DE102006027663A1 - Optical inspection system for measuring e.g. unpacked electronic components, has endoscope with optical inlet and optical outlet arranged such that electronic component that is found in coverage penetrates under diagonal angle - Google Patents

Abstract

The system (100) has a camera for detecting an electronic component (141) that is found in given spatial coverage, and a light guiding unit i.e. endoscope (120), with an optical inlet and an optical outlet, where the outlet is optically coupled with the camera and the inlet is introduced into the coverage. The endoscope has a rigid shape, and is arranged such that the component that is found in the coverage penetrates under a diagonal angle. The endoscope is adjustably supported relative to a chassis, and has an optical deflecting unit arranged at the inlet.

Description

The The invention relates to an optical inspection system for surveying of electronic components, which are in a given spatial Detection area. The exact measurement is preferred for the purpose of a precise Picking up the components by a placement head of a placement device, which for automatic loading from components to component carriers, in particular to printed circuit boards, is provided.

by virtue of the increasing miniaturization of electronic components it will not be economical in the near future, electronic components applied to an electronic circuit substrate stocked be for the purpose of a secure component feeder for a placement process repack. Such a repacking into special component supply straps is commonplace today in Surface Mount Device (SMD) devices to individually supply the SMD components to the placement process. Much more is made by modern placement systems be required that they are also unhoused components (so-called bare This) directly from a wafer and on appropriate Can set up sites of electronic circuit substrate.

Around the handling of unhoused ones simplify electronic components, the entire wafer before a component singulation a sticky carrier film applied. The separation is usually carried out by a high-precision mechanical Saw or through a high-precision chemical etching.

From the carrier film, the components are removed from a suction pad and fed to a placement process. A detachment of the components of the sticky carrier film can be supported by so-called. Ejecting needles, which for example from the EP 565781 A1 are known.

at the highly accurate assembly of components or other objects on a component carrier plays The optical inspection plays a vital role in the quality and accuracy the equipment. Likewise, by the optical inspection of special markings the position of the component carrier be determined to fixed on a precise assembly of the components placement positions of the component carrier to ensure. The components or brands are typically over recorded analog or digital camera system. The corresponding Image data are analyzed in an evaluation step with suitable algorithms processed around the quality, the madness, the rotation of the device etc. to a reference state determine.

ever by type of component, whether conventional SMD components or reflecting ungehäuste Components (Bare Dies, Flip-Chips) on a wafer, are currently different placement machines used. For example, SMD components are populated by a head picks up the components to photograph them afterwards and using of an image processing system, the location and structure of the fetched To measure component. Finally they are picked up by the placement head the circuit board set.

nowadays No inspection systems exist at the same time for both Device types, i. as well as SMD components made of straps or so-called trays as well as for reflecting Components of wafers can perform a position and structure detection. at known SMD placement machines is for the purpose of a possible fast assembly of the Space for an optical inspection system for picking up or already recorded components very limited. Nevertheless, a reliable inspection to ensure, are conventional inspection systems with regard to the optical properties of SMD components optimized, so that an inspection of spie ting components not reliable and the construction of another inspection system due to the low Installation space usually not possible is.

Also when picking up unhoused components directly from a wafer is typically very small as a result Dimensions of unhoused Components of the an optical inspection system available space extremely limited.

From the JP 07-221164 A is a removal device for held by a wafer holder Bare Dies is known in which prior to a component recording the entire structure of the wafer holder is measured. The removal device has the disadvantage that possibly occurring after the measurement position shifts individual components are not recognized and accordingly the process reliability is reduced in the component recording.

From the JP 02-137338 A a position detector for unhoused components is known. The position detector comprises a camera which can be positioned above the component. Through an image evaluation of the outer edges of the component, the exact spatial position of the component can be determined and thus the accuracy of a bonding process can be improved. The vertical detection of the device has the disadvantage that in case of receiving the compo Ment by a holding device of a placement the freedom of movement of the placement is severely limited.

Of the Invention is based on the object, an optical inspection system for measuring unhoused To create components, which inspection system within a small space can be built and which still one reliable Surveying the unhoused Components allows.

