JP6196684B2 - Inspection device - Google Patents

Description

  The present invention relates to an inspection apparatus, and more particularly to an inspection apparatus that determines pass / fail as an inspection result of an inspection object.

  2. Description of the Related Art Conventionally, an inspection apparatus that determines pass / fail as an inspection result of an inspection object is known. Such an inspection apparatus is disclosed in, for example, Japanese Patent Application Laid-Open No. 2009-170517.

  JP 2009-170517 A discloses a component that includes a control device (main control unit) that controls the operation of the component recognition device and a camera unit that includes a TDI sensor that captures an image of a predetermined region of the inspection object. A recognition device is disclosed. In addition, the component recognition device includes an image capturing device that performs predetermined processing on an image captured by the camera unit and transmits the image to the control device. The control device controls the image capturing device to transmit a plurality of imaging operation trigger signals to the camera unit when imaging a predetermined region of the inspection object. And the setting for imaging with an image taking-in apparatus is performed with respect to a camera unit. In addition, the image of the predetermined area captured by the camera unit is output to the image capturing device, subjected to predetermined processing, and then transmitted to the control device. And the pass / fail which is an inspection result about a test subject is discriminated by a control device.

JP 2009-170517 A

  However, in the component recognition apparatus disclosed in Japanese Patent Application Laid-Open No. 2009-170517, the control device (main control unit) is in parallel with the operation control of the component recognition device when determining pass / fail as the inspection result of the inspection object. In order to determine whether the inspection object is acceptable or not, the processing load on the control device increases, and as a result, the time for acquiring the inspection result for the inspection object increases. In addition, when the predetermined region of the inspection object is imaged a plurality of times, the operation trigger signal is transmitted a plurality of times from the control device to the image capturing device, and the setting for performing imaging is set to the camera unit by the image capturing device. Done. For this reason, since it takes time to set for imaging, it takes a long time to acquire the inspection result of the inspection object. Therefore, it is desired to shorten the time for acquiring the inspection result for the inspection object.

  The present invention has been made in order to solve the above-described problems, and one object of the present invention is to provide an inspection apparatus capable of shortening the time for acquiring the inspection result of the inspection object. Is to provide.

An inspection apparatus according to one aspect of the present invention includes: a main control unit that performs operation control of the entire inspection apparatus; an inspection head that can move above the substrate and has an imaging unit that images the substrate ; Based on receiving the imaging operation trigger signal for the first time, the imaging unit is caused to capture an image of the predetermined region of the substrate a plurality of times at different timings, and the inspection of the substrate is performed based on the image of the predetermined region captured by the imaging unit. A sub-control unit that determines whether the result is acceptable or not, and the sub-control unit is provided so as to be movable together with the inspection head on the inspection head, and based on receiving one imaging operation trigger signal from the main control unit, to perform a plurality of times of imaging operations in different imaging conditions each time of imaging the imaging section of the inspection head, based on an image of a predetermined area of the substrate which is imaged at different imaging conditions each time the imaging Is configured to determine the acceptance or rejection is a test result for the substrate.

In the inspection apparatus according to one aspect of the present invention, as described above, by providing a sub-control unit that determines pass / fail as the inspection result for the substrate based on the image of the predetermined area captured by the imaging unit, the inspection is performed. The sub-control unit different from the main control unit that controls the operation of the entire apparatus can determine whether or not the substrate is acceptable. Thereby, unlike the case where the main control unit determines whether or not the substrate is accepted in parallel with the operation control of the entire inspection apparatus, the time for acquiring the inspection result for the substrate can be shortened. In addition, an image pickup unit that picks up an image of a predetermined region of the substrate a plurality of times based on the reception of a single imaging operation trigger signal from the main control unit is used to pick up an image of the predetermined region of the substrate a plurality of times. In contrast, when the setting for performing imaging by transmitting a plurality of imaging operation trigger signals from the main control unit to the imaging unit is performed on the imaging unit, the main control unit performs the imaging operation. There is no need to transmit the imaging operation trigger signal a plurality of times. This also shortens the time for acquiring the inspection result for the substrate .

