KR20190106098A - Vision inspection module, device inspection system having the same and device inspection method using the same - Google Patents

Abstract

The present invention relates to a vision inspection module, a device inspection system having the same and a device inspection method using the same and, more specifically, to a vision inspection module, a device inspection system having the same and a device inspection method using the same which perform vision inspection on semiconductor devices. The vision inspection module (100) performs vision inspection of a device (1) having a rectangular plane shape, and comprises: an image acquisition unit (110) to acquire an image of the device (1); and a light path forming unit (120) to selectively form a first light path (L1) to allow a first plane image for a first plane of the device (1) to reach the image acquisition unit (110), and a pair of second light paths (L2) to allow a pair of side images for a pair of sides of the device (1) facing each other to reach the image acquisition unit (110).

Description

Vision inspection module, device inspection system having the same and device inspection method using the same {Vision inspection module, device inspection system having the same and device inspection method using the same}

The present invention relates to a vision inspection module, a device inspection system having the same, and a device inspection method using the same, and more particularly, a vision inspection module for performing a vision inspection on a semiconductor device, a device inspection system having the same and a device inspection using the same. It is about a method.

After completion of the package process, the semiconductor device is loaded into a tray and shipped after completion of inspection such as burn-in test.

The semiconductor device undergoes a marking process for displaying a serial number, a logo of a manufacturer's logo, etc. on the surface of the semiconductor device before shipment, and finally, whether a lead or a ball grid is damaged, The process of inspecting the appearance of the semiconductor device, such as cracks, scratches, chipped off, etc., and whether the markings formed on the surface are good or not.

Conventionally, an inspection process for inspecting an outer surface of a semiconductor device generally involves capturing images of one surface of the semiconductor device and four sides adjacent to the surface of the semiconductor device at a time by using one image acquisition means (for example, a camera). This is done by obtaining an image.

For example, a device for performing vision inspection of a conventional semiconductor device may be configured as a vision inspection module of Korean Patent Laid-Open No. 10-2017-0024808.

In the conventional vision inspection module, the planar image and the four side images of the device must be contained in the limited inspection area (the light receiving surface of the image acquisition means), so that a total of five images are included. ) Needs to be sufficiently secured.

However, in order to maintain a certain resolution or more and to secure a large FOV, expensive image acquisition means must be used, resulting in a high cost of the device.

In addition, since the optical paths to the plane of the image acquisition means and the element and the optical paths to the side of the image acquisition means and the element are different from each other, there is no separate focal length correction means for compensating such optical path difference. There is a problem that a sharp image cannot be obtained because it is out of focus.

In addition, even if a separate focal length correction means is provided, the device configuration is complicated, the manufacturing cost of the device is increased, and the optical path is changed when the size of the semiconductor element to be inspected is changed so that the focal length correction means or other optical There is a problem that the members (reflective members, etc.) need to be replaced.

An object of the present invention is to recognize the above problems can utilize the image acquisition device having a minimum FOV to minimize the cost and manufacturing cost of the device, a vision inspection module, a device inspection system having the same and a device inspection method using the same To provide.

In addition, an object of the present invention, by independently obtaining the planar image and the side image of the device, to provide a separate configuration for compensating for the path difference between the first optical path for the planar image and the second optical path for the side image There is no need to provide a vision inspection module, a device inspection system having the same, and a device inspection method using the same, which can simplify the structure of the device and reduce the manufacturing cost.

It is also an object of the present invention to obtain only an image of a pair of opposing pairs of four sides of a device whose plane shape is rectangular, so that even if the size of the device to be inspected varies, The present invention provides a vision inspection module, a device inspection system having the same, and a device inspection method using the same.

The present invention was created in order to achieve the object of the present invention as described above, as a vision inspection module 100 for performing a vision inspection of the device 1 of a planar rectangular shape, to obtain an image of the device (1) The first optical path L1 and the device 1 opposing the image acquisition unit 110 and the first plane image of the first plane of the device 1 to reach the image acquisition unit 110. And a light path forming unit 120 for selectively forming a pair of second light paths L2 for allowing a pair of side images of the pair of side surfaces to reach the image acquisition unit 110, The optical path forming unit 120 may include a pair of first reflecting members corresponding to a pair of opposite sides of the device 1 and reflecting a pair of side images in parallel to a normal direction of the first plane ( 122 is fixed to the fixed frame portion 126 is installed, and moves relative to the fixed frame portion 126 Vision inspection module 100, characterized in that it comprises a movable frame portion 128 to be selectively installed to selectively form the first optical path (L1) and the pair of second optical path (L2) according to the position. Initiate.

The moving frame unit 128 may include a “first position at which the first optical path L1 is formed” and “a pair of second optical paths L2” formed at the fixed frame unit 126. Can be movably coupled between two positions ".

The second position may be set at a position at which the moving frame unit 128 blocks the first plane image so that the first plane image does not reach the image acquisition unit 110.

The moving frame unit 128 may include the pair of first reflecting members 122 such that the pair of side images reach the vicinity of the central portion of the light receiving surface S of the image acquisition unit 110 at the second position. ) May include a plurality of second reflecting members 124 reflecting the pair of side images reflected by the light toward the image acquisition unit 110.

The first position may be set at a position where the moving frame unit 128 does not interfere with the first plane image and the pair of side images.

The movable frame 128 may be linearly coupled to the fixed frame 126 in a plane direction perpendicular to the normal direction.

The optical path forming unit 120 may further include a guide part 129 for guiding linear movement of the moving frame part 128 with respect to the fixed frame part 126.