These The object is according to the independent claim 1 by an optical inspection system for measuring electronic Solved components, which components are in a given spatial coverage are located. The inspection system includes (a) a camera, which for detecting a component located in the detection area is set up, and (b) a light guide, which a optical input and an optical output. It is the optical output is optically coupled to the camera and the optical Input is brought to the detection area.

Of the The invention is based on the finding that the use of a Light guide a close introduction of the inspection system to the component to be measured even in a very limited Space available. This will be a precise Component measurement possible, with interfering edges for example, by a placement or a holding device of the placement can be avoided.

Under The term surveying in this context is both the provision a particular type of device, for example, based on its outer edges as well as a position detection of a device relative to a To understand reference point.

at A position detection is preferred both the translational Detected position as well as the rotation angle of a component. there can the component before or after the recording by a component holding device, For example, a suction pipette to be measured. The Measurement a recorded component allows this by a suitable Compensation for the positioning of a corresponding placement head a positionally accurate placement on a component carrier. at a not yet recorded component allows such a survey a precise, preferably central, recording of the device by a Holding device of a placement.

It It is noted that the described optical inspection system also for the detection of markings on component carrier for Purpose of the exact positioning of the component carrier in a placement field suitable is.

According to one embodiment the invention of claim 2, the light guide is an endoscope. This has the advantage that the optical inspection device on simple and inexpensive way through the use of conventional endoscopes, for example in medical technology or during the inspection used by turbine can be realized.

in the Comparison to the use of conventional inspection systems for the detection of SMD components, which are conventional inspection systems have a CCD camera and elaborate lighting components, The use of an endoscope allows the realization of a reliable inspection system within a much smaller space. Furthermore, this allows Endoscope a component detection under a much steeper Observation angle than that of conventional inspection systems the case would be. This is because conventional Inspection systems for avoiding obstacles and interfering edges in the optical image, for example, by a placement or a component holding device the device only under a very shallow Can capture angles. One compared to conventional Inspection systems significantly steeper viewing angle has the Advantage that distortions and distortions as a result of an inconsistent Object distance are significantly lower.

According to one another embodiment of the The invention according to claim 3, the endoscope is a rigid structure. This has the advantage that a close approach of the optical input to the detection area is possible without additional support. Such an additional Holder, as example, in mechanically flexible endoscopes required would, would that anyway small space that is available, further reduce and / or hinder the movement of a holding device.

Prefers the endoscope has a juxtaposition of several rod lenses on which a high light intensity enable the light guide. This way are for a reliable component measurement by the described optical inspection system not necessarily especially bright lighting conditions required.

According to a further embodiment of the invention according to claim 4, the endoscope is arranged such that a component located in the detection area under an oblique Win kel is detectable. This advantageously allows an even closer approach of the endoscope to the detection area.

Of course, one leads slope Component detection to distortions caused by various object distances for example, from the component leading edge or the component trailing edge caused. To the strength of To limit distortions by a too flat observation angle, should the detection angle not greater than 60 °, preferably not greater than 45 °. In this context, the term detection angle is the one Inclination angle to understand which is between the optical axis of the inspection system and the standards of the component level or the wafer plane extends. The component level is determined by the component surface, at which the holding device on the device for receiving the same attacks.

According to one another embodiment of the The invention according to claim 5, the endoscope is arranged such that Components at least in the vicinity their pickup position before recording by a holding device of a placement head ver are measurable. This is especially the case with the typical ones Small Bare Dies or flip chips are an advantage, which are directly from be picked up a translationally displaceable wafer. In the Picking up these small components is in fact an accurate positioning of the component to be picked up centrally to the corresponding holding device required to be a reliable To allow the device to be mounted which often smaller than the tip of the holding device used. If the component measurement immediately before picking up the device done, can Thus position error of the components to be picked up by appropriate further shifting of the wafer and / or by a corresponding Positioning of the placement head be compensated.

moreover can by inspecting the components immediately before picking up marked and not for equipping provided Bare This will be detected. Thus, an assembly with faulty components reliable be avoided.

