CN216686204U

CN216686204U - Chip packaging colloidal particle arrangement feeding mechanism

Info

Publication number: CN216686204U
Application number: CN202123240643.8U
Authority: CN
Inventors: 戈勇; 李峰
Original assignee: Dongguan Huamao Precision Machinery Technology Co ltd
Current assignee: Dongguan Huamao Precision Machinery Technology Co ltd
Priority date: 2021-12-22
Filing date: 2021-12-22
Publication date: 2022-06-07
Anticipated expiration: 2031-12-22

Abstract

The utility model discloses an arrangement feeding mechanism of chip packaging colloidal particles, which relates to the technical field of chip processing and comprises an operation table and a vibration disc, wherein symmetrical Y-axis moving assemblies are arranged at two sides of the top of the operation table, the tops of the two Y-axis moving assemblies are commonly connected with an X-axis moving assembly, one side of the X-axis moving assembly is connected with a feeding assembly, the upper end of the operation table and the position corresponding to the vibration disc are provided with a feeding assembly, the vibration disc and a first motor are started to drive a feeding plate to move along the direction of a first linear slide rail and sequentially sequence and feed the colloidal particles into corresponding material grooves, when an inductor senses the colloidal particles at the forefront end, the first motor can stop rotating, so that the next procedure operation is convenient, the structure is operated in the whole process, more time-saving and labor-saving, simultaneously achieves the effect of arrangement feeding, and effectively ensures the quantity and the efficiency of feeding, and the setting of baffle can carry on spacingly to the micelle of material loading, prevents to drop from one side.

Description

Chip packaging colloidal particle arrangement feeding mechanism

Technical Field

The utility model relates to the technical field of chip processing, in particular to a distributing and feeding mechanism for chip packaging colloidal particles.

Background

Currently, the colloidal particles used for chip packaging are generally divided into two feeding modes, one is manual feeding, and the other is machine feeding, but the two feeding modes have the following defects in practical use:

manual feeding: the time and the labor are wasted, the feeding efficiency is low, and the labor input cost is high.

Machine feeding: only one colloidal particle can be loaded at a time, and the quantity of the loaded colloidal particles cannot be guaranteed, so that the processing efficiency is reduced.

In order to solve the above problems, workers in the field have proposed a feeding mechanism for arranging chip packaging colloidal particles.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects of the prior art, the utility model provides a distributing and feeding mechanism for chip packaging colloidal particles, which solves the problems that manual feeding is time-consuming and labor-consuming, the feeding efficiency is low, the labor input cost is high, only one colloidal particle can be fed by a machine during feeding, the feeding quantity cannot be guaranteed, and the processing efficiency is reduced.

In order to achieve the purpose, the utility model is realized by the following technical scheme: a chip packaging colloidal particle arrangement feeding mechanism comprises an operation table and a vibration disc, wherein symmetrical Y-axis moving assemblies are mounted on two sides of the top of the operation table, the tops of the two Y-axis moving assemblies are connected with an X-axis moving assembly, one side of the X-axis moving assembly is connected with a feeding assembly, and a feeding assembly is mounted at the upper end of the operation table and corresponds to the vibration disc;

the material loading subassembly includes bottom plate, baffle and support, the inductor is installed at the top of support, first motor is installed to the rear side one end of bottom plate, the power drive end of first motor has cup jointed first action wheel, first linear slide rail is installed at the top of bottom plate, the outside sliding connection of first linear slide rail has first slide, the upper end of first slide is passed through the connecting plate and is connected the flitch, the rear side of going up the flitch is seted up and is equipped with the equidistant silo of a plurality of, the axle bed is installed at the top of bottom plate and the one end of keeping away from first motor, the internal rotation of axle bed is connected with first from the driving wheel, first from the common cover in outside of driving wheel and first action wheel being equipped with first belt, the top block of first belt has first cardboard, and the top of first cardboard meets with the bottom of connecting plate.

According to a further technical scheme, the feeding assembly comprises a vertical plate and a second motor, a second driving wheel and a second driven wheel are respectively connected to the front side of the vertical plate in a rotating mode from top to bottom, a second belt is sleeved outside the second driving wheel and the second driven wheel together, one side of the second belt and a side plate form a fixed connection structure through the second clamping plate, a feeding plate is installed at the bottom of the front side of the side plate, and a plurality of sucking discs which are equidistant are installed inside the feeding plate.

