KR20180131792A - Apparatus for aligning chip in dual manner - Google Patents

Abstract

A dual-type chip alignment apparatus comprises: a base body; a pair of chip feeders arranged on the base body and including a first chip feeder providing a first chip on one side and a second chip feeder providing a second chip on the other side facing the one side; a rotary feeder arranged on the base body and transferring the first chip and the second chip; a posture alignment unit including a first posture alignment unit aligning the posture of the first chip provided to the rotary feeder and a second posture alignment unit aligning the posture of the second chip provided to the rotary feeder; and a tray loader having a first tray loader individually changing the location of a first pocket of a first tray to accommodate the first chip by corresponding to the posture of the first chip, and a second tray loader individually changing the location of a second pocket of a second tray to accommodate the second chip by corresponding to the posture of the second chip.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to dual-

The present invention relates to a dual mode chip alignment apparatus.

2. Description of the Related Art [0002] Recently, various semiconductor devices, for example, semiconductor chips having a very small size and having excellent performance have been manufactured by a semiconductor manufacturing process.

Semiconductor chips manufactured in a very small size, such as an inductor among semiconductor devices manufactured by a semiconductor manufacturing process, are individually stored and packed in a pocket formed in a tray, and then shipped.

In order to accommodate a semiconductor chip such as an inductor in a pocket of a tray, a picker for picking up and transferring a semiconductor device is generally used.

1 and 2 are plan views showing the relationship between a semiconductor element transferred by a conventional picker and a tray in which semiconductor elements are housed.

Referring to FIG. 1, a tray 10 in which semiconductor elements 1 and 3 are housed is formed with pockets 2 in which semiconductor elements 1 and 3 are accommodated by a plurality of partition walls formed in a lattice pattern.

1 is transported to the tray 10 by the picker while being rotated at a predetermined angle with respect to the pocket 2 of the tray 10, the semiconductor element 1, The semiconductor element 1 collides with the partition wall of the tray 10 and is broken.

1 is not rotated with respect to the pockets 2 of the tray 10 but is not aligned with the pockets 2 so that the semiconductor elements 3 are held in the pockets 2 in this state , The semiconductor element 3 collides with the partition wall of the tray 10 and is also broken.

2, the semiconductor element 5 is transferred to the tray 10 in the specified posture, but the tray 10 is rotated at a predetermined angle with respect to the semiconductor element 5, 5 is inserted into the pocket 2 of the tray 10, the semiconductor element 3 collides with the partition wall of the tray 10 and is also broken.

Japanese Patent Application Laid-Open No. 10-2015-0123387, Semiconductor Product Packaging Apparatus, (Published Nov. 25, 2015)

The present invention primarily corrects the posture of a semiconductor element by confirming the posture of the semiconductor element and corrects the position and posture of the pocket of the tray into which the posture corrected semiconductor element is to be inserted, There is provided a dual type chip sorting apparatus for preventing damage of a semiconductor element by contacting a semiconductor element with a partition wall of a tray in the process of providing the semiconductor element.

In addition, the present invention provides a dual-type chip sorting apparatus that provides a semiconductor device as a dual type to a tray, thereby greatly improving the alignment, storage, and packaging speed of semiconductor devices.

In one embodiment, the dual chip alignment system includes a base body; A pair of chip feeders disposed on the base body and including a first chip feeder for providing a first chip at one side and a second chip feeder for providing a second chip at the other side opposite to the one side; A rotary feeder disposed on the base body for feeding the first chip and the second chip; A posture aligning unit including a first posture aligning unit for aligning the posture of the first chip provided to the rotary feeder and a second posture aligning unit aligning the posture of the second chip provided to the rotary feeder; A first tray loader for individually changing a position of a first pocket of the first tray so as to accommodate the first chip corresponding to each posture of the first chip, And a second tray loader that individually changes the position of the second pocket of the second tray so that the second chip is received.