According to one another embodiment of the The invention of claim 6 is the endoscope relative to a chassis slidably mounted. In particular by a vertical shift The inspection system can be variably adjusted to different focal planes to be adjusted. This is particularly advantageous if with one and the same placement device Flip chips and other components are populated, which without a Flipping on a component carrier be put on. This is a so-called for flipping the flip chips. Flip-head used which temporarily stores the flip chips to be populated takes up, turns by one turn and in one of the pickup position opposite Transfers position to the actual placement. This is done then a precise optical measurement of the device at the transfer position, which is above the plane of the wafer. In contrast, it takes place the measurement of components, which during the placement process not be turned, directly in the plane of the wafer. The movable one Storage of the endoscope allows thus advantageously a rapid reconfiguration of the optical Inspection system, with components at different altitudes can be reliably measured with respect to the plane of the wafer.

According to one another embodiment of the The invention according to claim 7, the endoscope has an optical deflection element on, which is arranged at the optical input. In this way becomes a camera field of view emerging laterally from the endoscope longitudinal axis generated, which in many cases, a particularly close approach to the Endoscope allows the detection area.

According to one another embodiment of the The invention according to claim 8, the endoscope is rotatably mounted. This can advantageously a fast switching between a Position measurement of a component at a pick-up position and allow a position measurement of a device, which already from a holding device has been recorded.

According to one another embodiment of the The invention according to claim 9, the optical inspection system additionally first illumination unit, by means of which the detection area under a first angle can be illuminated. It is preferred the first lighting unit as well as the optical input below at a shallow angle the level of the detection area arranged. In a mirror-symmetrical arrangement of the first illumination unit and the optical input of the light-guiding device can thus advantageously for a reliable measurement conducive Bright field illumination realized a device to be measured become.

According to a further embodiment of the invention according to claim 10, the optical inspection system additionally comprises a second illumination unit, by means of which the detection area can be illuminated at a second angle. Preferably, the second lighting unit from the perspective of the detection range behind or un arranged indirectly next to the optical input of the light guide, so that at an oblique viewing angle of the inspection system advantageously a dark field illumination can be realized.

The optionally lighting the components to be measured with a Brightfield and / or with a darkfield enables safe detection both of components with a reflective surface as well as of components with a matte finish. The lighting system is thus for a variety of different Component types suitable.

According to one another embodiment of the The invention according to claim 11, the first lighting unit and / or the second illumination unit has a circuit board on which a plurality of light emitting diodes are arranged. The light-emitting diodes are preferred so-called SMD light-emitting diodes, which on the respective board in a compact spatial Arrangement populated are. This can be easily by means of intensive lighting each realized a compact design of lighting units become.

It It should be noted that the lighting units described formed separately from the light guide or from the endoscope are. This has the advantage that the light-conducting device in one especially slim design can be realized and that anyway a high light intensity the entire inspection system is possible because beam splitter or other optical components for the separation of lighting and measuring light are not required.

According to one another embodiment of the The invention according to claim 12 comprises the optical inspection system additionally a downstream of the camera evaluation, which for Position detection and / or for Typerkennung of optically detected components is provided. This has the advantage that the entire position measurement the components to be picked up within a self-sufficient module trained feeder can be realized.

Further can be picked up and called by a so-called online monitoring by a corresponding control of the positioning of the placement and / or the positioning of the components to be picked up the collection security further increased become. In this case, a positioning of the components to be picked up by a collective displacement of a component feed unit respectively. In the case of assembly from unhoused ones Devices directly from a wafer is preferred to the entire wafer translationally shifted, so that each component to be picked up moved to the correct pick-up position.

According to one another embodiment of the The invention according to claim 13, the evaluation unit is set up in such a way that a distortion of an image taken by the camera Component is compensated. This is first a determination of the distortion required. This can be done, for example, by calibrating marks, which are within the detection range of the camera, in terms of their position and / or their shape become. A compensation of the distortion then takes place in known Way through usual Methods of digital image processing.

Further Advantages and features of the present invention will become apparent the following exemplary description of presently preferred embodiments.

In the drawing show in schematic representations

1 the detection of a component located on a wafer immediately before the component is picked up by a placement head,

2 the detection of a device turned by a flip-flop immediately before the device is picked up by a placement head,

3 an endoscope camera system for an optical inspection system according to an embodiment of the invention,

4 an optical inspection system with two lighting units in a plan view,

5 a perspective view of an optical inspection system, and

6 an enlarged view of the component detection by means of in 5 illustrated optical inspection system.