Further, the sub control unit causes the imaging unit to perform the imaging operation a plurality of times under different imaging conditions for each imaging based on the reception of the one imaging operation trigger signal from the main control unit. based on the image of a predetermined area taken at different imaging conditions each time, and is configured to determine the acceptance or rejection is a test result for the substrate. As a result, even when the imaging unit performs imaging of a predetermined region multiple times under different imaging conditions for each imaging, the imaging control trigger signal is transmitted once from the main control unit, and multiple times under different imaging conditions. Thus, it is possible to capture an image of a predetermined area under different imaging conditions.
Moreover, since the wiring used for the sub-control unit can be shortened, the wiring can be easily handled.

In the inspection apparatus according to the above aspect, the inspection head includes an illumination unit, and the sub-control unit receives a single imaging operation trigger signal from the main control unit, so that the imaging unit has a predetermined region of the substrate . When the image is captured a plurality of times, the illumination unit is controlled so that illumination light is irradiated in synchronization with the imaging operation of the imaging unit. If comprised in this way, while imaging the predetermined area | region of a board | substrate several times with one imaging operation trigger signal, illumination light can be irradiated so that it may synchronize with the imaging operation of an imaging part.

In the inspection apparatus according to the above aspect, preferably, when the sub-control unit determines that the inspection result for the substrate is acceptable, the sub-control unit transmits information indicating that the inspection result for the substrate is acceptable to the main control unit. and, the inspection result when it is determined that it is not the pass is configured to transmit the image information test results indicating non-acceptance information with the substrate of about board to the main control unit for the substrate. If comprised in this way, according to the test result about a board | substrate , since only required information is transmitted to a main control part, it can suppress that the processing load of a main control part becomes large.

In this case, preferably, the apparatus further includes a storage unit for storing a pass / fail determination program for determining pass / fail as an inspection result for the substrate , and an imaging operation program for causing the imaging unit to perform an imaging operation. The inspection head is disposed in the vicinity of the inspection head. If comprised in this way, since the wiring used for a memory | storage part can be shortened, routing of wiring can be performed easily.

  According to the present invention, as described above, the time for acquiring the inspection result for the inspection object can be shortened.

It is a figure which shows the external appearance of the test | inspection apparatus by one Embodiment of this invention. It is the top view which showed the inside of the inspection apparatus by one Embodiment of this invention. It is the side view which showed the inside of the test | inspection apparatus by one Embodiment of this invention. It is the block diagram which showed the structure of the test | inspection apparatus by one Embodiment of this invention. It is the schematic diagram which showed the exchange of the data of the main control part of the test | inspection apparatus by one Embodiment of this invention, and a sub control part. It is a flowchart (first half part) for demonstrating the imaging of the inspection apparatus by one Embodiment of this invention, and a pass / fail determination process. It is a flowchart (latter half part) for demonstrating the imaging of the inspection apparatus by one Embodiment of this invention, and a pass / fail determination process.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  First, the structure of the inspection apparatus 100 according to an embodiment of the present invention will be described with reference to FIGS.

  The inspection apparatus 100 is an apparatus for performing various inspections such as whether or not the solder is accurately printed on the substrate 110 (see FIG. 2) and whether or not the component is accurately mounted on the substrate 110. The substrate 110 is an example of the “inspection object” in the present invention.

  As shown in FIG. 2, the inspection apparatus 100 includes a substrate transfer conveyor (hereinafter referred to as a conveyor) 10 provided on the base 1, an X beam 20, a Y beam 30, an inspection head 40, and a controller 50. It has. The inspection apparatus 100 includes a display unit 60 as shown in FIG. In addition, the inspection apparatus 100 includes an opening 101 for carrying out the substrate 110 that has been inspected.

  As shown in FIG. 2, the conveyor 10 has a function of holding the substrate 110 and transporting it from the X2 direction to the X1 direction. The conveyor 10 is a position between the carry-in part 11 arranged on the apparatus upstream side (X2 direction side), the carry-out part 12 arranged on the apparatus downstream side (X1 direction side), and the carry-in part 11 and the carry-out part 12. And a fixed portion 13 disposed on the surface. Further, the fixing unit 13 is configured to fix the substrate 110 at a predetermined position on the fixing unit 13 by a holding mechanism (not shown). At this predetermined position, the substrate 110 is inspected. The carry-in unit 11 is configured to carry the substrate 110 into the fixed unit 13 of the inspection apparatus 100. Further, the carry-out unit 12 is configured to carry out the substrate 110 from the fixed unit 13 toward the opening 101 (see FIG. 1).