The fixed frame part 126 may include a plurality of pairs of the first reflecting members 122 to perform vision inspection on the plurality of devices 1.

The vision inspection module 100 may further include a focus adjusting unit 130 that adjusts the focus by adjusting the position of the image acquisition unit 110.

The vision inspection module 100 is installed between the optical path forming unit 120 and the image acquisition unit 110 to provide the image acquisition unit 110 with the first plane image and the pair of side images. It may further include a main reflecting member 140 for reflecting toward.

The main reflection member 140 may be made of a transflective material that can transmit light.

The vision inspection module 100 may further include an illumination unit 150 for irradiating light to the first plane and each side surface of the device 1 on the rear surface of the reflective surface of the main reflection member 140. .

In addition, the present invention is a device inspection method performed in the vision inspection module 100 for performing a vision inspection of the device (1) having a planar rectangular shape, the pair of first reflecting member by a transfer tool for device transfer A first planar image acquisition step of acquiring a first planar image of the device 1 located between the 122 and the image acquisition unit 110; and the pair of four side surfaces of the device 1; A first side image acquisition step of acquiring a pair of side images of a pair of side surfaces facing the first reflective member 122 of the through the image acquisition unit 110, and the other of the four sides The image acquisition unit 110 is rotated about the central axis perpendicular to the first plane by the transfer tool such that the pair of side surfaces face the pair of first reflecting members 122. Acquire a pair of side images for the remaining pair of sides through Discloses a device testing method comprising the acquisition step second side image.

In the device vision inspection method, before the first side image acquisition step, the first plane image acquired in the first plane image acquisition step is located between the pair of first reflecting members 122. An alignment step of aligning the position of the device 1 may be further included.

The first planar image acquisition step may be performed in a state where the moving frame unit 128 is located at a first position that does not interfere with the first planar image and the pair of side images.

In the first side image acquisition step and the second side image acquisition step, the moving frame unit 128 blocks the first plane image so that the first plane image does not reach the image acquisition unit 110. It may be performed after moving to the second position.

In addition, the present invention, the loading unit 10 is loaded with a tray (2) is loaded with a plurality of elements (1); A vision inspection module 100 installed at one side of the loading unit 10 to perform vision inspection on the device 1; The first device picks up the device 1 from the tray 2 of the loading unit 10 and transfers the device 1 to the vision inspection module 50, and transfers and loads the device 1 after the vision inspection to the tray 2. Disclosed is a device inspection system comprising a transfer tool 20.

The device inspection system may further include an unloading unit 30 for unloading the trays 2 on which the devices 1 that have completed the vision inspection are loaded.

The first transfer tool 20 is coupled to the main body portion 21 and the main body portion 21 to attract and secure the rear surface (hereinafter referred to as a second plane) of the first plane of the device 1 or more It may include a plurality of pickers 22 arranged in rows.

The first transfer tool 20 may further include a picker rotation driver for rotating the picker 22 about a central axis parallel to the normal direction of the first plane.

The first transfer tool 20 may be configured such that a plurality of elements 1 picked up by a plurality of pickers 22 arranged in a row are sequentially positioned between the pair of first reflecting members 122. It may further include a linear moving drive for linearly moving the body portion (21).

The vision inspection module according to the present invention, the device inspection system having the same, and the device inspection method using the same, by independently obtaining the planar image and the side image of the device, it is possible to utilize the image acquisition device having a minimum FOV, the cost of the device and There is an advantage to minimize the manufacturing cost.

In addition, the vision inspection module, a device inspection system having the same and a device inspection method using the same according to the present invention, by independently obtaining the planar image and the side image of the device, the first optical path for the plane image and the side image for the image; There is no need to separately provide a configuration for compensating the path difference between the two optical paths, there is an advantage that the structure of the device is simple and the manufacturing cost can be reduced.

In particular, the vision inspection module, the device inspection system having the same, and the device inspection method using the same according to the present invention can be inspected by obtaining only an image of a pair of opposite sides of the four sides of a device whose plane shape is rectangular. Even if the size of the target device is changed, there is an advantage that the conventional device can be used as it is without changing or replacing the components of the device.

1 is a plan view showing a device inspection system according to an embodiment of the present invention.
2 and 3 are side views showing a vision inspection module according to an embodiment of the present invention.
4 is a conceptual diagram illustrating a process of obtaining a side image of a device in the vision inspection module of FIG. 2.
5A is a view showing an image obtained by the conventional vision inspection module, Figures 5b to 5c is a view showing an image obtained by the vision inspection module of FIGS.
6A to 6B are conceptual views illustrating a vision inspection process for a device transferred to a vision inspection module by a transfer tool in the device inspection system of FIG. 1.
7A to 7B are side views showing a vision inspection module according to another embodiment of the present invention.
8 is a perspective view illustrating a part of the vision inspection module of FIGS. 2 and 3, and FIG. 9 is a perspective view showing a portion of the vision inspection module of FIGS. 7A to 7B.

Hereinafter, a vision inspection module, a device inspection system having the same, and a device inspection method using the same according to the present invention will be described with reference to the accompanying drawings.

An element inspection system according to an embodiment of the present invention includes a loading unit 10 on which a tray 2 on which a plurality of elements 1 are loaded is loaded; A vision inspection module 100 installed at one side of the loading unit 10 to perform vision inspection on the device 1; A first transfer tool that picks up the device 1 from the tray 2 of the loading unit 10 and transfers the device 1 to the vision inspection module 50, and transfers the devices 1 that have completed the vision inspection to the tray 2 to be loaded. And 20.

In this case, the device 1 may be a target of any semiconductor device having a planar shape of a rectangle and having completed a semiconductor process such as memory, SD RAM, flash RAM, CPU, and GPU.