As a further technical scheme of the utility model, a kidney-shaped hole is formed in the baffle at the position flush with the inductor, and the rear side of the feeding plate is attached to the front side of the baffle.

As a further technical scheme, the power driving end of the second motor is connected with the second driving wheel, and a second linear sliding rail is mounted on the front side of the vertical plate and on one side of the second clamping plate.

As a further technical solution of the present invention, a second slide carriage is slidably connected to an exterior of the second linear slide rail, and a front side of the second slide carriage is connected to a rear side of the side plate.

As a further technical scheme of the utility model, the Y-axis moving assembly and the X-axis moving assembly have the same structure, and the length of the baffle is the same as that of the feeding plate.

Advantageous effects

The utility model provides a distributing and feeding mechanism for chip packaging colloidal particles. Compared with the prior art, the method has the following beneficial effects:

1. the utility model provides a chip package micelle's feed mechanism that arranges, through starting vibration dish and first motor, can drive the direction of flitch along first linear slide rail and remove, and send into the silo that corresponds with the micelle sequencing in proper order, when the inductor senses the micelle of foremost, but first motor stall, thereby be convenient for next process operation, compare with traditional artifical material loading's mode, whole journey automation operation of this structure, labour saving and time saving more, the effect of arranging the material loading has been reached simultaneously, the effectual quantity and the efficiency of guaranteeing the material loading, and the setting of baffle, can carry on spacingly to the micelle of material loading, prevent to drop from one side.

2. The utility model provides a feed mechanism that arranges of chip encapsulation micelle, at the second action wheel, the second is from the driving wheel, under the effect of second belt and second cardboard, through starting the second motor, can drive curb plate and feed plate and go up and down along the direction of second linear slide rail, move under mutually supporting of subassembly and X axle removal subassembly at the Y axle simultaneously, can make the sucking disc grab the micelle from the silo and take out, reach the effect of automatic unloading, and send the tool to fast in, be convenient for follow-up chip encapsulation.

Drawings

Fig. 1 is a schematic structural view of a distributing and feeding mechanism of chip packaging colloidal particles;

fig. 2 is a schematic structural diagram of a feeding assembly of a distributing and feeding mechanism of chip packaging colloidal particles;

fig. 3 is a schematic structural diagram of a feeding assembly of a chip packaging colloidal particle arranging and feeding mechanism.

In the figure: 1. an operation table; 2. a vibrating pan; 3. a Y-axis moving assembly; 4. an X-axis moving assembly; 5. a feeding assembly; 51. a vertical plate; 52. a second motor; 53. a second drive wheel; 54. a second driven wheel; 55. a second belt; 56. a second clamping plate; 57. a side plate; 58. a feeding plate; 59. a suction cup; 510. a second linear slide rail; 511. a second slide carriage; 6. a feeding assembly; 61. a base plate; 62. a baffle plate; 63. a support; 64. an inductor; 65. a first motor; 66. a first linear slide rail; 67. a first slider; 68. a connecting plate; 69. a shaft seat; 610. a first driven wheel; 611. a first drive wheel; 612. a first belt; 613. a first clamping plate; 614. feeding plates; 615. a trough; 616. a waist-shaped hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, the present invention provides a technical solution of a distributing and feeding mechanism for chip packaging colloidal particles: the utility model provides a chip packaging micelle's feed mechanism that arranges, including operation panel 1 and vibration dish 2, symmetrical Y axle removal subassembly 3 is installed to the top both sides of operation panel 1, two Y axle removal subassembly 3's top is connected with X axle removal subassembly 4 jointly, Y axle removal subassembly 3 is the same with X axle removal subassembly 4's structure, Y axle removal subassembly 3 and X axle removal subassembly 4's theory of operation all realize removing through the motor drive lead screw driven mode, one side of X axle removal subassembly 4 is connected with pay-off subassembly 5, upper end and the corresponding department with vibration dish 2 of operation panel 1 install material loading subassembly 6.