At It should be noted that in the drawing the Reference signs of identical or corresponding components only in its first digit and / or by an appended letter differ.

1 shows an optical inspection system 100 when capturing one on a wafer 140 located component 141 immediately before the recording of the device 141 through a placement head 150 , The component 141 is an unhoused component, which is also called Bare Die becomes. The component 141 is in a known manner on a sticky carrier film 142 of the wafer 140 fixed.

The optical inspection system 100 has a light guide 120 on, which is an endoscope according to the embodiment shown here. The endoscope 120 is with an in 1 not shown camera optically coupled, showing the exact position of the device 141 on the wafer 140 detected. The corresponding measuring light is denoted by the reference numeral 131 characterized.

The optical inspection system 100 also has a first lighting unit 160 on which relative to the endoscope 120 is arranged such that a bright field illumination of the device 141 is realized. The lighting unit 160 includes a circuit board 161 on which in a compact arrangement so-called SMD LEDs 162 are arranged, which are controlled by means of a driver circuit, not shown. To ensure uniform illumination of the component 141 To ensure the lighting unit also has a lens 163 on. So that's the lighting unit 160 emitted brightfield illumination light 165 a diffused light, which is particularly well suited for optical measurement.

By a precise position measurement of the device 141 can the placement head 150 relative to the wafer 140 be positioned so that when lowering a hollow shaft or a quill 151 , on which a suction device designed as a suction pipette 152 is attached, the device 141 is recorded centrally. For a precise relative positioning of the placement of the placement 150 and / or the wafer 140 parallel to the plane of the wafer 140 be moved translationally.

To possible interference edges, for example, by the placement 150 and / or the suction pipette 152 The endoscope can be avoided 120 relative to the plane of the wafer 140 be inclined. In order to be able to reliably correct the distortions inevitably produced during an oblique measurement, measurement light should be at a maximum illumination angle of 45 ° to the component to be detected 141 incident. The illumination angle in this context is the angle between the optical axis of the endoscope and the normals of the wafer plane.

The endoscope 120 , which is a so-called. Stabendoskop with a diameter of about 3.8 mm, due to a slim tube shape particularly close to the component to be imaged 141 be introduced. In any case, the optical inspection system is significantly more space-saving compared to conventional camera lighting systems.

It should be noted that the device 141 also by a lateral turning of the endoscope with simultaneous additional perspective distortion of the component 141 can be inspected at the pick-up position.

2 shows an optical inspection system 200 in the position measurement of a so-called flip-chip 241 , which of a turning tool 207 from a carrier film 242 a wafer 240 removed and provided in a direction rotated by 180 ° orientation a placement. The turning tool is a so-called flip-head 207 which has at least two component holding devices 209 and which about a rotation axis 208 is rotatably mounted.

The entire optical inspection system 200 is relative to a chassis 205 displaceable along a direction of displacement, so that both the endoscope 220 as the bright field illumination unit 260 in the vertical direction 206 be moved. This is the inspection system 200 for measuring the position of components 241 usable, which are located at different altitudes.

The bright field illumination unit 260 corresponds in its structure to the in 1 illustrated lighting unit 160 so that the corresponding components of the lighting unit 260 namely, the board 261 , the SMD light-emitting diodes 262 and the diffuser 263 will not be explained again at this point. That of the lighting unit 260 generated bright field illumination light 265 allows in any case an accurate position determination of the device 241 through the measuring light 231 , allowing a reliable recording of the device 241 through the holding device 252 is possible.

3 shows an endoscope camera system 310 which, for example, in the in 1 and 2 illustrated optical inspection systems 100 respectively. 200 can be used. The camera system includes an endoscope 320 which has an optical input 320a and an optical output 320b having.

The endoscope 320 is a so-called rod endoscope, which is a rigid structure, the first tube 321 with a diameter of only about 3.8 mm and a slightly thicker second tube 328 having. The optical input 320a is with a 45 ° inclined reflector 323 provided, which is a small prism according to the embodiment shown here. The prism 323 has the effect of making the field of view of the endoscope 320 is tilted 90 ° relative to the endoscope longitudinal axis. Thus, the endoscope can be introduced in many applications particularly close to the object to be detected, without the endoscope, for example, at a detection angle of 45 ° must be arranged across the room.