The tray 2 is a configuration in which one or more elements 1 are stacked in a matrix array of n m m (n, m is a natural number), and is generally standardized according to the type or process step of a stacked element such as a memory element. to be.

A mounting groove (not shown) for mounting the device 1 may be formed on the upper surface of the tray 2.

The loading unit 10 is configured to load the tray 2 on which the device 1 to be inspected is loaded in order to perform vision inspection, and various configurations are possible.

For example, the loading unit 10 may be a guide for guiding the movement of the tray 2 on which the plurality of elements 1 are stacked, as shown in FIG. 1 and Korean Patent Application Laid-Open No. 10-2008-0092671. It may be configured to include a portion (not shown), and a driving portion (not shown) for moving the tray 2 along the guide portion.

The vision inspection module 100 is installed on one side of the loading unit 10 to obtain an image of the device 1 by using a camera, a scanner, etc. to perform a vision inspection on the device 1. Therefore, various configurations are possible depending on the type of the device 1 to be inspected, the type of inspection and the configuration of the system.

For example, the vision inspection module 50 may be installed at one side of the loading unit 10 to be perpendicular to the conveying direction of the tray 2 in the loading unit 10, but is not limited thereto.

Specifically, as shown in FIG. 1, when the transport direction of the tray 2 in the loading unit 10 is the Y-axis direction, the vision inspection module 50 is one side of the X-axis direction perpendicular to the Y-axis direction. Can be installed on

The vision inspection module 50 is preferably configured to independently acquire an image of any one surface (hereinafter, referred to as a 'first plane') and a side adjacent to the first plane of the top and bottom surfaces of the device 1. Do. Here, the first plane is a backside of one surface (hereinafter referred to as a 'second plane') that is fixed by the first transfer tool 20 to be described later, and is subjected to vision inspection.

In the first embodiment, the vision inspection module 50 is a vision inspection module 100 that performs a vision inspection of the device 1, which is rectangular in planar shape, as shown in FIGS. An image acquisition unit 110 for acquiring the image of (1), a first optical path L1 for allowing the first plane image of the first plane of the device 1 to reach the image acquisition unit 110; The light path forming unit 120 to selectively form a pair of second light paths L2 to allow the pair of side images of the pair of opposite sides of the device 1 to reach the image acquisition unit 110. ) May be included.

The image acquisition unit 110 may be configured of various imaging devices such as a camera and a scanner to acquire an image of the device 1.

The image acquired through the image acquisition unit 110 may be transferred to a controller (not shown), analyzed using a program, and then used for vision inspection, such as whether there is a defect.

The light path forming unit 120 may face the first light path L1 and the device 1 to allow the first plane image of the first plane of the device 1 to reach the image acquisition unit 110. Various configurations are possible by selectively forming a pair of second optical paths L2 for allowing the pair of side images of the pair of side surfaces to reach the image acquisition unit 110.

When the first optical path L1 is formed by the optical path forming unit 120, a first plane image of the device 1 may be obtained through the image acquisition unit 110, and the optical path forming unit ( When the second optical path L2 is formed by 120, a pair of side images of the device 1 may be obtained through the image acquisition unit 110.

For example, as illustrated in FIGS. 2, 3, and 7A to 9, the light path forming unit 120 may correspond to a pair of side surfaces of the device 1 corresponding to a pair of side images. A fixed frame portion 126 that is fixedly installed and has a pair of first reflecting members 122 that reflect in parallel to the normal direction of the first plane, and is installed to be movable relative to the fixed frame portion 126 Accordingly, the first optical path L1 and the pair of second optical paths L2 may include a moving frame part 128 to selectively form.

The fixed frame part 126 is a pair of first reflecting members 122 corresponding to a pair of opposite sides of the element 1 and reflecting a pair of side images in parallel to the normal direction of the first plane. It is equipped with a fixed installation is possible in a variety of configurations.

The fixed frame part 126 may be formed of various materials as long as the frame is coupled to the pair of first reflecting members 122 and has a rigidity, and is reflected by the pair of first reflecting members 122. If it does not block the movement path of the side of the image, that is, if the opening corresponding to the portion corresponding to the second light path (L2) is formed, it can be made in various shapes.

The pair of first reflecting members 122 are configured to reflect a pair of side images in parallel to the normal direction of the first plane to correspond to a pair of opposite sides of the device 1. If the reflective surface reflects the incident light, it may be made of various members such as a mirror and a prism.

As shown in FIGS. 2 to 4, the pair of first reflecting members 122 correspond to a pair of opposite sides of the four sides of the device 1, and a pair of side images are formed. The pair of reflecting surfaces are inclined at an angle of 45 ° with respect to the normal direction of the first plane (-Z axis direction) in order to reflect toward the normal direction of the first plane of (1). It can be installed to achieve.

By the pair of first reflecting members 122, a pair of second optical paths L2 for the pair of side images may be formed in parallel with the first optical paths L for the first planar image. Can be.

The movable frame portion 128 is installed to be movable relative to the fixed frame portion 126 to selectively form a first optical path L1 and a pair of second optical paths L2 according to a position. Various configurations are possible.

Specifically, the movable frame 128 is movable between the "first position where the first optical path L1 is formed" and the "second position where the pair of second optical path L2 is formed". Can be installed.

Here, in the first position, the first optical path L1 is formed through the combination of the fixed frame unit 126 and the movable frame unit 128 to acquire an image of the first planar image of the device 1. If the position is a variety of positions depending on the shape of the moving frame 128 and the coupling relationship between the members.