  The X beam 20 is configured to support the inspection head 40 so as to be movable in the X direction. Specifically, the X beam 20 includes an X beam motor 21, and the inspection head 40 moves along the X beam 20 by driving the X beam motor 21. The Y beam 30 is configured to support the inspection head 40 so as to be movable in the Y direction. Specifically, the Y beam 30 includes a Y beam motor 31, and the inspection head 40 moves along the Y beam 30 when the Y beam motor 31 is driven. By these, the inspection head 40 can move in the XY plane.

  The inspection head 40 has a function of imaging the substrate 110. The inspection head 40 is provided so as to be movable above the substrate 110. In addition, the inspection head 40 inspects the substrate 110 while being moved above the substrate 110. The inspection head 40 will be described in detail later.

  As shown in FIG. 4, the controller 50 includes a communication unit 51, a beam motor control unit 52, a storage unit 53, an image processing unit 54, and a main CPU 55. The main CPU 55 is an example of the “main control unit” in the present invention.

  The communication unit 51 is configured to exchange information with a later-described communication unit 41 of the inspection head 40.

  The beam motor control unit 52 is configured to control the driving of the X beam motor 21 and the Y beam motor 31 by being controlled by the main CPU 55. Thereby, the inspection head 40 can be moved to a predetermined inspection position on the substrate 110.

  The storage unit 53 stores an imaging sequence program 70 for causing the inspection head 40 to perform an imaging operation, and a pass / fail determination program 80 for determining whether the inspection head 40 is an inspection result for the substrate 110. . The imaging sequence program 70 is a program for controlling the illumination operation of the illumination unit 42 and the imaging operation of the imaging unit 43 when inspecting the substrate 110. The storage unit 53 stores reference data (hereinafter referred to as master data 90) for determining whether or not the substrate 110 is acceptable by comparing with image data of the substrate 110 to be inspected. The imaging sequence program 70 corresponding to the substrate 110 is stored in the storage unit 53 in advance. The imaging sequence program 70 is an example of the “imaging operation program” in the present invention.

  The image processing unit 54 performs processing so that the main CPU 55 can display the image information transmitted from the sub CPU 47 on the display unit 60 as described later.

  The main CPU 55 (controller 50) is configured to control the operation of the entire inspection apparatus 100 according to a predetermined program. For example, the main CPU 55 exchanges information with the sub CPU 47 of the inspection head 40, and transmits the imaging sequence program 70, pass / fail judgment program 80 and master data 90 stored in the storage unit 53 to the inspection head 40. It is configured as follows. Further, the imaging sequence program 70, the pass / fail determination program 80 and the master data 90 transmitted to the inspection head 40 are stored in the storage unit 46 of the inspection head 40. The main CPU 55 is configured to transmit an imaging operation trigger signal to the inspection head 40 (sub CPU 47).

  The display unit 60 is configured to display the inspection result of the substrate 110 based on the control of the main CPU 55.

  Next, the configuration of the inspection head 40 will be described.

  In this embodiment, as shown in FIG. 4, the inspection head 40 includes a communication unit 41, an illumination unit 42, an imaging unit 43, and a drive unit 44. The inspection head 40 includes an image processing unit 45, a storage unit 46, and a sub CPU 47. The communication unit 41, the storage unit 46, the sub CPU 47, and the image processing unit 45 are all arranged on one substrate and provided on the inspection head 40. The sub CPU 47 is an example of the “sub control unit” in the present invention.

  The illumination unit 42 is configured to emit illumination light when imaging the substrate 110 based on control by the sub CPU 47. The illumination unit 42 is a light source such as a white LED light source. Further, as shown in FIG. 5, the illumination unit 42 includes an upper illumination unit 421, a middle illumination unit 422, and a lower illumination unit 423 in order from the upper side on the inner surface side of the dome-shaped case 42 a. Further, as viewed from above, the upper illumination unit 421, the middle illumination unit 422, and the lower illumination unit 423 are arranged so as to surround the imaging unit 43 in a ring shape. Each illumination unit is provided in plural, and is configured to be able to irradiate light for two-dimensional inspection that can acquire information on hue (gradation), saturation, and brightness. Thereby, it is possible to detect a thin film-like foreign substance or the like adhering to the substrate 110. For simplification, in FIG. 2 and FIG. 5, the substrate 110 is illustrated with the solder and components arranged on the surface of the substrate 110 omitted.

  The imaging unit 43 is configured to image the substrate 110. The imaging unit 43 is an imaging device such as a CCD camera, for example.

  The drive unit 44 is provided for adjusting the orientation of the imaging unit 43 and adjusting the focus.

