism, the blocking mechanism, the discharging sensing mechanism, the second lifting blocking mechanism and the discharging sensing mechanism are installed in the conveying belt mechanism from left to right successively, the feeding sensing mechanism and the discharging sensing mechanism are located in the feeding end and the discharging end of the conveying belt mechanism respectively, and the feeding sensing mechanism and the discharging sensing mechanism are located in a circulating lifting mechanism and a circulating descending mechanism respectively.

6. A dry buffer according to claim 1, wherein: the circulation hoist mechanism includes frame, drive assembly, chain circulation subassembly one, chain circulation subassembly two, L shape layer board one and L shape layer board two, the interval between chain circulation subassembly one and the chain circulation subassembly two, chain circulation subassembly one and chain circulation subassembly two set up in last frame and all are connected with the drive assembly drive along Y axial symmetry, drive assembly drive chain circulation subassembly one and two synchronous motion of chain circulation subassembly, the motion direction of chain circulation subassembly one and chain circulation subassembly two is opposite, L shape layer board one and L shape layer board two are installed respectively on chain circulation subassembly one and chain circulation subassembly two and are set up along Y axial symmetry, L shape layer board one and L shape layer board two are respectively along the conveying orbit array of chain circulation subassembly one and chain circulation subassembly two a plurality ofly.

7. The dry buffer according to claim 6, wherein: chain circulation subassembly one includes rotation axis, chain drive module, lower rotation axis and tensioning regulating plate, the one end and the drive assembly drive of going up the rotation axis are connected, the chain drive module sets up two sets ofly, go up rotation axis rotatable coupling and be connected with lower rotation axis in the top of last frame and through two sets of chain drive modules, the both ends of rotation axis are connected with the below of last frame through the tensioning regulating plate respectively down, L shape layer board is one and is spaned the setting on two sets of chain drive modules along the X axial.