For example, the first position may be set at a position where the moving frame unit 128 blocks a pair of images of the device 1 or reflects the pair of images so that they do not face the image acquisition unit 110. have.

However, as shown in FIGS. 3 and 7B, the first position interferes with the pair of side images reflected by the moving frame unit 128 only by the first plane image and the pair of reflecting members 122. It is more preferable in that the configuration of the apparatus can be simplified so that the pair of side images do not reach the image acquisition unit 110 by being set at a position that is not set.

Similarly, in the second position, the second optical path L1 is formed through the combination of the fixed frame part 126 and the moving frame part 128 to obtain an image of a pair of side images of the device 1. If possible, various positions are possible depending on the shape of the moving frame 128 and the coupling relationship between the members.

For example, the second position may include the first plane image between the fixed frame unit 126 and the image acquisition unit 110 so that the moving frame unit 128 does not reach the image acquisition unit 110. It may be set at a position to block or reflect.

However, the second position, as shown in Figures 2 and 7a, in terms of simplifying the configuration of the device, blocking the first plane image between the fixed frame portion 126 and the image acquisition unit 110 It is preferably set in position.

Meanwhile, the moving frame part 128 is movable to the fixed frame part 126 as shown in FIGS. 8 and 9 to improve the positional accuracy of the moving frame part 128 for clear image acquisition. Can be combined.

Specifically, as shown in FIGS. 2, 3 and 7a to 7b, the movable frame part 128 has a first plane of the device 1 to be inspected on one surface of the fixed frame part 126. Can be linearly coupled in a plane direction (XY plane direction) perpendicular to the normal direction of.

At this time, to guide the movement of the movable frame portion 128, the optical path forming portion 120 is a guide portion for guiding the linear movement of the moving frame portion 128 relative to the fixed frame portion 126 129 may be further included.

For example, as shown in FIGS. 8 and 9, the movable frame part 128 includes a fixed frame part such that the movable frame part 128 slides with respect to the fixed frame 126 along the guide part 129. 126 may be slide coupled.

On the other hand, the moving frame portion 128, in the second position for forming a pair of second optical path (L2), a pair of side images are the central portion of the light receiving surface (S) of the image acquisition unit 110 A plurality of second reflecting members 124 reflecting the pair of side images reflected from the pair of first reflecting members 122 toward the image acquisition unit 110 to reach the vicinity.

The plurality of second reflecting members 124 may be configured to reflect a pair of side images, and may be formed of various members such as a mirror and a prism as long as the reflecting surfaces reflect incident incident light. have.

The plurality of second reflecting members 124 may reflect a pair of side images in a state in which the moving frame unit 128 is located at the second position, so that the pair of side images may receive a light receiving surface ( If it is possible to reach near the center portion of S) may be installed in various positions of the moving frame portion (128).

For example, as illustrated in FIG. 2, the plurality of second reflecting members 124 reflect a pair of side images reflected in parallel from each other in the pair of first reflecting members 122 toward the inner center portion. A pair of outer reflecting member 124a and a central reflecting member 124b reflecting the pair of side images reflected from the pair of outer reflecting members 124a in parallel to each other again.

The pair of outer reflecting members 124a is configured to reflect a pair of side images, and may have various members such as a mirror and a prism as long as the pair of outer reflecting members 124a has a reflecting surface reflecting incident incident light. have.

The pair of outer reflection members 124a may have various shapes and may be installed at various positions as long as the pair of side reflection images can be reflected toward the center portion.

For example, the pair of outer reflecting members 124a may be installed to form a symmetrical form with the pair of first reflecting members 122 while forming an inclination of 45 ° with a pair of incident side images. It is not limited.

The central reflecting member 124b is configured to reflect a pair of side images, and may have various members such as a mirror and a prism as long as the central reflecting member 124b has a reflecting surface that reflects incident incident light.

The central reflecting member 124b may have various shapes and may be installed at various positions as long as it reflects a pair of side images that are reflected from the pair of outer reflecting members 124a toward the center in parallel.

For example, the central reflecting member 124b is installed at the center of the pair of outer reflecting members 124a, and has a pair of reflecting surfaces facing in parallel with the reflecting surfaces of the pair of outer reflecting members 124a. This can be formed.

The pair of reflecting surfaces may also be installed to form an inclination of 45 ° with a pair of incident side images.

By the plurality of second reflecting members 124, a pair of side images may reach the light receiving surface S of the image acquisition unit 110 in a state in which the pair of side images are close to each other.

In addition, although not shown in the drawings, according to the configuration of the device, a separate reflective member for changing the traveling direction of the first plane image or the pair of side images between the moving frame portion 128 and the fixed frame portion 126 Of course, it is also possible to install additional.

On the other hand, the vision inspection module 100, as shown in Figures 2, 3 and 7a to 7b, is installed between the optical path forming unit 120 and the image acquisition unit 110, the first planar image And a main reflection member 140 for reflecting the pair of side images toward the image acquisition unit 110.

The main reflecting member 140 is configured to reflect a pair of side images passing through the first plane image and the moving frame unit 128 and has a reflecting surface reflecting incident incident light. It may be made of various members such as a prism.

By the main reflection member 140, the traveling direction of the first planar image and the pair of side images may be bent toward the image acquisition unit 110.

The vision inspection module 100 may further include an illumination unit 150 for irradiating light to the first plane and the respective side surfaces of the device 1.

The lighting unit 150 may be installed in various ways depending on the irradiation method and may be disposed at various positions, and monochromatic light such as laser light, tricolor light such as R, G, and B, depending on the type or type of vision inspection. Various light such as white light may be irradiated, and various light sources such as an LED element may be used.

