JPWO2013153645A1 - Imaging apparatus and image processing apparatus - Google Patents

Abstract

The imaging device 22 is configured to capture and image both the component 18 and the reference position mark 25 that are two imaging targets within the image circle 26, and the main imaging element 27 and the mark imaging element 28 are respectively It is arranged at a position that falls within the range of the focal depth with respect to the imaging plane (focal plane) of the imaging target. At the time of imaging, the component 18 is imaged by the main image sensor 27, the reference position mark 25 is imaged by the mark image sensor 28, and the image signal output from each of the image sensors 27 and 28 is subjected to image processing to obtain the reference position mark. 25, the suction position of the component 18 with respect to the suction nozzle 17 is recognized.

Description

  The present invention relates to an imaging apparatus and an image processing apparatus that capture and image a plurality of imaging targets within an image circle of one lens system.

  For example, in a component mounting machine, as described in Patent Document 1 (Japanese Patent Application Laid-Open No. 2002-94296), when a component is sucked into the suction nozzle and mounted on a circuit board, the component sucked into the suction nozzle Is picked up by the camera from below, the image signal is processed to recognize the suction position of the component, and the deviation of the suction position of the component with respect to the suction nozzle (shift between the center of the component and the center of the suction nozzle) is taken into account. The component is mounted on a circuit board. At this time, since the center of the suction nozzle is hidden behind the part in the image picked up by the suction nozzle, the center of the suction nozzle is accurately aligned with the center of the camera. Although it is necessary to stop, if the center of the suction nozzle is accurately aligned with the center of the camera and stopped every time the parts are imaged, the time required from picking up the parts to mounting becomes longer, and the productivity decreases. To do.

  Therefore, in Patent Document 1, a reference pin is provided downward at a predetermined position with respect to the suction nozzle, the lower end of the reference pin is used as a reference mark, and the height position of the reference mark is set to the lower end of the suction nozzle. Set the height to approximately the same as that of the part, and pick up both the part sucked by the suction nozzle and the reference mark in the camera's field of view when picking up the part. By recognizing the position, it is possible to measure the displacement of the suction position of the component with respect to the suction nozzle (shift between the center of the component and the center of the suction nozzle). In this way, it is not necessary to accurately align the center of the suction nozzle with the center of the camera when imaging the part, and even if the part is imaged while moving the suction nozzle (that is, the center of the suction nozzle is away from the center of the camera). It is possible to measure the displacement of the suction position of the component with respect to the suction nozzle.

Japanese Patent Laid-Open No. 2002-94296

  By the way, as shown in FIG. 2, when both the component 31 attracted by the suction nozzle 30 and the reference position mark 32 are imaged on the light receiving surface of the image sensor 33 through the lens of the camera, the image of the component 31 is obtained. The image of the reference position mark 32 is imaged in a region near the end of the light receiving surface of the image sensor 33. Since the position of the reference position mark 32 needs to be positioned outside the existing range of the component 31 of the maximum size that can be sucked by the suction nozzle 30, the region near the two sides of the light receiving surface of the image sensor 33 is the reference position. Only the mark 32 is captured in the region B, and cannot be used as the region A for capturing the component 31. For this reason, the image pickup device 33 that picks up both the component 31 and the reference position mark 32 needs to use an image pickup device 33 having a large size in which the number of vertical and horizontal pixels is increased by the image pickup region B of the reference position mark 32 as compared with the related art. In addition, if the size of the image sensor 33 is increased, the image circle 34 (a circular area where the imaging object is sharply imaged through the lens of the camera) needs to be increased accordingly. However, there is a drawback that the cost increases greatly.

  By the way, when the height position of the reference position mark 32 (the lower end of the reference pin) is set to the same height as the lower surface of the component 31 to be imaged, the component 31 is mounted on the substrate when the component 31 is sucked by the suction nozzle 30. When the reference position mark 32 may collide with surrounding objects, the height position of the reference position mark 32 may be slightly higher than the height position of the lower surface of the part 31 to be imaged. Need to avoid. For this reason, the positions of the imaging planes of the two imaging targets (the component 31 and the reference position mark 32) are shifted back and forth in the optical axis direction, and when one of the imaging targets is focused, the other imaging target is focused. Is not suitable, and the captured image is blurred.

  As a countermeasure, if the lens aperture is narrowed to increase the depth of field (the range that appears to be in focus), the captured image becomes dark and the shutter speed must be reduced. For this reason, when imaging a moving imaging target, there is a possibility that the imaging target is blurred and the image recognition accuracy deteriorates.