  The image processing unit 45 is configured to acquire the image data captured by the imaging unit 43 by reading the image data from the imaging unit 43 at a predetermined timing based on the control signal output from the sub CPU 47. Has been.

  In the present embodiment, the storage unit 46 is configured to store the imaging sequence program 70, the pass / fail determination program 80, and the master data 90 transmitted from the controller 50.

  In the present embodiment, the sub CPU 47 is configured to start inspection of a predetermined area of the substrate 110 based on the reception of one imaging operation trigger signal (inspection start signal) from the main CPU 55. . Specifically, the sub CPU 47 sets the imaging unit under different imaging conditions for each imaging according to the imaging sequence program 70 stored in the storage unit 46 based on the reception of one imaging operation trigger signal. 43 is configured to perform a plurality of imaging operations, and the illumination unit 42 is configured to perform a plurality of illumination operations. That is, the sub CPU 47 changes the imaging (imaging and illumination) conditions to cause the imaging unit 43 to perform a plurality of imaging operations and to cause the illumination unit 42 to perform a plurality of illumination operations. Note that the above different conditions include, for example, a condition in which the illumination unit that irradiates illumination light among the upper illumination unit 421, the middle illumination unit 422, and the lower illumination unit 423 is changed, or a condition in which the imaging time by the imaging unit 43 is changed. Etc.

  Specifically, the sub CPU 47 is configured to cause the imaging unit 43 to perform primary imaging to n-th imaging for a predetermined region of the substrate 110 based on the reception of one imaging operation trigger signal from the main CPU 55. Has been. That is, the sub CPU 47 causes the imaging unit 43 and the illumination unit 42 to sequentially perform primary imaging to n-th imaging in a predetermined region of the substrate 110 based on the reception of one imaging operation trigger signal from the main CPU 55. Then, the sub CPU 47 performs an inspection on a predetermined area of the substrate 110 based on n images acquired from the primary imaging to the n-th imaging. Of images acquired by a plurality of imaging operations and illumination operations, an image acquired by an i-th imaging operation (i is a natural number equal to or less than n) and an illumination operation is referred to as i-th image data. In the present embodiment, “one sequence (one sequence)” refers to a series of imaging operations from the primary imaging to the n-th imaging performed in a predetermined area of the substrate 110 (the illumination operation by the illumination unit 42 and the imaging unit). This is a concept showing an image pickup operation by H.43. Further, n is a natural number that varies depending on the substrate 110 to be inspected.

  The imaging sequence program 70 is programmed to irradiate the illumination unit 42 with illumination light at a predetermined timing in accordance with the imaging timing of the imaging unit 43. Specifically, when the sub CPU 47 causes the imaging unit 43 to capture a plurality of (multiple times) images of a predetermined area of the substrate 110, illumination light is emitted in synchronization with the imaging operation of the imaging unit 43. The illumination unit 42 is controlled.

  Note that the number of imaging operations and illumination operations is the number of times for obtaining an image necessary for the inspection of the substrate 110, and differs depending on the substrate 110 to be inspected.

  In addition, the sub CPU 47 is a pass / fail result that is an inspection result for the substrate 110 based on an image of a predetermined area imaged by a plurality of imaging operations of the imaging unit 43 in accordance with a pass / fail determination program 80 stored in the storage unit 46. Is configured to determine.

  In this embodiment, when the sub CPU 47 determines that the inspection result for the substrate 110 is acceptable, the sub CPU 47 does not transmit the image information of the predetermined area of the substrate 110 to the main CPU 55, and the inspection for the substrate 110 is performed. Information indicating that the result is acceptable is configured to be transmitted to the main CPU 55. On the other hand, when the sub CPU 47 determines that the inspection result for the substrate 110 is not acceptable, the sub CPU 47 transmits information indicating that the inspection result for the substrate 110 is not acceptable and image information of the substrate 110 to the main CPU 55. It is configured. The image information (primary image data to n-order image data) of the substrate 110 when it is determined that it does not pass is transmitted to the main CPU 55 and then displayed on the display unit 60. Thereby, it is possible to visually confirm an image of the substrate 110 that is determined not to pass.

  Next, imaging and pass / fail determination processing of the inspection apparatus 100 will be described with reference to FIGS. Of the imaging and pass / fail determination processing, the main CPU 55 performs steps S1 to S4 and step S21. Further, the sub CPU 47 performs the processes of Step S5 to Step S8, Step S10 to Step S12, Step S14 to Step S17, Step S19, and Step S20. Further, the processing of step S9, step S13 and step S18 is performed by both the sub CPU 47 and the main CPU 55.