For example, when the vision inspection module 100 includes the above-described main reflection member 140, if the main reflection member 140 has a transflective material through which light can pass, the lighting unit 150, It may be configured to irradiate light to the first plane and each side of the element 1 at the back side of the reflecting surface.

In addition, the lighting unit 150 may be configured to perform irradiation on the first plane and irradiation on each side by a separate light source (not shown).

The vision inspection module 100 according to the second embodiment will be described in detail with reference to the differences from the first embodiment described above with reference to FIGS. 7A to 7B.

In the second embodiment, as shown in FIGS. 7A to 7B, the fixed frame unit 126 may include a pair of first reflecting members 122 to perform vision inspection on the plurality of devices 1. It is provided with a plurality.

For example, the fixed frame part 126 includes two pairs of first reflecting members 122, so that image acquisition of two devices at a time is possible, so that vision inspection of a plurality of devices 1 is performed. The speed can be greatly improved.

The second reflecting members 124 of the moving frame part 128 may be disposed corresponding to the position and the number of the two pairs of the first reflecting members 122.

In this case, the vision inspection module 100 is fixedly installed at a predetermined position, and when the moving frame unit 128 is positioned at the first position, two first plane images are received by the light receiving surface of the image acquisition unit 110. Two first plane images are reflected toward the image acquisition unit 110 so as to reach near the center of S), and when the moving frame unit 128 is positioned at the second position, two pairs of side images are acquired. It may include a plurality of third reflecting members 127 for reflecting two pairs of the first plane image toward the image acquisition unit 110 to reach near the central portion of the light receiving surface (S) of 110.

The plurality of third reflecting members 127 may be installed in the auxiliary frame part 125 fixedly installed at a predetermined position.

As shown in FIG. 9, the auxiliary frame part 125 may be coupled to the fixed frame part 126 or may be integrally formed with the fixed frame part 126. The moving frame unit 128 may be coupled to the frame unit 125 so as to be slidably movable.

The plurality of third reflecting members 127 may be formed of various members such as a mirror and a prism as long as the reflecting surface reflects incident incident light.

For example, as illustrated in FIGS. 7A to 7B, the plurality of third reflecting members 127 may include a pair of outer reflecting members reflecting the first planar image or the pair of side images toward the inner center portion. 127a) and a central reflection member 127b for reflecting the first planar image or the pair of side images reflected by the pair of outer reflection members 127a back in parallel with each other.

The third reflecting members 127 may be the same as or similar to the pair of outer reflecting members 124a and the central reflecting member 124b installed in the moving frame 128, and thus a detailed description thereof will be omitted.

By the plurality of third reflection members 127, the FOV of the vision inspection module 100 required for vision inspection of the plurality of devices 1 may be minimized. This effect of the present invention can be clearly seen when comparing Fig. 5a showing the image obtained in the conventional vision inspection module and Fig. 5b and 5c showing the image acquired in the vision inspection module according to the present invention. 5B is a first plane image of the first plane obtained by the vision inspection module of the present invention, and FIG. 5C is a pair of side images of a pair of sides obtained by the vision inspection module of the present invention.

In the case of FIG. 5A, since both the first plane and the four side surfaces are acquired on the light receiving surface of the image acquisition unit 110, a large FOV must be secured during vision inspection of the large device 1 and a very expensive equipment is installed. Since the size of the device 1 to be examined exceeds 12mm, it is very difficult to perform vision inspection with general equipment.

However, in the case of FIG. 5C, since only a pair of side images of two sides are to be obtained on the light receiving surface of the image acquisition unit 110, the large-size device 1, in particular, the maximum size using conventional low-cost equipment Vision inspection can also be sufficiently performed on the device 1 having (36 mm).

In addition, since the vision inspection module 100 having the above-described configuration acquires the first planar image and the pair of side images independently of each other, the first optical path L1 and the second optical path L2. The focal length is different due to the difference between the paths), and thus, when the image is acquired by the image acquisition unit 110, there is an advantage in that a blurry image is not obtained because the focal points are not in focus with each other.

Accordingly, the vision inspection module 100 according to the present invention may be used even if the distance between the pair of first reflecting members 1122 and the side surface of the device 1 is changed or the first optical path L1 is changed (the inspection object). Since only the focus of the first optical path L1 or the pair of second optical paths L2 need to be adjusted, it is simple without replacing components of the vision inspection module 100. By simply adjusting the position of the image acquisition unit 110, the focus can be adjusted to obtain a clear image.

In this case, the vision inspection module 100 may further include a focus adjustment unit 130 that adjusts the focus by adjusting the position of the image acquisition unit 110. For example, as shown in FIGS. 2, 3, and 7A to 7B, the focus adjusting unit 130 may be combined with the image obtaining unit 110 to form the first image or side surface of the image obtaining unit 110. Various configurations are possible by the linear movement along the incident direction of the image (drawing reference, Y-axis direction).

In addition, the vision inspection module 100 according to the present invention, in acquiring side images of the device 1, does not acquire four side images at once, but uses a pair of first reflecting members 122 at one time. Since a pair of side images of the pair of sides are acquired, as shown in FIG. 5C, when a pair of side images are acquired, a pair of side images are obtained by using a plurality of second reflecting members 124. By collecting the central portion of the light receiving surface 110, there is an advantage that can minimize the FOV of the vision inspection module 100 necessary for vision inspection.

The first transfer tool 20 picks up the device 1 from the tray 2 of the loading unit 10 and transfers the device 1 to the vision inspection module 50, and transfers the device 1 having completed the vision inspection to the tray 2. Various configurations are possible by transporting and loading).