The dual-system chip aligning apparatus photographs the first chip having the aligned posture and photographs the first vision unit for generating the posture information of the first chip and the second chip whose posture is aligned, And a second vision unit for generating the second vision unit.

The first vision unit of the dual-system chip alignment apparatus photographs the first chip at a height at which the first chip is unloaded to the first pocket, and the second vision unit captures the second vision unit, The second chip is photographed at a height at which the second chip is unloaded.

The rotary feeder of the dual-system chip sorting apparatus comprises a rotary feeder body formed in an annular shape, a rotary shaft coupled to a rotation center of the rotary feeder body, a circular feeder arranged in a circular shape in the rotor feeder body, And a rotating motor for rotating the rotating shaft.

The chip feeder, the posture aligning unit, and the tray loader of the dual type chip aligning device are symmetrically arranged on the base body with respect to the center of the rotary feeder.

The first tray loader of the dual-system chip aligner includes a first XY table unit for moving the first tray on the base body in the X and Y axes, and a second XY table unit mounted on the first XY table unit, Wherein the second tray loader comprises a second XY table unit for moving the second tray on the base body in the X and Y axes and a second XY table unit mounted on the second XY table unit And a second tray rotating unit for rotating the second tray in a plane.

The first XY table unit and the first tray rotation unit of the dual-system chip alignment apparatus are formed in a plurality, and the second XY table unit and the second tray rotation unit are formed in a plurality.

The posture of the first chip aligned in the first posture aligning unit of the dual type chip aligning apparatus is different for each of the first chips provided in the rotary feeder and the posture of the second chip arranged in the second posture aligning unit Are different from each other on the second chip provided in the rotary feeder.

The dual-chip aligning apparatus according to the present invention primarily corrects the posture of the semiconductor element by checking the posture of the semiconductor element, and adjusts the position and posture of the pockets of the tray to which the posture- The semiconductor element is brought into contact with the partition wall of the tray to prevent breakage of the semiconductor element and to provide the semiconductor element to the tray, thereby greatly improving the alignment, storage and packaging speed of the semiconductor element .

1 and 2 are plan views showing the relationship between a semiconductor element transferred by a conventional picker and a tray in which semiconductor elements are housed.
3 is a plan view of a dual chip alignment apparatus according to an embodiment of the present invention.
Fig. 4 is a sectional view showing the rotary feeder and the vision unit of Fig. 3; Fig.
5 to 8 are views showing the operation of the dual chip alignment apparatus according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The invention, which is set forth below, may be embodied with various changes and may have various embodiments, and specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail.

It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Also, the terms first, second, etc. may be used to distinguish between various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

3 is a plan view of a dual chip alignment apparatus according to an embodiment of the present invention.

The dual chip alignment apparatus 800 includes a base body 100, a chip feeder 200, a rotary feeder 300, an attitude align unit 400, and a tray loader tray loader 500). In addition, the dual-chip alignment apparatus 800 may further include a vision unit 600.

The base body 100 supports and supports the chip feeder 200, the rotary feeder 300, the posture aligning unit 400, and the tray loader 500, which will be described later in detail.

The chip feeder 200 is installed on the base body 100. In one embodiment of the present invention, for example, two chip feeders 200 are installed on the base body 100. Alternatively, two or more chip feeders 200 may be installed on the base body 100 when the number of semiconductor elements that can be transferred from the rotary feeder 300 is large enough.

The chip feeders 200 may be arranged, for example, on the base body 100 in mutually symmetrical shapes.

A chip feeder 200 having a pair of mutually symmetrical shapes draws out a plurality of housed semiconductor elements one by one.

Hereinafter, a chip feeder 200 having a pair of mutually symmetrical shapes is defined as a first chip feeder 210 and a second chip feeder 250.