  First, in step S1, the main CPU 55 reads board data. Specifically, the imaging sequence program 70, the pass / fail determination program 80, and the master data 90 for inspecting the substrate 110 to be inspected are read from the storage unit 53.

  Next, in step S <b> 2, as shown in FIG. 5, the main CPU 55 transmits the imaging sequence program 70, the pass / fail determination program 80 and the master data 90 to the sub CPU 47.

  Next, in step S3, the main CPU 55 moves the inspection head 40 to the inspection start position. That is, the inspection head 40 is moved to a position (inspection position) corresponding to a predetermined area of the substrate 110.

  Next, in step S <b> 4, as shown in FIG. 5, the main CPU 55 transmits a single imaging operation trigger signal to the sub CPU 47.

  In step S5, the sub CPU 47 determines whether or not a single imaging operation trigger signal transmitted from the main CPU 55 in step S4 has been received. The sub CPU 47 repeats this determination until a single imaging operation trigger signal is received. When the sub CPU 47 receives a single imaging operation trigger signal, the process proceeds to step S6.

  Next, in step S6, the sub CPU 47 resets the imaging number i (i = 1).

  Next, in step S7, the sub CPU 47 starts an imaging operation and an illumination operation.

  Next, in step S8, the sub CPU 47 determines whether an imaging operation and an illumination operation are started. When the imaging operation and the illumination operation are started, the process proceeds to step S10 and step S11. On the other hand, when the illumination operation and the imaging operation are not started, the process proceeds to step S9.

  In step S9, the sub CPU 47 and the main CPU 55 execute error processing. Specifically, the sub CPU 47 transmits information that the illumination operation and the imaging operation are not started to the main CPU 55, and the main CPU 55 displays information that the illumination operation and the imaging operation are not started on the display unit 60. Thereafter, the sub CPU 47 ends the imaging and pass / fail determination processing.

  When the process proceeds to step S <b> 10, the sub CPU 47 controls the operation of the illumination unit 42 according to the imaging sequence program 70. Specifically, as shown in FIG. 5, the sub CPU 47 controls the illumination unit 42 based on a predetermined condition (for example, a condition for irradiating only the upper illumination unit 421 with illumination light) according to the imaging sequence program 70. A control signal is transmitted to the illumination unit 42, and the illumination unit 42 is controlled to emit illumination light. Further, the sub CPU 47 performs the process of step S10 in synchronization with the process of the next step S11 according to the imaging sequence program 70. Specifically, as shown in FIG. 5, the sub CPU 47 controls the illumination unit 42 so that the illumination light is irradiated in accordance with the timing when the imaging unit 43 captures an image according to the imaging sequence program 70.

  In step S <b> 11, the sub CPU 47 controls the operation of the imaging unit 43 according to the imaging sequence program 70. Specifically, as shown in FIG. 5, the sub CPU 47 controls the imaging unit 43 based on a predetermined condition (for example, a condition where the imaging time is t) according to the imaging sequence program 70. An image of a predetermined area of the substrate 110 is captured (acquired) by the processes of step S10 and step S11.

  Next, in step S12, the sub CPU 47 determines whether or not i-th image data has been acquired. If i-th image data has been acquired, the process proceeds to step S14. On the other hand, if the i-th image data cannot be acquired, the process proceeds to step S13.

  In step S13, the sub CPU 47 and the main CPU 55 execute error processing. Specifically, the sub CPU 47 transmits information indicating that the i-th image data cannot be acquired to the main CPU 55, and the main CPU 55 displays information indicating that the i-th image data cannot be acquired on the display unit 60. Thereafter, the sub CPU 47 ends the imaging and pass / fail determination processing.

  If the process proceeds to step S14, the imaging number i is set to i + 1.

Next, in step S15, the sub CPU 47 determines whether or not the number of imaging times i has reached n. If the number of imaging i is n, the process proceeds to step S16.
On the other hand, if the imaging count i is not n, the process returns to step S7.

  When the primary imaging to the n-th imaging are performed and the process proceeds to step S16, the sub CPU 47 executes a pass / fail determination process. Specifically, the sub CPU 47 determines pass / fail, which is an inspection result for a predetermined area of the substrate 110, based on the acquired image data from the primary image to the n-th image.