For example, as shown in FIGS. 6A to 6B, the first transfer tool 20 may be coupled to the main body portion 21 and the main body portion 21 so as to have a rear surface of the first plane of the device 1 ( Hereinafter, the second plane) may include a plurality of pickers 22 disposed in one or more rows by fixing and adsorbing the second plane.

The plurality of pickers 22 is preferably provided in a plurality, such as a row or a double row in order to increase the inspection speed.

The picker 22 is configured to pick up the element 1 by sucking and fixing the second plane by vacuum pressure, and various configurations are possible.

The first transfer tool 20 may further include a picker rotation driving unit for rotating the picker 22 about a central axis c parallel to the normal direction (-Z axis direction) of the first plane.

Through the picker rotation driver, the element 1 positioned between the pair of first reflecting members 122 may be rotated together with the picker 22.

In addition, as shown in FIGS. 6A and 6B, the first transfer tool 20 may include a plurality of pairs of first elements 1 picked up by a plurality of pickers 22 arranged in a line. It may further include a linear moving drive for linearly moving the body portion 21 to be sequentially positioned between the reflective member 122.

The first transfer tool 20 may include a first guide rail 40 disposed in a direction in which the tray 2 moves in the loading unit 10 (in the Y-axis direction of the drawing) and in a vertical direction (the X-axis direction of the drawing). It may be combined with the first guide rail 40 to move along.

The first guide rail 40 is arranged perpendicular to the moving direction of the tray 2 in the loading unit 10 to support the first transfer tool 20 and to guide the movement thereof. It is possible.

In addition, the device inspection system may further include an unloading unit 30 for unloading the trays 2 on which the devices 1 after the vision inspection have been loaded.

The unloading unit 30 receives the trays 2 containing the elements 1 that have undergone vision inspection in the loading unit 10 and classifies the trays 2 into the trays 2 according to the vision inspection results. It is possible.

The unloading unit 30 has a structure similar to that of the loading unit 10, and the first unloading unit 31 in which the devices 1 of the good quality G are unloaded according to the vision inspection result of the device 1. , A second unloading part 32 in which the devices 1 determined as defective 1 or abnormal 1 (R1) are unloaded, and a third in which the devices 1 determined as defective 2 or abnormal 2 R2 are unloaded. It may include an unloading unit 33.

The unloading parts 31, 32, and 33 may include a guide part (not shown) installed in parallel with one side of the loading part 10, and a driving part (not shown) for moving the tray 2 along the guide part. Unloading trays including a plurality may be installed in parallel.

Meanwhile, the tray 2 may be transferred between the loading unit 10 and the unloading units 31, 32, and 33 by a tray transfer device (not shown), and the unloading units 31, 32, and 33 may be transferred. ) May further include a bin tray unit (not shown) for supplying an empty tray 2 in which the semiconductor device 1 is not loaded.

Meanwhile, the sorting tool 50 for transferring the device 1 may be separately installed in the unloading parts 31, 32, and 33 according to the classification class of each unloading tray part. .

The sorting tool 50 may have a configuration identical to or similar to the first transfer tool 20 described above, and may have a double or single row structure, and a second guide rail disposed in parallel with the first guide rail 40. 60 may be installed to be movable along.

Meanwhile, the unloading units 31, 32, and 33 have been described with reference to an embodiment in which the device 1 is unloaded after the device 1 is again loaded in the tray 2 loaded by the loading unit 10. Any configuration may be used as long as the device 1 can be loaded and unloaded, including a so-called tape reel module, which is loaded and unloaded on a carrier tape in which a pocket is formed.

The device inspection method performed in the vision inspection module and the device inspection system having the above-described configuration includes a first plane of the device 1 positioned between the pair of first reflection members 122 by a transfer tool for device transfer. A first planar image acquisition step of acquiring an image through the image acquisition unit 110 and a pair of side surfaces facing the pair of first reflecting members 122 of the four sides of the device 1. The first side image acquisition step of acquiring a pair of side images through the image acquisition unit 110, and the other side of the four sides of the four sides of the transfer tool so as to face the pair of the first reflecting member 122 And a second side image acquisition step of rotating the device 1 about a central axis perpendicular to the first plane and acquiring a pair of side images of the other pair of side surfaces through the image acquisition unit 110. It may include.

In the element inspection method, the transfer tool is positioned between the pair of first reflecting members 122 in a state of picking up the element 1 to be inspected as the first transfer tool 20 described above.

In order to form the first optical path L1 such that the first plane image of the element positioned between the first reflecting members 122 by the first transfer tool 20 is obtained, the movable frame part 128 is shown in FIG. As shown in FIG. 3 and FIG. 7B, it is positioned at a first position that does not interfere with the first plane image and the pair of side images.

That is, the first plane image acquisition step is performed in a state where the moving frame unit 128 is located at a first position that does not interfere with the first plane image and the pair of side images.

The first planar image obtained in the first planar image acquisition step may be utilized for external inspection such as cracking, scratching, ball grid breakage, chipping, etc. of the first plane of the device 1.

In addition, the first planar image acquired in the first planar image acquisition step may be utilized for setup for aligning the position of the device 1 before acquiring side images of the device 1.

That is, in the device vision inspection method, a device positioned between a pair of first reflecting members 122 by using the first plane image acquired in the first plane image acquisition step before the first side image acquisition step. It may further include an alignment step of aligning the position of (1).

When acquiring a pair of side images of the device 1, if the device 1 is not located at the center of the pair of reflecting members 122, a path difference is generated between the pair of second optical paths L2, so that the blurred image Since is obtained, by performing the alignment step before the first side image acquisition step, a clearer image can be obtained to improve the reliability of vision inspection.