The first chip feeder 210 is, for example, disposed on the left side of FIG. 3, and the second chip feeder 250 is, for example, disposed on the right side of FIG. The first and second chip feeders 210 and 250 are symmetrically disposed on the left and right sides of the rotary feeder 300.

In one embodiment of the present invention, the first semiconductor chip feeder 210 and the second chip feeder 250 may be provided with the same semiconductor device. Hereinafter, a semiconductor device to be discharged from the first chip feeder 210 is defined as a first chip 215, and a semiconductor device to be discharged from the second chip feeder 250 is defined as a second chip 255 .

The first chip feeder 210 and the second chip feeder 250 discharge the first chip 215 and the second chip 255 in a direction facing each other.

The rotary feeder 300 is disposed on the base body 100 and the rotary feeder 300 includes a first chip feeder 210 and a first chip feeder 210 provided from the second chip feeder 250, 255 to the tray loader 500 to be described later.

The rotary feeder 300 includes a rotary feeder body 310, a rotary shaft 320, a picker 330, and a rotary motor 340.

The rotary feeder body 310 is disposed between the first chip feeder 210 and the second chip feeder 250 so that the first chip feeder 310 and the first chip feeder 310 are disposed in the rotary feeder body 310, And the second chip 255 from the second feeder 250 are provided.

The rotary feeder body 310 may include, for example, a ring-shaped picker mounting portion 315 to which the picker 330 is mounted, and a connecting bar 317 extending from the picker mounting portion 315 to the rotation center have.

The rotary shaft 320 is coupled to the center of rotation of the rotary feeder body 310 and the rotary shaft 320 is coupled in a direction perpendicular to the rotary feeder body 310.

The picker 330 is coupled to the rotary feeder body 310 at equal intervals and the picker 330 is connected to the first chip 215 provided from the first chip feeder 210 and the first chip 215 provided from the second chip feeder 350 The second chip 255 is picked up.

To pick up the first chip 215 and the second chip 255, the picker 330 includes a picker tip 335 which is lowered or raised in the Z-axis direction with respect to the rotary feeder body 310, . ≪ / RTI >

The rotary motor 340 is coupled to the lower end of the rotary shaft 320 and the rotary motor 340 generates a rotary force that continuously or intermittently rotates the rotary shaft 320 clockwise or counterclockwise. In one embodiment of the present invention, the rotary motor 340 rotates the rotary shaft 320, for example, in a clockwise direction.

The posture aligning unit 400 serves to primarily correct the posture of the first chip 215 or the second chip 255 coupled to the picker 330 of the rotary feeder 300.

The posture aligning unit 400 corrects the posture of the first chip 215 or the second chip 255 so that the rotation angle on the plane of the first chip 215 or the second chip 255 is within a specified angle .

In an embodiment of the present invention, the first chip 215 and the second chip 255 whose posture is corrected by the posture aligning unit 400 may be slightly different from the predetermined posture. In addition, in one embodiment of the present invention, the posture aligning unit 400 may include a function of reversing the upper and lower surfaces of the first chip 215 and the second chip 255, and the like.

The posture aligning unit 400 includes a first posture aligning unit 410 disposed adjacent to the first chip feeder 210 and a second posture aligning unit 410 disposed adjacent to the second chip feeder 250, (450).

In one embodiment of the present invention, the first posture aligning unit 410 and the second posture aligning unit 450 may be formed on both sides of the rotary feeder 300.

The first posture aligning unit 410 may be configured such that the picker 330 picks up the first chip 215 at the first chip feeder 210 and then moves the first chip 215 before reaching the vision unit 600, And corrects or aligns the posture of the user.

The first posture aligning unit 410 can calibrate the position of the first chip 215 while contacting the side of the first chip 215 that is attracted to the picker tip 335 of the picker 330.

As the first posture aligning unit 410 comes into contact with the first chip 215, the picker tip 335 that picked up the first chip 215 of the picker 330 is rotated in a plane, The position or posture is corrected.