  Next, in step S17, the sub CPU 47 determines whether or not a pass / fail determination result has been acquired. When the pass / fail determination result is acquired, the process proceeds to step S19. On the other hand, if the pass / fail judgment result cannot be acquired, the process proceeds to step S18.

  In step S18, the sub CPU 47 and the main CPU 55 execute error processing. Specifically, the sub CPU 47 transmits information indicating that the pass / fail determination result cannot be acquired to the main CPU 55, and the main CPU 55 displays information indicating that the pass / fail determination result cannot be acquired on the display unit 60. Thereafter, the sub CPU 47 ends the imaging and pass / fail determination processing.

  When the process proceeds to step S 19, the sub CPU 47 transmits a pass / fail determination result to the main CPU 55. Specifically, as shown in FIG. 5, when the sub CPU 47 determines that the inspection result for the substrate 110 is acceptable, information indicating that the inspection result for the substrate 110 is acceptable (pass / fail determination result). ) To the main CPU 55. On the other hand, if the sub CPU 47 determines that the inspection result for the substrate 110 is not acceptable, the sub CPU 47 receives information indicating that the inspection result for the substrate 110 is not acceptable, and image data of the substrate 110 (from the primary image to the n-th image). Are sent to the main CPU 55. One sequence process is performed by the above steps S7 to S19. Thereby, the sub CPU 47 acquires the inspection result based on the images from the primary image data to the n-th image data, and transmits the inspection result to the main CPU 55.

  Next, in step S <b> 20, the sub CPU 47 determines whether or not a pass / fail determination result for all regions of the substrate 110 has been acquired. If the pass / fail determination result for all the regions of the substrate 110 is not acquired, the process proceeds to step S21.

  In step S21, the main CPU 55 moves the inspection head 40 to the next inspection area. Then, it returns to step S4.

  On the other hand, in step S20, when the pass / fail determination results for all the regions of the substrate 110 are acquired, the sub CPU 47 ends the imaging and pass / fail determination processing.

  In the present embodiment, the following effects can be obtained.

  In the present embodiment, as described above, the sub CPU 47 that determines pass / fail as the inspection result of the substrate 110 based on the image of the predetermined area imaged by the imaging unit 43 is provided. As a result, the sub CPU 47 different from the main CPU 55 that controls the operation of the entire inspection apparatus 100 can determine whether or not the substrate 110 is acceptable. As a result, unlike the case where the main CPU 55 determines pass / fail of the substrate 110 in parallel with the operation control of the entire inspection apparatus 100, the time for acquiring the inspection result for the substrate 110 can be shortened. In addition, an imaging unit 43 that captures an image of a predetermined region of the substrate 110 n times based on the reception of one imaging operation trigger signal from the main CPU 55 is provided. Accordingly, when the image of the predetermined area of the substrate 110 is captured n times, the setting for transmitting the imaging operation trigger signal a plurality of times from the main CPU 55 to the imaging unit 43 and performing imaging is performed on the imaging unit 43. Compared to the case where the image capturing operation is performed, it is not necessary to transmit the image capturing operation trigger signal from the main CPU 55 a plurality of times to perform the image capturing operation. Also by this, the time for acquiring the inspection result for the substrate 110 can be shortened.

  Further, in the present embodiment, as described above, the sub CPU 47 receives the imaging operation trigger signal from the main CPU 55 once, and the imaging unit 43 performs n times under different imaging conditions for each imaging. An imaging operation is performed, and it is configured to determine whether or not the inspection result for the substrate 110 is a pass / fail based on an image of a predetermined area captured under different imaging conditions for each imaging. As a result, even when the imaging unit 43 performs imaging of a predetermined area n times under different imaging conditions for each imaging, the main CPU 55 only transmits an imaging operation trigger signal once, and n times under different imaging conditions. Thus, it is possible to capture an image of a predetermined area under different imaging conditions.

  Further, in the present embodiment, as described above, the illumination unit 42 is provided in the inspection head 40, and based on the reception of one imaging operation trigger signal from the main CPU 55, the imaging unit 43 has a predetermined region of the substrate 110. The sub CPU 47 is configured to control the illumination unit 42 so that illumination light is irradiated in synchronization with the imaging operation of the imaging unit 43 when the image is captured n times. Thus, a predetermined area of the substrate 110 is imaged n times by one imaging operation trigger signal, and illumination light can be irradiated so as to be synchronized with the imaging operation of the imaging unit 43.