Referring to fig. 2, the feeding assembly 6 includes a bottom plate 61, a baffle 62 and a support 63, an inductor 64 is installed on the top of the support 63, a first motor 65 is installed at one end of the rear side of the bottom plate 61, a first driving wheel 611 is sleeved at a power driving end of the first motor 65, a first linear slide rail 66 is installed on the top of the bottom plate 61, a first slide seat 67 is slidably connected to the outside of the first linear slide rail 66, the upper end of the first slide seat 67 is connected to a feeding plate 614 through a connecting plate 68, a plurality of equidistant material troughs 615 are formed on the rear side of the feeding plate 614, a shaft seat 69 is installed on the top of the bottom plate 61 and one end far away from the first motor 65, a first driven wheel 610 is rotatably connected to the inside of the shaft seat 69, a first belt 612 is commonly sleeved on the outside of the first driven wheel 610 and the first driving wheel 611, a first clamping plate 613 is clamped on the top of the first belt 612, and the top of the first clamping plate 613 is connected to the bottom of the connecting plate 68, baffle 62's inside and the department of flushing mutually with inductor 64 has seted up waist shape hole 616, the rear side of going up flitch 614 is laminated with baffle 62's front side mutually, through starting vibration dish 2 and first motor 65, can drive the direction of going up flitch 614 along first linear slide rail 66 and remove, and send into corresponding silo 615 with the micelle in proper order in the sequencing, when inductor 64 senses the micelle of foremost, first motor 65 stall, thereby be convenient for next process operation, compare with the mode of traditional artifical material loading, this structure full automation operation, labour saving and time saving more, the effect of arranging the material loading has been reached simultaneously, the effectual quantity and the efficiency of guaranteeing the material loading, and the setting of baffle, can be spacing to the micelle of material loading, prevent to drop from one side.

Referring to fig. 3, the feeding assembly 5 includes a vertical plate 51 and a second motor 52, a second driving wheel 53 and a second driven wheel 54 are respectively rotatably connected to the front side of the vertical plate 51 from top to bottom, a second belt 55 is sleeved outside the second driving wheel 53 and the second driven wheel 54 together, one side of the second belt 55 forms a fixed connection structure with a side plate 57 through the second clamping plate 56, a feeding plate 58 is installed at the bottom of the front side of the side plate 57, a plurality of equidistant suction cups 59 are installed inside the feeding plate 58, the number of the suction cups 59 is the same as that of the troughs 615, a power driving end of the second motor 52 is connected to the second driving wheel 53, a second linear slide rail 510 is installed at one side of the second clamping plate 56 and at the front side of the vertical plate 51, a second slide carriage 511 is slidably connected to the outside of the second linear slide rail 510, the front side of the second slide carriage 511 is connected to the rear side of the side plate 57, the length of the baffle 62 is the same as that of the feeding plate 614, under the effect of second action wheel 53, second from driving wheel 54, second belt 55 and second cardboard 56, through starting second motor 52, can drive curb plate 57 and feed plate 58 and go up and down along the direction of second linear slide rail 510, move under mutually supporting of subassembly 3 and the X axle removal subassembly 4 in the Y axle simultaneously, can make sucking disc 59 grab the micelle from silo 615 and take out, reach the effect of automatic unloading, and send the tool to fast in, be convenient for follow-up chip encapsulation.

The working principle of the utility model is as follows: in use, the initial trough 615 at the end side of the upper material plate 614 and the baffle plate 62 are firstly attached to each other, moved to the outer side of the baffle plate 62, then the vibration plate 2 is started, the colloidal particles inside the first trough 615 are fed into the first trough by vibration, and at the same time, the first motor 65 is started, under the action of the first driving wheel 611 and the first driven wheel 610, the first belt 612 can be driven to rotate, and with the rotation of the first belt 612, under the action of the first catch plate 613, the connecting plate 68 and the feeding plate 614 are driven to move continuously along the direction of the first linear slide 66, when the outer side surface of the first trough 615 is attached to the baffle 62, the next colloidal particles enter the second trough 615 in sequence, when the outer side surface of the second trough 615 is attached to the baffle 62, the next colloidal particles sequentially enter the third trough 615, and the colloidal particles are continuously moved in this way, so that the effect of sequentially arranging and feeding the colloidal particles can be achieved.

