CN212711652U - Chip burning system - Google Patents

Abstract

The utility model discloses a chip burns record system belongs to automation equipment technical field. The automatic chip feeder mainly comprises a workbench, an input end, an output end and a transmission mechanism, and further comprises an input temporary storage mechanism, an output temporary storage mechanism and at least two burning seats, and further comprises two material storage devices and two first material taking devices, wherein the material storage devices comprise storage plates, the storage plates are provided with a plurality of storage grooves used for bearing and positioning chips, the material storage devices are respectively arranged in the input temporary storage mechanism and the output temporary storage mechanism, one first material taking device is arranged in the input temporary storage mechanism and used for conveying the chips to the material storage devices corresponding to the input temporary storage mechanism, the other first material taking device is movably arranged in the output temporary storage mechanism and used for conveying the chips to the output end on the material storage device corresponding to the output temporary storage mechanism, and the transmission mechanism comprises a second material taking device used for conveying a plurality of chips between the material storage devices and the burning seats. The utility model discloses a chip burns record system has effectively improved the efficiency of burning record.

Description

Chip burning system

Technical Field

The utility model relates to an automation equipment technical field, concretely relates to chip burns record system.

Background

The burning seat is a tool for writing data on the programmable integrated circuit and is applied to a chip burning system; because the chip needs to be accurately aligned and placed in the chip socket of the burning seat to smoothly perform subsequent burning operation, the conventional chip burning system only takes and places a single chip every time to ensure accurate chip positioning, and thus the production efficiency is limited.

Therefore, it is necessary to provide a system for burning chips to solve the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem who solves: the chip burning system is provided, and burning efficiency can be effectively improved.

In order to solve the technical problem, the utility model discloses a as follows technical scheme be: a chip burning system comprises a workbench, an input end, an output end and a transmission mechanism; the chip burning system also comprises an input temporary storage mechanism positioned at the input end, an output temporary storage mechanism positioned at the output end and at least two burning seats, the chip burning system also comprises two material storages and two first material extractors, wherein the material storages comprise storage plates, the storage plate is provided with a plurality of accommodating grooves for bearing and positioning the chips, the material storage devices are respectively arranged in the input temporary storage mechanism and the output temporary storage mechanism, one of the first extractors is arranged in the input temporary storage mechanism and used for conveying the chip to a corresponding material storage device of the input temporary storage mechanism, the other first extractor is movably arranged in the output temporary storage mechanism, the transfer mechanism comprises a second material taking device used for conveying a plurality of chips between the material storage device and the burning seat.

Furthermore, four accommodating grooves are distributed along the length direction of the accommodating plate.

Furthermore, the arrangement structure of the accommodating groove on the accommodating plate is the same as the arrangement structure of the chip interface on the burning seat.

Further, the input end is used for being connected with an external chip supply machine, and the output end is used for being connected with an external chip packaging machine.

Furthermore, the number of the burning seats is two.

Further, the transmission mechanism further includes a first translating member and a second translating member.

Furthermore, the first translation member includes a first slide rail fixedly mounted on the workbench, a first slide carriage slidably connected to the first slide rail, and a fourth motor for driving the first slide carriage to perform linear reciprocating motion on the first slide rail.

Furthermore, the second translation member includes a second slide rail fixedly mounted on the first slide rail and intersecting with the first slide rail, a second slide rail slidably connected to the second slide rail, and a fifth motor for driving the second slide rail to perform linear reciprocating motion on the second slide rail.

Furthermore, the second material taking device comprises a mounting seat fixedly mounted on the second sliding seat, a connecting block connected to the mounting seat in a sliding manner, a sixth motor used for driving the connecting block to do linear reciprocating motion relative to the mounting seat, and a suction nozzle assembly mounted on the connecting block.

Furthermore, four suction nozzles which are in one-to-one correspondence with the containing grooves on the storage plate are arranged on the suction nozzle assembly.