The optical input 320a is also with a lens 322 provided, which according to the embodiment shown here, an achromatic, ie, a lens or a lens system with a low chromatic aberration. The Achromat 322 has the advantage of having the endoscope 320 has a large field of view. To a high light intensity of the endoscope 320 to ensure are in the first tube 321 a plurality of so-called rod lenses 324 provided, each of which allow both a low-loss light pipe as well as a particularly trouble-free optical imaging.

The optical output 320b is over an eyepiece 329 with a camera 330 optically coupled. The eyepiece 329 acts in such a way with the rod lenses 324 and the Achromat 322 Altogether, that means a high depth of field of the entire endoscope 320 is guaranteed. The camera 330 preferably has a CCD sensor, which is connected to an evaluation unit 332 connected via a line. The evaluation unit is set up such that distortions caused by an oblique observation angle can be compensated.

4 shows a top view of an optical inspection system 400 which is a bright field illumination unit 460 and a dark field illumination unit 470 having. The lighting unit 470 is right next to an endoscope 420 arranged, which via an eyepiece 429 with a camera 430 optically coupled. The lighting unit 460 is spatially arranged such that from the perspective of the optical input of the endoscope, not shown 420 a bright field illumination light 465 on the unhoused component to be measured 441 meets. The lighting unit 470 is spatially arranged such that the device 441 with a dark field illumination light 475 is illuminated.

The lighting unit 460 respectively. 470 as well as the above based on 1 explained lighting unit 160 a circuit board 461 respectively. 471 , SMD LEDs 462 respectively. 472 and a diffuser 463 respectively. 473 on. A first holder 464 serves to attach the first lighting unit 460 , A second holder 474 serves to attach the second lighting unit 470 ,

5 shows a perspective view of an optical inspection system 500 , The components to be measured (not shown) are located above a cross member 580 which is a first holder 564 and a second holder 574 connects with each other. The first holder 564 serves to attach a brightfield illumination unit 560 , The second holder 574 serves to attach a dark field illumination unit 570 , The two lighting units are constructed according to the embodiment shown here as well as in 1 illustrated lighting unit 160 ,

The inspection system 500 has a rod endoscope 520 on, which has an optical input 520a for collecting measuring light and an optical output 520b which has an eyepiece 529 with a camera 530 optically coupled. The camera has a light-sensitive sensor, not shown, which is, for example, a two-dimensional CCD sensor array. For a stable mounting of the lighting unit 570 and on the other hand, a close approach of the optical input 520a and to allow the detection area above the cross member is in the holder 574 an opening 581 formed into which the front portion of the endoscope 520 can protrude.

6 shows an enlarged view of the optical inspection system 500 , which now with the reference numeral 600 is provided. The components to be measured 641 , which on a carrier foil 642 of a wafer are releasably fixed, via an optical input 620a an endoscope 620 detected by a camera, not shown. The corresponding measuring light is denoted by the reference numeral 631 Mistake. To illuminate the components to be measured 641 is on the one hand a bright field illumination unit 660 provided, which by means of a first holder 664 is spatially fixed. The corresponding bright field illumination light is denoted by the reference numeral 665 Mistake. On the other hand is a dark field illumination unit 670 provided, which by means of a second holder 674 is spatially fixed. The corresponding bright field illumination light is denoted by the reference numeral 675 Mistake.

The second holder 674 is with an opening 681 provided through which a front portion of the endoscope 620 is guided.

The two brackets 664 and 674 are over a crossbeam 680 connected, which has a recess 682 having. The recess 682 allows movement of a placement head, not shown, near the wafer surface. The placement head is in particular a so-called turret, in which a plurality of holding devices are rotatable about an axis of rotation in a star-shaped arrangement.

It should be noted that the two lighting units 660 and 670 are independently controllable, so that depending on the optical properties of the surfaces of the components 641 a bright field illumination and / or a dark field illumination can be adjusted. Furthermore, in the case of components which are particularly difficult to detect, sequential component detection with two different types of illumination is also possible, with accurate measurement being possible only by evaluating two images of one and the same component recorded with different illuminations.