The second posture aligning unit 450 may be configured such that the picker 330 picks up the second chip 255 in the second chip feeder 250 and then moves the second chip 255 before reaching the vision unit 600, And corrects or aligns the posture of the user.

The second posture aligning unit 450 can calibrate the position of the second chip 255 while contacting the side of the second chip 255 adsorbed to the picker 330.

As the second posture aligning unit 450 contacts the second chip 255, the part of the picker tip 335 which attracted the second chip 255 of the picker 330 is rotated, Or posture is corrected.

The posture of the first chip 215 aligned in the first posture aligning unit 410 is different for each first chip 215 provided in the rotary feeder 300, The posture of the second chip 255 aligned in the second feeder 450 is different for each second chip 255 provided in the rotary feeder 300.

For this reason, an embodiment of the present invention requires a tray loader 500 to be described later in addition to the first and second posture aligning units 410 and 450, and the tray loader 500 will be described later.

3 and 4, the vision unit 600 includes a first posture aligning unit 450 and a first posture aligning unit 450. The first posture aligning unit 410 includes a first chip 215 and a second posture aligning unit 450, And the second chip 255 is photographed to generate attitude information of the first chip 215 and the second chip 255, respectively.

The posture information generated in the vision unit 600 is interlocked with the operation of the tray loader 500 to be described later.

The vision unit 600 includes a first vision unit 610 and a second vision unit 620. The first vision unit 610 and the second vision unit 620 are installed in the base body 100 .

The first vision unit 610 is installed in the base body 100 adjacent to the first orientation aligning unit 410 and the first vision unit 610 includes a first chip 215 fixed to the picker 330 The photograph is taken in the direction from the bottom to the top.

The second vision unit 620 is installed on the base body 100 adjacent to the second orientation aligning unit 450 and the second vision unit 620 includes a second chip 255 fixed to the picker 330 The photograph is taken in the direction from the bottom to the top.

In particular, in one embodiment of the present invention, the first and second vision units 610 and 620 are fixed to the picker 330 with the picker 330 being driven downward as shown in FIG. The first chip 215 and the second chip 255 are photographed to reduce the positional deviation of the first and second chips 215 and 255 that may be generated when the picker 330 is disposed obliquely with respect to the vertical direction, Is a very important technology in.

The tray loader 500 serves to house the first chip 215 and the second chip 255, whose posture is corrected by the posture aligning unit 400, in the tray.

The tray loader 500 includes a first tray loader 510 and a second tray loader 550. The first and second tray loaders 510 and 550 are disposed on the upper surface of the base body 100, respectively.

The first tray loader 510 drives the first tray 512 to allow the first chip 215 to be housed in the first tray 512. The first tray loader 510 has a plurality of first trays 512, (512) may be disposed.

Each of the first trays 512 includes a plurality of first pockets 515 arranged in a matrix to accommodate a plurality of the first chips 215. The first pockets 515 are arranged in the horizontal and vertical directions Are formed by the partition walls formed.

The first tray loader 510 includes a first XY table unit 520 and a first tray rotation unit 530.

The first XY table unit 520 allows the first tray 512 to be transported in the X and Y axis directions and the first XY table unit 520 transports the first tray 512 in the XY axis direction You can include an XY table that you can do.

The first tray rotation unit 530 is mounted on the first XY table unit 520 and the first tray rotation unit 530 is conveyed together with the first XY table unit 520.

A first tray 512 is mounted on the first tray rotating unit 530 and a number corresponding to the number of the first trays 512 is mounted on the first XY table unit 520 Respectively.

The first tray rotating unit 530 rotates the first tray 512 at a predetermined angle in a clockwise or counterclockwise direction on a plane.

The first tray 512 disposed in the first tray rotation unit 530 by the first XY table unit 520 and the first tray rotation unit 530 can be freely deformed in the plane.