  Accordingly, the problem to be solved by the present invention is to realize a compact (space saving) and cost reduction of an imaging device that captures a plurality of imaging targets, while reducing the depth of field without increasing the depth of field. It is to be able to image all the imaging targets in focus and to improve the image recognition accuracy of a plurality of imaging targets.

  In order to solve the above-described problems, the present invention provides an imaging apparatus that captures and captures a plurality of imaging targets within an image circle of a single lens system, and includes a plurality of imaging elements that capture the plurality of imaging targets, Each of the image pickup devices picks up a different image pickup object, and is arranged at a position that is optically within the range of the focal depth with respect to the imaging plane (focal plane) of the image pickup object. Is. Here, the depth of focus is a distance on the optical axis where the blur of the image falls within the allowable blur. If the focal depth is within the range of the focal depth, the blur of the image falls within the allowable blur. A sufficiently clear image can be obtained.

  Further, the image circle is a circular area where an imaging target sharply forms an image through a lens system (one lens or a group of lenses), whereas each imaging element has a rectangular shape. In consideration of this point, the present invention is configured so that a plurality of imaging elements that capture a plurality of imaging targets for each imaging target are arranged in a circular image circle, so that the entire area of the circular image circle is effectively used. It is possible to use a plurality of image sensors in a space-efficient manner, and to effectively use the entire light-receiving surface of all the image sensors as an imaging area for imaging. Thereby, since it is not necessary to increase the size of the imaging element and the image circle, it is possible to realize a compact (space-saving) imaging apparatus that captures a plurality of imaging targets. In addition, since each imaging device can use a small-sized imaging device, it is relatively inexpensive, and compared with the conventional configuration in which a plurality of imaging objects are collectively imaged with one large imaging device. Cost reduction can also be realized. Furthermore, in the present invention, each imaging element is disposed at a position optically within the range of the depth of focus with respect to the imaging plane (focal plane) of each imaging target, so that a plurality of imaging targets are within the same plane. Even if it is not located at the position, it is possible to capture all of the plurality of imaging targets in focus without increasing the depth of field, and the image recognition accuracy of the plurality of imaging targets can be improved.

INDUSTRIAL APPLICABILITY The present invention can be widely applied to devices equipped with an imaging device that captures and images a plurality of imaging objects that are not located in the same plane within an image circle of one lens system, and is applied to, for example, a component mounting machine. In this case, one of the plurality of imaging targets is a component to be mounted by a component mounter, and the imaging device that captures the component is an imaging device that is larger than the other imaging devices, and is in the image circle. The other imaging object is a mark indicating a reference position or information of the component, and a configuration in which an imaging element for imaging a mark for imaging the mark is arranged outside the imaging element for imaging the component And good. In this way, it is possible to arrange the image pickup device for mark imaging by effectively using the empty space outside the image pickup device for picking up components in the circular image circle.

  In addition, the present invention mounts a plurality of image sensors on the same circuit board, and the position of the image sensor having the longer distance from the lens system to the imaging surface of the imaging target is within the depth of focus range. An optical device that arranges the circuit board and shortens the optical distance (optical path length) on the light receiving surface side of the image pickup device having a shorter distance from the lens system to the imaging surface of the image pickup object among the plurality of image pickup devices. It is good also as a structure which provided the distance adjustment means. Here, as the optical distance adjusting means, for example, a glass plate, a small lens or the like may be used. In this configuration, since a plurality of image sensors can be mounted on the same circuit board, the mounting structure of the plurality of image sensors can be simplified and the cost can be reduced.

  When the present invention is applied to a component mounting machine, one imaging target among a plurality of imaging targets is a component sucked by a suction nozzle of the component mounting machine, and the other imaging target is set to the suction nozzle. A reference position mark provided at a predetermined position may be used, and an image signal output from the imaging apparatus may be processed so that the position of the component is recognized by the image processing means with reference to the reference position mark. In this way, in the component mounting machine, it is possible to realize a compact (space saving), cost reduction, and image recognition accuracy improvement of the imaging device that images both the component sucked by the suction nozzle and the reference position mark.

FIG. 1 is a longitudinal sectional view showing a configuration of a component mounter showing Embodiment 1 of the present invention. FIG. 2 is a diagram showing the arrangement relationship between the image circle and the image sensor in the conventional example. FIG. 3 is a diagram illustrating a positional relationship among the image circle, the main image sensor, and the mark image sensor in the first embodiment. FIG. 4 is a diagram illustrating the positional relationship among the component, the reference position mark, the lens, and each image sensor in the first embodiment. FIG. 5 is a diagram illustrating the positional relationship among the components, the reference position mark, the lens, and each image sensor in the second embodiment. FIG. 6 is a diagram illustrating the positional relationship between the image circle, the main image sensor, and the two mark image sensors in the third embodiment.