The utility model has the beneficial technical effects that: the utility model relates to a chip burning system, wherein a material storage device is respectively arranged in an input temporary storage mechanism and an output temporary storage mechanism, the material storage device comprises a storage plate, a plurality of storage grooves are arranged on the storage plate corresponding to a burning seat, a first material taking device is movably arranged in the input temporary storage mechanism and the output temporary storage mechanism corresponding to the material storing device respectively, therefore, in the input temporary storage mechanism, a plurality of chips can be orderly arranged on the material storage plate through the first material taking device, positioning the plurality of chips through the containing groove on the material storing plate so that the suction nozzle assembly with the plurality of suction nozzles in the second material taking device can grab and place the plurality of chips input into the temporary storage mechanism into the burning seat, therefore, the multiple chips can be burned at one time, the capacity of the burning system is effectively improved, the multiple burning seats allow the multiple chips to be burned at the same time, and the burning efficiency is further improved.

Drawings

The present invention will be further explained with reference to the drawings and examples.

In the figure: fig. 1 is a schematic diagram of a chip burning system according to the present invention;

FIG. 2 is a schematic structural view of FIG. 1 without the transfer mechanism;

FIG. 3 is a schematic view of the structure of the accumulator;

FIG. 4 is a schematic view of the first dispenser;

FIG. 5 is a schematic view of the assembly of the transfer mechanism with the table;

FIG. 6 is another perspective view of FIG. 5;

FIG. 7 is a schematic view of the second dispenser;

in the figure:

100. a work table; 110. a vertical plate.

200. An input terminal.

300. An input temporary storage mechanism; 310. a first translation guide rail; 320. a first motor.

400. And (4) an output end.

500. An output temporary storage mechanism; 510. a second translation guide rail; 520. a second motor.

600. A material storage device; 610. a storage plate; 6101. a containing groove; 620. and a cylinder.

700. A first material taking device; 710. a first slide plate; 711. a clamping block; 712. a first lifting guide rail; 720. A second slide plate; 730. a third motor; 740. a suction nozzle.

800. A burning seat.

900. A transfer mechanism; 910. a first translating member; 911. a first slide rail; 912. a first slider; 913. A fourth motor; 920. a second translating member; 921. a second slide rail; 922. a second slide carriage; 923. a fifth motor; 930. a second material taking device; 931. a mounting seat; 932. connecting blocks; 933. a sixth motor; 934. A nozzle assembly.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the present application, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

As shown in fig. 1, a chip burning system includes a working platform 100, an input temporary storage mechanism 300, an output temporary storage mechanism 500, a burning seat 800 and a transmission mechanism 900, wherein the input temporary storage mechanism 300 and the output temporary storage mechanism 500 respectively input and output chips, the transmission mechanism 900 sends a plurality of chips into or out of the burning seat 800, and each action mechanism cooperates with each other to quickly complete burning.

Specifically, in the present embodiment, in order to facilitate the installation of the input buffer mechanism 300 and the output buffer mechanism 500 on the table 100, one vertical plate 110 is fixedly installed on the table 100 corresponding to each of the input buffer mechanism 300 and the output buffer mechanism 500.

In a specific implementation mode, the utility model discloses a chip burns record system is still including the input 200 that is located workstation one side and the output 400 of relative one side, and input 200 is used for connecting outside chip feed machine (not shown) to in sending into the chip that will wait to burn record the utility model discloses an in the chip burns record system, output 400 is used for connecting outside chip packaging machine (not shown) simultaneously, can directly encapsulate burning record good chip to this.

Referring also to fig. 2, the input buffer mechanism 300 is located adjacent to the input end 200, the input buffer mechanism 300 includes a first translation rail 310 and a first motor 320, which are located on the working platform 100, specifically, in the present embodiment, the first translation rail 310 and the first motor 320 are both fixedly mounted on the vertical plate 110 adjacent to the input end 200, and the first translation rail 310 is parallel to the upper end surface of the working platform 100.

The output buffer mechanism 500 is located adjacent to the output end 400, the output buffer mechanism 500 includes a second translation rail 510 and a second motor 520 located on the working table 100, specifically, in the present embodiment, the second translation rail 510 and the second motor 520 are both fixedly mounted on the vertical plate 110 adjacent to the output end 400, and the second translation rail 510 is collinear with the first translation rail 310.