The second tray loader 550 drives the second tray 552 to accommodate the second chip 255 in the second tray 552 and the second tray loader 550 is provided with a plurality of second trays (Not shown).

Each second tray 552 includes a plurality of second pockets 555 arranged in a matrix to accommodate a plurality of second chips 255. The second pockets 555 include a plurality of second pockets 555, Are formed by the partition walls formed.

The second tray loader 550 includes a second XY table unit 560 and a second tray rotation unit 570.

The second XY table unit 560 allows the second tray 552 to be transported in the X and Y axis directions while the second XY table unit 560 transports the second tray 552 in the XY axis direction You can include an XY table that you can do.

The second tray rotating unit 570 is mounted on the second XY table unit 560 and the second tray rotating unit 570 is carried together with the second XY table unit 560. [

The second tray rotating unit 570 is mounted on the second tray rotating unit 570 and the second tray rotating unit 570 is mounted on the second XY table unit 560 in a number corresponding to the number of the second trays 552 Respectively.

The second tray rotating unit 570 rotates the second tray 552 clockwise or counterclockwise on the plane at a predetermined angle.

Accordingly, the second tray 552 disposed in the second tray rotation unit 570 by the second XY table unit 560 and the second tray rotation unit 570 can be freely deformed in the plane.

5 to 8 are views showing the operation of the dual chip alignment apparatus according to an embodiment of the present invention.

3, in order to store the first chip 215 and the second chip 255 in the tray loader 500 in the dual chip alignment apparatus 800, the first chip feeder 210, A second chip feeder 215 is provided, and a second chip 255 is provided from the second chip feeder 250.

In an embodiment of the present invention, the first chip 215 provided from the first chip feeder 210 and the second chip 255 provided from the second chip feeder 250 may be the same product.

The first chip 215 and the second chip 255 are provided to the rotary feeder 300 and the first chip 215 and the second chip 255 are picked up by the picker 330 and then the rotary feeder 300 .

The first chip 215 is primarily aligned by the first orientation aligning unit 410 and the second chip 255 is primarily aligned by the second orientation aligning unit 450. [ At this time, the postures of the first chip 215 and the second chip 255 are not the same and can be aligned in different postures.

The first chip 215 whose posture is aligned in the first posture aligning unit 410 is transferred to the first vision unit 610 and the first vision unit 610 images the first chip 215.

5, the first chip 215 photographed by the first vision unit 610 is arranged to be shifted in the X and Y axis directions from the reference position indicated by a dotted line, and furthermore, It is in a rotated state.

The image photographed by the first vision unit 610 is processed by an image processing apparatus (not shown) or the like to generate attitude information of the first chip 215.

 On the other hand, the second chip 255 whose posture is aligned in the second posture aligning unit 450 is transferred to the second vision unit 620, and the second vision unit 620 photographs the second chip 255 .

6, the second chip 255 photographed by the second vision unit 620 is arranged to be shifted in the X-axis and Y-axis directions from a reference position indicated by a dotted line. In addition, In the counterclockwise direction.

The image photographed by the second vision unit 620 is processed by an image processing apparatus (not shown) or the like to generate attitude information of the second chip 255.

The attitude information of the first chip 215 generated by the image photographed by the first vision unit 610 and the attitude information of the second chip 255 generated by the image photographed by the second vision unit 620 The first tray loader 510 and the second tray loader 550, respectively.

The first tray loader 510 changes the posture of the first tray 512 in accordance with the posture information of the first chip 215 so that the first chip 215 is moved to the first pocket 515 of the first tray 512 So that it can be accurately stored without being collided with the partition wall.

In order to realize this, the first tray loader 510 may move the first XY table unit 510 (510) according to the XY coordinate shifted with respect to the reference position and the rotated angle of the attitude information of the first chip 215 And the first tray rotation unit 520 to change the posture of the first tray 512 according to the posture of the first chip 215. [

The first chip 215 picked up in the picker 330 is accommodated in the designated first pocket 515 of the first tray 512.