The However, not only do the optical inspection system shown enable Measurement of electronic components. The inspection system Rather, they are also suitable for a recognition (a) of marks, for example on printed circuit boards, (b) of edges of objects, (c) of Inkpoints for example for individual marking of individual components or (d) of other structures or contours.

It It should be noted that the embodiments described herein only a limited one Choice of possible variants represent the invention. So it is possible the characteristics of individual embodiments suitably combine with each other, so for the skilled person with the explicit variants here a variety of different embodiments as obvious to be disclosed.

In summary, it remains to be stated:

It becomes an optical inspection system 100 for the measurement of electronic components 141 described, which are located in a given spatial detection area. The inspection system 100 points to a camera 330 , which for detecting a component located in the detection area 141 is set up, and a light guide 120 . 320 which has an optical input 320a and an optical output 320b having, wherein the optical output 320b with the camera 33 ) is optically coupled and the optical input 320a is introduced to the detection area. The light-guiding device is preferably an endoscope 120 . 320 which is a close approach to the optical input 320a to be measured components 141 allows and thus ensures component detection without major interference edges. Furthermore, two lighting units are preferred 660 . 670 provided, wherein a lighting unit 660 for a bright field illumination and the other illumination unit 670 is provided for a dark field illumination of the detection area. The optical detection system 100 Compared to conventional inspection systems, it can be implemented within a much more compact design so that it is also possible to inspect unhoused components that are still located on a wafer carrier.

Claims (13)

Optical inspection system for measuring electronic components ( 141 ), which are located in a given spatial detection area, the inspection system ( 100 ) comprising • a camera ( 330 ), which is used to detect a component in the detection area ( 141 ), and • a light-conducting device ( 120 . 320 ), which has an optical input ( 320a ) and an optical output ( 320b ), wherein the optical output ( 320b ) with the camera ( 330 ) is optically coupled and the optical input ( 320a ) is brought to the detection area. An optical inspection system according to claim 1, wherein the light-guiding device is an endoscope ( 120 . 320 ). Optical inspection system according to claim 2, wherein the endoscope ( 120 . 320 ) is a rigid structure. Optical inspection system according to one of claims 2 to 3, wherein the endoscope ( 120 . 320 ) is arranged such that a component located in the detection area ( 141 ) is detectable at an oblique angle. Optical inspection system according to one of claims 2 to 4, wherein the endoscope ( 120 . 320 ) is arranged such that components ( 141 ) at least in the vicinity of its pick-up position before being picked up by a holding device ( 152 ) of a placement head ( 150 ) are measurable. Optical inspection system according to one of claims 2 to 5, wherein the endoscope ( 120 . 220 . 320 ) relative to a chassis ( 205 ) is slidably mounted. Optical inspection system according to one of claims 2 to 6, wherein the endoscope ( 120 . 320 ) an optical deflection element ( 323 ), which at the optical input ( 320a ) is arranged. An optical inspection system according to claim 7, wherein the endoscope ( 120 . 320 . 520 ) is rotatably mounted. An optical inspection system according to any one of claims 1 to 8, additionally comprising A first lighting unit ( 160 . 460 . 660 ) arranged to illuminate the detection area at a first angle. Optical inspection system according to one of claims 1 to 9, additionally comprising • a second illumination unit ( 470 . 670 ) arranged to illuminate the detection area at a second angle. Optical inspection system according to one of claims 9 to 10, wherein the first illumination unit ( 160 . 460 . 660 ) and / or the second lighting unit ( 470 . 670 ) a board ( 161 . 461 . 471 ), on which a plurality of light-emitting diodes ( 162 . 462 . 473 ) are arranged. Optical inspection system according to one of claims 1 to 11, additionally comprising • one of the cameras ( 330 ) downstream evaluation unit ( 332 ) for position detection and / or for Typerkennung of optically detected components ( 141 ). Optical inspection system according to claim 12, wherein the evaluation unit ( 332 ) is arranged such that a distortion of one of the camera ( 330 ) of a component ( 141 ) is compensatable.