The first transfer tool 20 may align the position of the element 1 and a pair of side surfaces of the four side surfaces of the element 1 may face the pair of first reflective members 122.

When alignment of the device 1 by the first transfer tool 20 is completed, a pair of side images of the device 1 are acquired.

In order to form a pair of second optical paths L2 such that a pair of side images of the device 1 are obtained, the movable frame portion 128 is arranged in a first plane, as shown in FIGS. 2 and 7A. The moving frame unit 128 may be performed after the moving frame unit 128 is moved to a second position that blocks the first plane image so that the image does not reach the image acquisition unit 110. In this case, the first planar image may be blocked by the central reflective member 124b among the second reflective members 124 of the moving frame part 128.

That is, the first side image acquisition step is performed in a state where the moving frame unit 128 blocks the first plane image and is positioned at a second position where the second optical path L2 is formed.

The pair of side images acquired in the first side image acquisition step may be utilized for external inspection such as cracking, scratching, ball grid breakage, chipping, etc. of the first plane of the device 1 as shown in FIG. 5C.

When the first side image acquisition step is completed, the first transfer tool 20, as shown in Figure 4, the center of the axis of rotation parallel to the normal direction of the first plane to the device 1 through the picker rotation drive unit Rotate

Accordingly, assuming that a pair of side images of a pair of side surfaces 1b of the four sides of the device 1 are acquired in the first side image acquisition step, the second side image acquisition step includes: A pair of side images for the pair of sides 1a can be obtained.

The second side image acquisition step is also performed in a state where the moving frame unit 128 blocks the first plane image and is positioned at a second position where the second optical path L2 is formed.

The pair of side images acquired in the second side image acquisition step may be utilized for external inspection such as cracking, scratching, ball grid breakage, chipping, etc. of the first plane of the device 1 as shown in FIG. 5C.

When the second side image acquisition is completed, the first transfer tool 20 moves to the tray 20 to unload the device 1.

However, in order to quickly perform vision inspection on the plurality of devices 1, it is necessary to configure the vision inspection system so that vision inspection is sequentially performed according to the device transfer by the first transfer tool 20.

6A to 6B, the operation of the first transfer tool 20 and the vision inspection procedure according thereto will be described in detail.

As shown in FIG. 6A, a plurality of elements 1 are picked up by the first transfer tool 20 in which a plurality of pickers 22 are arranged in a row or more. The first transfer tool 20 moves to the vision inspection module 100, and moves from the vision inspection module 100 to the fourth picker 22d at the front end of the moving direction reference (X-axis direction) of the first transfer tool 20. The picked-up element 1 and the picked-up element 1 at the rear end first picker 22a are sequentially moved so as to be positioned between the pair of reflecting members 122 in sequence.

At this time, in the vision inspection module 100 for the first planar image acquisition step and the pair of side surfaces 1b obtained by obtaining the first planar image with respect to the device 1 positioned between the pair of reflective members 122. A first side image acquisition step for acquiring a pair of side images may be performed.

When the first side image acquisition step is completed, the first transfer tool 20 rotates the picker 22 about the central axis C to move the first transfer tool 20 from the vision inspection module 100 again. A pair of reflecting members 122 are sequentially arranged with the element 1 picked up by the first picker 22a in the front direction (-X axis direction) and the element 1 picked up by the fourth picker 22d at the rear end. Step by step to be positioned between. Since the first transfer tool 20 reciprocates around the vision inspection module 100, the first picker 22a is first moved between the pair of reflective members 122.

In this case, the vision inspection module 100 acquires a second side image for acquiring a pair of side images of the other pair of side surfaces 1a with respect to the device 1 positioned between the pair of reflective members 122. Steps may be performed.

FIG. 8 shows the movement path P of the element 1 by the first transfer tool 20 when the first transfer tool 20 has a plurality of pickers 22 arranged in one row. . A pair of first reflecting members 122 are installed on both sides of the movement path P of the device 1.

Similarly, FIG. 9 shows the movement path P1 of the element 1 by the second transfer tool 20 when the first transfer tool 20 has a plurality of pickers 22 arranged in a double row, in particular in two rows. , P2). P1 is a movement path of the elements 1 arranged in one of the two columns, and P2 is a movement path of the elements 1 arranged in the other of the two columns. A pair of first reflecting members 122 are provided on both sides of the movement paths P1 and P2 of the device 1, respectively.

That is, since the vision inspection of the plurality of devices 1 may be performed by linear reciprocating movement of the first transfer tool 20 around the vision inspection module 100, the device fixed to the picker 22. Since the Z-axis driving of the transfer tool 20 or the picker 22 for positioning (1) between the pair of first reflecting members 122 is unnecessary, device transfer for vision inspection can be made very fast and Therefore, there is an advantage that can greatly improve the vision inspection speed for the plurality of devices (1).

On the other hand, the present invention is characterized by the vision inspection module, the configuration of the device inspection system presented is only one embodiment, the vision inspection module according to the present invention is limited to being installed in the device inspection system according to an embodiment of the present invention Of course not.