Along with the movement of the feeding plate 614, when the sensor 64 senses the rubber particles at the forefront, the first motor 65 can stop rotating, the feeding assembly 5 can be moved to the position right above the feeding plate 614 under the action of the Y-axis moving assembly 3 and the X-axis moving assembly 4, finally, the suction cup 59 is connected with an external air pump through a connecting pipe, the second motor 52 is started, and the side plate 57 and the feeding plate 58 can be driven to descend along the direction of the second linear slide rail 510 under the action of the second driving wheel 53, the second driven wheel 54, the second belt 55, the second clamping plate 56 and the second slide seat 511, so that the suction cup 59 can be prompted to grab the rubber particles at the corresponding position from the trough 615 and quickly send the rubber particles to a jig for chip packaging.

Claims

1. The arrangement feeding mechanism for the chip packaging colloidal particles comprises an operating platform (1) and a vibrating disc (2), and is characterized in that symmetrical Y-axis moving assemblies (3) are mounted on two sides of the top of the operating platform (1), the tops of the two Y-axis moving assemblies (3) are connected with an X-axis moving assembly (4) together, one side of the X-axis moving assembly (4) is connected with a feeding assembly (5), and a feeding assembly (6) is mounted at the upper end of the operating platform (1) and corresponds to the vibrating disc (2);

the feeding assembly (6) comprises a bottom plate (61), a baffle (62) and a support (63), an inductor (64) is installed at the top of the support (63), a first motor (65) is installed at one end of the rear side of the bottom plate (61), a first driving wheel (611) is sleeved at the power driving end of the first motor (65), a first linear sliding rail (66) is installed at the top of the bottom plate (61), a first sliding seat (67) is connected to the outer portion of the first linear sliding rail (66) in a sliding manner, an upper material plate (614) is connected to the upper end of the first sliding seat (67) through a connecting plate (68), a plurality of equidistant material grooves (615) are formed in the rear side of the material feeding plate (614), a shaft seat (69) is installed at the top of the bottom plate (61) and at one end far away from the first motor (65), and a first driven wheel (610) is connected to the inner portion of the shaft seat (69), the first driven wheel (610) and the first driving wheel (611) are sleeved with a first belt (612) together, a first clamping plate (613) is clamped at the top of the first belt (612), and the top of the first clamping plate (613) is connected with the bottom of the connecting plate (68).

2. The chip packaging colloidal particle arranging and feeding mechanism according to claim 1, wherein the feeding component (5) comprises a vertical plate (51) and a second motor (52), a second driving wheel (53) and a second driven wheel (54) are respectively and rotatably connected to the front side of the vertical plate (51) from top to bottom, a second belt (55) is sleeved outside the second driving wheel (53) and the second driven wheel (54), one side of the second belt (55) forms a fixed connection structure with the side plate (57) through the second clamping plate (56), a feeding plate (58) is installed at the bottom of the front side of the side plate (57), and a plurality of sucking discs (59) with equal distances are installed inside the feeding plate (58).

3. The chip packaging glue particle arranging and feeding mechanism of claim 1, wherein a kidney-shaped hole (616) is formed in the baffle (62) at the position flush with the inductor (64), and the rear side of the feeding plate (614) is attached to the front side of the baffle (62).

4. The chip packaging glue particle arranging and feeding mechanism according to claim 2, wherein the power driving end of the second motor (52) is connected with the second driving wheel (53), and a second linear sliding rail (510) is mounted on the front side of the vertical plate (51) and on one side of the second clamping plate (56).

5. The chip packaging glue particle arranging and feeding mechanism of claim 4, wherein a second slide carriage (511) is slidably connected to the outside of the second linear slide rail (510), and the front side of the second slide carriage (511) is connected to the rear side of the side plate (57).

6. The chip packaging glue bump arrangement feeding mechanism as claimed in claim 1, wherein the Y-axis moving assembly (3) and the X-axis moving assembly (4) have the same structure, and the length of the baffle (62) is the same as that of the feeding plate (614).