  Hereinafter, three embodiments 1 to 3 in which a mode for carrying out the present invention is applied to a component mounter will be described.

A first embodiment of the present invention will be described with reference to FIGS.
First, a schematic configuration of the entire component mounter will be described with reference to FIG.

  The X-axis slide 11 is provided so as to be slidable in the X-axis direction (left-right direction in FIG. 1) by the X-axis ball screw 12, and the Y-axis slide 13 is moved by the Y-axis ball screw 14 relative to the X-axis slide 11. It is provided so as to be slidable in the Y-axis direction (perpendicular to the plane of FIG. 1).

  A mounting head 15 is provided on the Y-axis slide 13, and a nozzle holder 16 is provided on the mounting head 15 so as to be movable up and down in the Z-axis direction (vertical direction) via a Z-axis drive mechanism (not shown). The suction nozzle 17 is attached to the nozzle holder 16 downward. The mounting head 15 is configured to be rotatable around a central axis (Z axis) by a rotation mechanism (not shown), and the component 18 is mounted when the component 18 sucked by the suction nozzle 17 is mounted on a circuit board. The direction of the can be adjusted.

  On the other hand, on the X-axis slide 11, an image pickup device 22 (parts camera) for recognizing a part position that picks up the part 18 (image pickup target) sucked by the suction nozzle 17 from the lower surface side through the pair of reflecting mirrors 20 and 21. Is provided. A ring-shaped front light 23 is provided above the reflecting mirror 20 positioned below the component 18 sucked by the suction nozzle 17 as an illumination light source for illuminating the component 18 sucked by the suction nozzle 17 from its lower surface side. . Note that the imaging device 22 may be arranged directly below the suction nozzle 17.

  In the first embodiment, the reference pin 24 is provided downward at a predetermined position in the upper end flange portion 17a of the suction nozzle 17, and the lower end of the reference pin 24 is used as a reference position mark 25 indicating the reference position. At the same time, the height position of the reference position mark 25 is set to be slightly higher than the height position of the lower surface of the component 18 sucked by the suction nozzle 17. This is to prevent the lower end (reference position mark 25) of the reference pin 24 from colliding with a surrounding object when the component 18 is attracted to the suction nozzle 17 or when the component 18 is mounted on the substrate. The position of the reference position mark 25 is located outside the existence range of the component 18 of the maximum size that can be sucked by the suction nozzle 17 and serves as a reference position when the position of the component 18 is recognized.

  As shown in FIG. 3, the imaging device 22 is configured to capture and image both the component 18 and the reference position mark 25 that are two imaging targets within an image circle 26. Here, the image circle 26 is a circular region in which an imaging target sharply forms an image through the lens 36 (one lens or a group of lenses) of the imaging device 22. A rectangular main image sensor 27 that images the component 18 is arranged in the image circle 26, and the reference position mark 25 is imaged at a predetermined position outside the main image sensor 27 in the image circle 26. A mark imaging device 28 is arranged.

  As described above, the reference position mark 25 (the lower end of the reference pin 24) is prevented from colliding with surrounding objects when the component 18 is sucked to the suction nozzle 17 or when the component 18 is mounted on the substrate. It is necessary to avoid a collision by making the height position of the reference position mark 25 slightly higher than the height position of the lower surface of the part 18 to be imaged. For this reason, as shown in FIG. 4, the positions of the imaging surfaces of the two imaging targets (component 18 and reference position mark 25) are shifted back and forth in the optical axis direction, and when focusing on one imaging target, The other imaging object is not focused and the captured image is blurred.

  As a countermeasure, if the aperture of the lens 36 is reduced to increase the depth of field (the range that appears to be in focus), the captured image becomes dark, and the shutter speed must be reduced. For this reason, when imaging a moving imaging target, there is a possibility that the imaging target is blurred and the image recognition accuracy deteriorates.

  Therefore, in the first embodiment, as shown in FIG. 4, the main image sensor 27 and the mark image sensor 28 for imaging two imaging objects (the component 18 and the reference position mark 25) are respectively imaged on the imaging objects. It arrange | positions in the position settled in the range of a focal depth with respect to a surface (focal plane). Here, the depth of focus is a distance on the optical axis where the blur of the image falls within the allowable blur. If the focal depth is within the range of the focal depth, the blur of the image falls within the allowable blur. A sufficiently clear image can be obtained.