In the present embodiment, belts parallel to the first and second translation rails 310 and 510 are respectively fitted over the first and second motors 320 and 520.

In a specific implementation mode, the utility model discloses a chip burns record system still includes and is no less than two banker 600 and first glassware 700, and in this implementation mode, banker 600 and first glassware 700 are provided with two respectively, and two banker 600 correspond respectively and set up on input temporary storage mechanism 300 and output temporary storage mechanism 500, and two same first glassware 700 also correspond respectively and set up on input temporary storage mechanism 300 and output temporary storage mechanism 500.

Further, as also shown with reference to figure 3,

the storage device 600 includes a storage plate 610, a plurality of accommodating grooves 6101 for accommodating chips are formed on the upper edge of the storage plate 610 along the length direction, and the arrangement structure of the accommodating grooves 6101 on the storage plate 610 is the same as the arrangement of chip interfaces on the burning seat 800, so that after the chips are positioned by the accommodating grooves 6101 on the storage plate 610, when the chips on the storage plate 610 are taken again, the chips can be accurately corresponded to the interfaces on the burning seat 800, in this embodiment, four accommodating grooves 6101 on the storage plate 610 are provided, it can be understood that, in actual application, the number of the accommodating grooves 6101 should be designed according to the specification of the burning seat 800, and in addition, in this embodiment, the notch position of the accommodating groove 6101 is provided with a chamfer, so as to perform a certain guiding and correcting function on the falling chips; in addition, in the present embodiment, the stocker 600 further includes an air cylinder 620, the storage plate 610 is detachably mounted on the output end of the corresponding air cylinder 620, specifically, the two storage devices 600 are respectively fixedly connected to the working table 100 through the air cylinder 620 and respectively located below the input buffer mechanism 300 and the output buffer mechanism 500, and the storage plate 610 is parallel to the first translation guide rail 310 and the second translation guide rail 510, so that the storage plate 610 can be driven by the air cylinder 620 to move away from or close to the corresponding input buffer mechanism 300 or output buffer mechanism 500.

Referring also to fig. 4, the first picker 700 includes a first slide plate 710, a second slide plate 720 slidably coupled to the first slide plate 710, a third motor 730 for driving the second slide plate 720 to move relative to the first slide plate 710, and a suction nozzle 740 fixedly mounted on the second slide plate 720.

The first sliding plate 710 is provided with a clamping block 711; a first lifting guide rail 712 is fixedly arranged on the first sliding plate 710 along a direction vertical to the upper end surface of the storage plate 610, and a sliding block correspondingly matched with the first lifting guide rail 712 is fixedly arranged on the second sliding plate 720, so that the sliding block is connected to the first lifting guide rail 712 in a sliding manner; the third motor 730 is fixedly installed on the first sliding plate 710, and in the embodiment, the third motor 730 is in transmission connection with the second sliding plate 720 through the matching of a screw rod and a nut; and the suction nozzle 740 is perpendicular to the upper surface of the storage plate 610.

Through the first sliding plate 710, the two first dispensers 700 are respectively slidably connected to the first translation guide rail 310 and the second translation guide rail 510, and meanwhile, the two first dispensers 700 are respectively connected to the first motor 320 and the second motor 520 through the first sliding plate 710 in a transmission manner, specifically, the two first dispensers 700 fixedly connect the corresponding first sliding plate 710 to the corresponding belt through the clamping block 711, so that the two first dispensers 700 are respectively movably disposed on the input temporary storage mechanism 300 and the output temporary storage mechanism 500.

The number of the burning seats 800 is two, and the burning seats 800 are installed at the upper end of the workbench 100 in parallel with the storage plate 610, in this embodiment, the burning seats 800 are four-port type burning seats, and it can be understood that the burning seats 800 can also be formed by connecting a plurality of single-port burning seats in series; the multiple-set design of the recording seat 800 can avoid the delay of the previous process, thereby reducing the recording efficiency.

Referring to fig. 5 and 6, the transfer mechanism 900 includes a first translating member 910, a second translating member 920, and a second picker 930.