Since the above has been described only with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

1: device 2: tray
100: vision inspection module 110: image acquisition unit
120: light path forming unit

Claims (19)

As a vision inspection module 100 for performing a vision inspection of the device (1) having a planar rectangular shape,
An image acquisition unit 110 for acquiring an image of the device 1,
A pair of first optical paths L1 and a pair of opposing pairs of side surfaces of the device 1 to allow the first plane image of the first plane of the device 1 to reach the image acquisition unit 110. It includes a light path forming unit 120 for selectively forming a pair of second light path (L2) to the side image of the image acquisition unit 110,
The optical path forming unit 120 may include a pair of first reflecting members corresponding to a pair of opposite sides of the device 1 and reflecting a pair of side images in parallel to a normal direction of the first plane ( And a fixed frame portion 126 fixedly installed and movable to the fixed frame portion 126, the first optical path L1 and the pair of second optical paths depending on the position. Vision inspection module 100, characterized in that it comprises a moving frame portion 128 to selectively form (L2). The method according to claim 1,
The moving frame unit 128 may include a “first position at which the first optical path L1 is formed” and “a pair of second optical paths L2” formed at the fixed frame unit 126. Vision inspection module 100, characterized in that coupled to move between two positions. The method according to claim 2,
The second position is a vision inspection module, characterized in that the moving frame portion 128 is set at a position to block the first plane image so that the first plane image does not reach the image acquisition unit 110. 100. The method according to claim 3,
The moving frame unit 128 may include the pair of first reflecting members 122 such that the pair of side images reach the vicinity of the central portion of the light receiving surface S of the image acquisition unit 110 at the second position. Vision inspection module (100), characterized in that it comprises a plurality of second reflecting member (124) for reflecting a pair of side images reflected from the image acquisition unit (110). The method according to claim 3,
The first position is a vision inspection module (100), characterized in that the moving frame portion 128 is set at a position that does not interfere with the first plane image and the pair of side images. The method according to claim 1,
The movable frame portion 128 is coupled to the fixed frame portion 126 so as to be linearly movable in a plane direction perpendicular to the normal direction.
The optical path forming unit 120, the vision inspection, characterized in that further comprises a guide portion 129 for guiding the linear movement of the moving frame portion 128 relative to the fixed frame portion 126 in the planar direction Module 100. The method according to claim 1,
The fixed frame unit 126, the vision inspection module 100, characterized in that it comprises a plurality of the pair of first reflecting member 122 to perform a vision inspection for a plurality of elements (1). The method according to claim 1,
The vision inspection module 100, the vision inspection module 100, characterized in that it further comprises a focus adjustment unit 130 for adjusting the focus by adjusting the position of the image acquisition unit (110). The method according to claim 1,
The vision inspection module 100 is installed between the optical path forming unit 120 and the image acquisition unit 110 to provide the image acquisition unit 110 with the first plane image and the pair of side images. Vision inspection module 100, characterized in that it further comprises a main reflecting member (140) to reflect toward. The method according to claim 6,
The main reflective member 140 is made of a transflective material that can transmit light,
The vision inspection module 100 further includes an illumination unit 150 for irradiating light to the first plane and each side surface of the device 1 on the rear surface of the reflective surface of the main reflection member 140. Vision inspection module (100). A device inspection method performed by the vision inspection module 100 of any one of claims 1 to 10, which performs a vision inspection of a device 1 having a planar rectangular shape,
A first planar image acquisition step of acquiring, via the image acquisition unit 110, a first planar image of the device 1 positioned between the pair of first reflecting members 122 by a transport tool for device transport. Wow,
A first image of obtaining a pair of side images of the pair of side surfaces of the four side surfaces of the device 1 facing the pair of first reflective members 122 through the image acquisition unit 110; Side image acquisition step,
The element 1 is rotated about a central axis perpendicular to the first plane by the transfer tool such that the other pair of sides of the four sides faces the pair of first reflecting members 122. And a second side image acquisition step of acquiring a pair of side images of the remaining pair of side surfaces through the image acquisition unit (110). The method according to claim 11,
The device vision inspection method,
Before the first side image acquisition step, the position of the device 1 positioned between the pair of first reflecting members 122 is determined using the first plane image acquired in the first plane image acquisition step. Device inspection method characterized in that it further comprises an alignment step to align. The method according to claim 11,
The first planar image acquiring step is performed when the movable frame unit 128 is located at a first position that does not interfere with the first planar image and the pair of side images. . The method according to claim 11,
In the first side image acquisition step and the second side image acquisition step, the moving frame unit 128 blocks the first plane image so that the first plane image does not reach the image acquisition unit 110. Device inspection method characterized in that performed after moving to the second position. A loading unit 10 on which a tray 2 on which a plurality of elements 1 are loaded is loaded;
A vision inspection module (100) according to any one of claims 1 to 10 installed on one side of the loading unit (10) to perform vision inspection on the device (1);
The first device picks up the device 1 from the tray 2 of the loading unit 10 and transfers the device 1 to the vision inspection module 50, and transfers and loads the device 1 after the vision inspection to the tray 2. Device inspection system comprising a transfer tool (20). The method according to claim 15,
The device inspection system,
The device inspection system, characterized in that it further comprises an unloading unit (30) for unloading the trays (2) loaded with the vision (1). The method according to claim 15,
The first transfer tool 20,
The plurality of pickers 22 coupled to the main body part 21 and the main body part 21 and fixed to the rear surface (hereinafter, referred to as a second plane) of the first plane of the device 1 and arranged in one or more rows are provided. Device inspection system comprising a. The method according to claim 17,
And the first transfer tool (20) further comprises a picker rotational drive for rotating the picker (22) about a central axis parallel to the normal direction of the first plane. The method according to claim 18,
The first transfer tool 20 may be configured such that a plurality of elements 1 picked up by a plurality of pickers 22 arranged in a row are sequentially positioned between the pair of first reflecting members 122. Device inspection system, characterized in that it further comprises a linear moving drive for linearly moving the body portion (21).

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