  The control device (image processing means) of the component mounting machine controls the operation of adsorbing the component 18 supplied from a feeder (not shown) to the suction nozzle 17 and mounting it on the circuit board during production. In the middle of transferring the component 18 adsorbed by the circuit board 17 to the circuit board side, the component 18 is passed through the imaging position (above the front light 23), and both the component 18 and the reference position mark 25 are moved from below to the front light 23. The operation of illuminating and imaging with the imaging device 22 is controlled. At the time of imaging, the component 18 is imaged by the main image sensor 27, the reference position mark 25 is imaged by the mark image sensor 28, and the image signal output from each of the image sensors 27 and 28 is subjected to image processing to obtain the reference position mark. 25, the suction position of the component 18 with respect to the suction nozzle 17 is recognized.

  As described above, the image circle is a circular region in which the imaging target sharply forms an image through the lens 36, whereas each of the imaging elements 27 and 28 has a rectangular shape. In consideration of this point, in the first embodiment, since the two imaging elements 27 and 28 for imaging two imaging targets (the component 18 and the reference position mark 25) are arranged in a circular image circle, By effectively using the entire area of the circular image circle, the two image sensors 27 and 28 can be arranged in a space-efficient manner, and the entire light receiving surface of each image sensor 27 and 28 can be effectively used as the imaging area of the imaging target. . Thereby, since it is not necessary to increase the size of the two image pickup devices 27 and 28 and it is not necessary to increase the image circle, it is possible to realize a compact (space-saving) image pickup apparatus 22 that picks up two image pickup targets. . In addition, since each of the image sensors 27 and 28 can use an image sensor having a small size, it is relatively inexpensive, and compared with a conventional configuration in which two image targets are collectively imaged with one large image sensor. Cost reduction of the imaging device 22 can also be realized.

  Furthermore, in the first embodiment, each of the image sensors 27 and 28 is disposed at a position that falls within the range of the depth of focus with respect to the imaging plane (focal plane) of each imaging target. 18 and the reference position mark 25) are not located in the same plane, it is possible to focus and image both of the two imaging objects without increasing the depth of field. The image recognition accuracy of the target can also be improved.

  Further, since the image pickup device of the image pickup device 22 is divided into the main image pickup device 27 for picking up the component 18 and the mark image pickup device 28 for picking up the reference position mark 25, various image processing methods can be employed. For example, the image processing of the component 18 and the image processing of the reference position mark 25 may be performed separately in parallel, or the image processing of the main image sensor 27 is performed after the image processing of the mark image sensor 28 is performed first. It may be started. Further, the data transfer between the mark image sensor 28 and the main image sensor 27 may be executed in parallel, or the position recognition of the reference position mark 25 and the position recognition of the component 18 may be executed in parallel. .

  In the first embodiment, the reference pin 24 (reference position mark 25) is provided on the upper end flange portion 17a of the suction nozzle 17. However, the reference pin 24 (reference position mark 25) may be provided on the nozzle holder 16. The reference pin 24 (reference position mark 25) may be provided at a predetermined position.

  In the first embodiment, when the mark image pickup device 28 is attached to the circuit board on which the main image pickup device 27 is mounted, the mark image pickup device 28 may be attached to the circuit board via a spacer member. Depending on the terminal structure of the mark image sensor 28 and the thickness of the spacer member, the wiring structure for connecting the terminal of the mark image sensor 28 to the circuit board of the main image sensor 27 may be complicated, or the mark image sensor 28 may be It is necessary to provide a circuit board to be mounted separately from the circuit board of the main image sensor 27.

  Therefore, in the second embodiment of the present invention, as shown in FIG. 5, the main image sensor 27 and the mark image sensor 28 are mounted on the same circuit board 37, and the distance from the lens 36 to the imaging plane of the imaging target The circuit board 37 is arranged so that the position of the main image sensor 27 that is the longer image sensor is within the range of the depth of focus. Further, an optical distance (optical path length) is formed on the light receiving surface side of the mark image sensor 28 which is an image sensor having a shorter distance from the lens 36 of the two image sensors 27 and 28 to the imaging surface to be imaged. The optical distance adjusting means 38 for shortening the distance is provided. Here, as the optical distance adjusting means 38, for example, a glass plate, a small lens or the like may be used. Other configurations are the same as those of the first embodiment.

  In the second embodiment described above, since the two image sensors 27 and 28 can be mounted on the same circuit board 37, the mounting structure of the two image sensors 27 and 28 can be simplified and the cost can be reduced. In addition, the same effects as those of the first embodiment can be obtained.