The first translating member 910 includes a first slide rail 911 fixedly mounted on the upper end of the workbench 100, a first slide base 912 slidably connected to the first slide rail 911, and a fourth motor 913 for driving the first slide base 912 to reciprocate linearly on the first slide rail 911.

The fourth motor 913 is fixedly mounted at an end of the first slide rail 911, and the fourth motor 913 and the first slide base 912 are in linear transmission connection through matching of a lead screw and a lead screw nut.

The second translation member 920 includes a second slide rail 921 fixedly mounted on the first slide base 912 and intersecting with the first slide rail 911, a second slide base 922 slidably connected to the second slide rail 921, and a fifth motor 923 for driving the second slide base 922 to reciprocate linearly on the second slide rail 921.

The fifth motor 923 is fixedly mounted at the end of the second sliding rail 921, and the fifth motor 923 and the second sliding base 922 are connected in a linear transmission manner through the matching of the screw rod and the screw nut.

Referring also to fig. 7, the second dispenser 930 includes a mounting seat 931 fixedly mounted on the second slide seat 922, a connecting block 932 slidably connected to the mounting seat 931, a sixth motor 933 for driving the connecting block 932 to reciprocate linearly with respect to the mounting seat 931, and a suction nozzle assembly 934 mounted on the connecting block 932.

In a specific embodiment, a second lifting rail 9311 is fixedly installed on the installation seat 931 in a direction perpendicular to the upper end surface of the storage plate 610; the connecting block 932 is slidably mounted on the second lifting rail 9311; the sixth motor 933 is fixedly mounted on the mounting seat 931, and the sixth motor 933 and the connecting block 932 are in linear transmission connection through a matching mode of a screw rod and a screw nut; the suction nozzle assembly 934 is provided with at least two suction nozzles side by side along the direction perpendicular to the upper end surface of the storage plate 610, and in this embodiment, the suction nozzle assembly 934 is provided with four grooves 6101 corresponding to the storage plate 610.

The following describes the working process of a chip burning system according to the present invention with reference to the accompanying drawings:

for the input buffer mechanism 300, the corresponding first extractor 700 is driven by the first motor 320 to move linearly along the first translation guide 310, so that the first material collector 700 on the input temporary storage mechanism 300 moves between the input end 200 and the corresponding material storage 600, and the third motor 730 in the first material collector 700 drives the suction nozzle 740 to move up and down, thereby transferring the chips to be burned at the input end 200 to the containing slot 6101 on the storing board 610 one by one, the chips are arranged in the accommodating groove 6101 in sequence, the chips arranged on the storage plate 610 not only facilitate the second extractor 930 to capture a plurality of chips at a time, but also position the chips placed on the storage plate 610 at a time through the finely processed accommodating groove 6101, so that the second extractor 930 can be accurately placed in the burning seat 800 after extracting a plurality of chips at a time, and the problem that the conventional chip burning system can only move one chip to the burning seat at a time is solved.

For the transfer mechanism 900, when the storage plate 610 on the storage device 600 in the input temporary storage mechanism 300 is filled, the fourth motor 913 and the fifth motor 923 drive the second material taking device 930 to move between the storage device 600 on the input temporary storage mechanism 300 and the spare burning seat 800, and the sixth motor 933 drives the nozzle assembly 934 to move up and down along the direction perpendicular to the upper end surface of the storage plate 610, and a plurality of nozzles in the nozzle assembly 934 send a plurality of chips on the storage plate 610 to the burning seat 800 together through negative pressure adsorption; when one of the recorders 800 finishes recording, the second picker 930 is driven by the transfer mechanism 900 to pick and place a plurality of chips into the stocker 600 on the output buffer mechanism 500.

For the output temporary storage mechanism 500, when the storage plate 610 on the storage device 600 is filled with the burned chips, the second motor 520 drives the first picker 700 on the output temporary storage mechanism 500 to move between the corresponding storage device 600 and the output end 400, and the third motor 730 in the corresponding first picker 700 drives the suction nozzle 740 to move up and down, and the chips on the storage plate 610 are picked and placed one by the suction nozzle 740 into the chip packaging machine at the position of the output end 400.