The second tray loader 550 changes the posture of the second tray 552 in correspondence with the posture information of the second chip 255 so that the second chip 555 is inserted into the second pocket 555 of the second tray 552, ) Can be stored correctly.

In order to realize this, the second tray loader 550 moves the second XY table unit 560 (refer to FIG. 8) according to the shifted XY coordinate and the rotated angle with respect to the reference position among the attitude information of the second chip 255, And the second tray rotating unit 570 to change the posture of the second tray 552 in accordance with the posture of the second chip 255.

The second chip 255 picked up in the picker 330 is accommodated in a designated second pocket 555 of the second tray 552.

The first tray 512 containing the first chip 215 and the second tray 555 containing the second chip 255 are packed in a subsequent process and then shipped.

As described above in detail, the posture of the semiconductor element is firstly checked by confirming the posture of the semiconductor element, and the position and the posture of the tray where the semiconductor element whose posture is to be corrected is to be inserted correspond to the posture of the semiconductor element The semiconductor element is brought into contact with the partition wall of the tray to prevent breakage of the semiconductor element and to provide the semiconductor element to the tray, thereby greatly improving the alignment, storage and packaging speed of the semiconductor element .

It should be noted that the embodiments disclosed in the drawings are merely examples of specific examples for the purpose of understanding, and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

100 ... base body 200 ... chip feeder
300 ... rotary feeder 400 ... posture aligning unit
500 ... tray loader 600 ... vision unit

Claims (8)

A base body;
A pair of chip feeders disposed on the base body and including a first chip feeder for providing a first chip at one side and a second chip feeder for providing a second chip at the other side opposite to the one side;
A rotary feeder disposed on the base body for feeding the first chip and the second chip;
A posture aligning unit including a first posture aligning unit for aligning the posture of the first chip provided to the rotary feeder and a second posture aligning unit aligning the posture of the second chip provided to the rotary feeder; And
A first tray loader for individually changing a position of a first pocket of the first tray so as to accommodate the first chip corresponding to each posture of the first chip, And a tray loader having a second tray loader for individually changing a position of a second pocket of the second tray so that two chips are accommodated. The method according to claim 1,
A first vision unit for capturing the first chip with the posture aligned and generating the posture information of the first chip and a second vision for capturing the posture information of the second chip by photographing the second chip with the posture aligned, Further comprising a vision unit including the unit. 3. The method of claim 2,
The first vision unit captures the first chip at a height at which the first chip is unloaded to the first pocket,
Wherein the second vision unit captures the second chip at a height at which the second chip is unloaded to the second pocket. The method according to claim 1,
The rotary feeder includes a rotary feeder body formed in an annular shape, a rotary shaft coupled to a rotation center of the rotary feeder body, pickers circularly arranged on the rotor feeder body and vertically lifted up to pick up the first and second chips, And a rotating motor for rotating the rotating shaft. The method according to claim 1,
Wherein the chip feeder, the posture aligning unit, and the tray loader are symmetrically arranged on the base body with respect to a center of the rotary feeder. The method according to claim 1,
The first tray loader includes a first XY table unit for moving the first tray on the X and Y axes on the base body and a second XY table unit mounted on the first XY table unit for rotating the first tray in a plane Comprising a rotating unit,
The second tray loader includes a second XY table unit for moving the second tray in the X and Y axes on the base body and a second XY table unit mounted on the second XY table unit for rotating the second tray in a plane And a rotating unit. The method according to claim 6,
Wherein the first XY table unit and the first tray rotating unit are formed in a plurality,
Wherein the second XY table unit and the second tray rotating unit are formed in a plurality. The method according to claim 1,
The posture of the first chip aligned in the first posture aligning unit is different for each first chip provided in the rotary feeder,
And the posture of the second chip aligned in the second posture aligning unit is different for each of the second chips provided in the rotary feeder.

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