  In the present invention, the reference position mark 25 may be provided in only one place as in the first and second embodiments. In this case, however, one reference is made in the coordinate system of the imaging device 22 (the coordinate system of the captured image). The position of the component 18 can only be measured using the position mark 25 as a reference, and the position of the suction nozzle 17 that is hidden behind the component 18 from the imaging device 22 side cannot be recognized. When the image of the state in which the position of the component 18 is relatively displaced in the rotation direction of the mounting head 15 due to the displacement of the position mark 25 in the rotation direction of the mounting head 15, It cannot be distinguished from the case where the state where the suction position is actually deviated is imaged.

  Therefore, in the third embodiment of the present invention shown in FIG. 6, reference position marks 25 </ b> X and 25 </ b> Y are provided at two positions in the X direction and Y direction determined in advance with respect to the suction nozzle 17, and The mark image pickup devices 28X and 28Y are provided at two locations in the X direction and Y direction outside the main image pickup device 27, respectively, and the reference image marks 25X and 25Y are imaged by the mark image pickup devices 28X and 28Y, respectively. ing. Each of the mark image pickup devices 28X and 28Y is disposed at a position optically within the range of the focal depth with respect to the imaging plane (focal plane) of the reference position marks 25X and 25Y that are the imaging targets. Other matters are the same as those in the first or second embodiment.

In the third embodiment described above, even if there is a situation in which the position of the suction nozzle 17 is hidden behind the component 18 from the imaging device 22 side, the suction nozzle 17 cannot be seen from the positions of the two reference position marks 25X and 25Y. Since the position is uniquely determined, the position of the suction nozzle 17 and the position of the component 18 can be accurately measured with reference to the two reference position marks 25X and 25Y in the coordinate system of the imaging device 22 (the coordinate system of the captured image). Even if the position of the reference position mark 25 is shifted in the rotation direction of the mounting head 15 due to the shift of the rotation stop position of the mounting head 15, the suction position of the component 18 with respect to the suction nozzle 17 can be accurately measured.
[Other Examples]
In the first to third embodiments, the component 18 sucked by the suction nozzle 17 of the component mounting machine is the imaging target. However, the component supplied from the feeder, the component mounted on the board, or the like is the imaging target, and these are viewed from above. You may apply this invention to the imaging device which images.

  Further, the mark imaged by the mark image sensor is not limited to the reference position mark, and an information mark such as a two-dimensional code or a one-dimensional code displaying information of an imaging target (component 18 or the like) may be imaged. Of course, an object other than the mark may be the imaging target.

In addition, the present invention is not limited to a component mounting machine, and is widely applied to devices equipped with an imaging device that captures and images a plurality of imaging targets that are not located in the same plane within an image circle of one lens system. Needless to say, various modifications can be made without departing from the scope of the invention.

  DESCRIPTION OF SYMBOLS 11 ... X-axis slide, 13 ... Y-axis slide, 15 ... Mounting head, 16 ... Nozzle holder, 17 ... Adsorption nozzle, 18 ... Parts (imaging object), 20, 21 ... Reflector, 22 ... Imaging device, 23 ... Front Light, 24 ... reference pin, 25, 25X, 25Y ... reference position mark (imaging target), 26 ... image circle, 27 ... main image sensor, 28, 28X, 28Y ... mark image sensor, 36 ... lens, 37 ... circuit Substrate, 38 ... optical distance adjusting means

Claims (4)

In an imaging apparatus that captures and images a plurality of imaging targets within an image circle of one lens system,
Comprising a plurality of imaging elements for imaging the plurality of imaging targets;
The image pickup device is characterized in that each of the image pickup devices picks up different image pickup targets and is disposed at a position optically within a depth of focus range with respect to an imaging plane of the image pickup target. One imaging object of the plurality of imaging objects is a component to be mounted by a component mounter, and an image sensor that captures the component is an image sensor larger than other image sensors, and the image circle Is located in the center of the inside,
The other imaging target is a mark indicating a reference position or information of the component, and the other imaging element that images the mark is arranged outside the imaging element that images the component. The imaging device according to claim 1. The plurality of image pickup devices are mounted on the same circuit board, and the position of the image pickup device having the longer distance from the lens system to the imaging plane of the image pickup target is within the range of the depth of focus. The circuit board is placed,
An optical distance adjusting means for shortening the optical distance is provided on the light receiving surface side of the image pickup device having a shorter distance from the lens system to the imaging surface of the image pickup target among the plurality of image pickup devices. The imaging apparatus according to claim 1 or 2, wherein One imaging target among the plurality of imaging targets is a component sucked by a suction nozzle of a component mounting machine,
The other imaging object is a reference position mark provided at a predetermined position with respect to the suction nozzle,
An image processing unit that processes an image signal output from the imaging apparatus according to claim 1 and recognizes a position of the component with reference to the reference position mark is provided. Image processing device.

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