Therefore the utility model discloses a chip burns record system has following beneficial effect at least:

wherein, at least one material storage 600 is respectively arranged in the input temporary storage mechanism 300 and the output temporary storage mechanism 500, the material storage 600 comprises a storage plate 610, a plurality of accommodating grooves 6101 are arranged on the storage plate 610 corresponding to the burning seats 800, a first material taking device 700 is respectively and movably arranged in the input temporary storage mechanism 300 and the output temporary storage mechanism 500 corresponding to the material storage 600, so that in the input temporary storage mechanism 300, a plurality of chips can be orderly arranged on the storage plate 610 through the first material taking device 700, the plurality of chips are positioned through the accommodating grooves 6101 on the storage plate 610, so that a nozzle component 934 with a plurality of nozzles in the second material taking device 930 can grab and place the plurality of chips in the input temporary storage mechanism 300 into the burning seats 800, thereby the plurality of chips can be burned at one time, the productivity of the burning system is effectively improved, the plurality of burning seats allow the plurality of chips to be burned simultaneously, further improving the burning efficiency.

In light of the foregoing, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made without departing from the scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (10)

1. The utility model provides a chip burns record system, includes workstation (100), input (200), output (400) and transfer mechanism (900), its characterized in that: the chip burning system further comprises an input temporary storage mechanism (300) positioned at the input end (200), an output temporary storage mechanism (500) positioned at the output end (400) and at least two burning seats (800), the chip burning system further comprises two material accumulators (600) and two first material extractors (700), the material accumulators (600) comprise storage plates (610), a plurality of accommodating grooves (6101) used for bearing and positioning chips are arranged on the storage plates (610), the material accumulators (600) are respectively arranged in the input temporary storage mechanism (300) and the output temporary storage mechanism (500), one of the first material accumulators (700) is arranged in the input temporary storage mechanism (300) and used for conveying the chips to the material accumulators (600) corresponding to the input temporary storage mechanism (300), and the other first material accumulator (700) is movably arranged in the output temporary storage mechanism (500), the chip transfer mechanism (900) is used for transferring chips on the storage device (600) corresponding to the output temporary storage mechanism (500) to the output end (400), and the transfer mechanism (900) comprises a second material taking device (930) used for transferring a plurality of chips between the storage device (600) and the burning seat (800).

2. The system of claim 1, wherein: four accommodating grooves (6101) are distributed along the length direction of the accommodating plate (610).

3. The system of claim 2, wherein: the arrangement structure of the accommodating groove (6101) on the accommodating plate (610) is the same as the arrangement structure of the chip interface on the burning seat (800).

4. The system of claim 1, wherein: the input end (200) is used for being connected with an external chip supply machine, and the output end (400) is used for being connected with an external chip packaging machine.

5. The system of claim 1, wherein: the number of the burning seats (800) is two.

6. The system of claim 1, wherein: the transfer mechanism (900) further includes a first translating member (910) and a second translating member (920).

7. The system of claim 6, wherein: the first translation member (910) comprises a first slide rail (911) fixedly mounted on the workbench (100), a first slide seat (912) connected to the first slide rail (911) in a sliding manner, and a fourth motor (913) for driving the first slide seat (912) to perform linear reciprocating motion on the first slide rail (911).

8. The system of claim 6, wherein: the second translation member (920) comprises a second sliding rail (921) fixedly mounted on the first sliding base (912) and intersecting with the first sliding rail (911), a second sliding base (922) connected to the second sliding rail (921) in a sliding manner, and a fifth motor (923) used for driving the second sliding base (922) to perform linear reciprocating motion on the second sliding rail (921).

9. The system of claim 1, wherein: the second material taking device (930) comprises a mounting seat (931) fixedly mounted on the second sliding seat (922), a connecting block (932) connected to the mounting seat (931) in a sliding mode, a sixth motor (933) used for driving the connecting block (932) to do linear reciprocating motion relative to the mounting seat (931), and a suction nozzle assembly (934) mounted on the connecting block (932).

10. The system of claim 9, wherein: the suction nozzle assembly (934) is provided with four suction nozzles which are in one-to-one correspondence with the accommodating grooves (6101) on the accommodating plate (610).

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