  In this embodiment, as described above, when it is determined that the inspection result for the substrate 110 is acceptable, information indicating that the inspection result for the substrate 110 is acceptable is transmitted to the main CPU 55, and The sub CPU 47 is configured to transmit information indicating that the inspection result for the substrate 110 is not acceptable and the image information of the substrate 110 to the main CPU 55 when it is determined that the inspection result for the substrate is not acceptable. As a result, only necessary information is transmitted to the main CPU 55 according to the inspection result for the substrate 110, so that the processing load on the main CPU 55 can be suppressed from increasing.

  In the present embodiment, the sub CPU 47 is provided in the inspection head 40 as described above. Thereby, since the wiring used for the sub CPU 47 can be shortened, the wiring can be easily routed.

  In the present embodiment, as described above, a pass / fail determination program 80 for determining pass / fail as an inspection result for the substrate 110 and an imaging sequence program 70 for causing the imaging unit 43 to perform an imaging operation are stored. A storage unit 46 is disposed on the inspection head 40. Thereby, since the wiring used for the memory | storage part 46 can be shortened, wiring can be performed easily.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims for patent, and further includes all modifications within the meaning and scope equivalent to the scope of claims for patent.

  For example, in the above-described embodiment, an example in which the sub CPU (sub control unit) controls the imaging unit and the illumination unit by receiving one imaging operation trigger signal transmitted from the main CPU (main control unit). Although shown, the present invention is not limited to this. In the present invention, the sub-control unit may control only the imaging unit by receiving one imaging operation trigger signal transmitted from the main control unit.

  Moreover, although the sub CPU (sub control unit) received one imaging operation trigger signal from the main CPU (main control unit) in the above embodiment, an example in which an illumination unit that performs a two-dimensional inspection is provided has been described. The present invention is not limited to this. In the present invention, an illumination unit (for example, a projector) that performs three-dimensional inspection may be provided because the sub-control unit receives one imaging operation trigger signal from the main control unit. In addition, since the sub-control unit receives one imaging operation trigger signal from the main control unit, both an illumination unit that performs a two-dimensional inspection and an illumination unit that performs a three-dimensional inspection may be provided.

  In the above embodiment, an example in which the sub CPU (sub control unit) is provided in the inspection head is shown, but the present invention is not limited to this. In the present invention, the sub control unit may be provided in a portion other than the inspection head. In this case, the sub-control unit can be provided in, for example, the X beam or the Y beam.

  Moreover, although the said embodiment showed the example which applies this invention to the inspection apparatus which test | inspects a board | substrate (inspection object) using the illumination light irradiated from the illumination part containing an LED light source, this invention shows this. Not limited to. In the present invention, the present invention may be applied to an inspection apparatus that provides an X-ray source and inspects an inspection object using X-rays.

  In the above embodiment, for convenience of explanation, the processing of the control unit has been described using a flow-driven flow that performs processing in order along the processing flow. However, for example, the processing operation of the control unit is performed on an event basis. You may perform by the event drive type (event driven type) process which performs a process. In this case, it may be performed by a complete event drive type or a combination of event drive and flow drive.

40 Inspection Head 42 Illumination Unit 43 Imaging Unit 46 Storage Unit 47 Sub CPU (Sub Control Unit)
55 Main CPU (Main Control Unit)
70 Imaging sequence program (imaging operation program)
80 Pass / fail judgment program 100 Inspection device 110 Substrate

Claims (4)

A main control unit for controlling the operation of the entire inspection apparatus;
An inspection head that is movable above the substrate and has an imaging unit that images the substrate ;
Based on receiving one imaging operation trigger signal from the main control unit, the imaging unit is caused to capture images of the predetermined region of the substrate a plurality of times at different timings, and the predetermined region captured by the imaging unit A sub-control unit that determines pass / fail, which is an inspection result for the substrate , based on an image;
The sub-control unit is provided in the inspection head so as to be movable together with the inspection head. Based on the reception of one imaging operation trigger signal from the main control unit, the sub-control unit performs imaging on the imaging unit of the inspection head . The imaging operation is performed a plurality of times under different imaging conditions for each time, and pass / fail is determined as an inspection result for the substrate based on an image of a predetermined area of the substrate that is imaged under different imaging conditions for each imaging time. An inspection device configured to be. The inspection head includes an illumination unit,
The sub control unit picks up an image of the image pickup unit when the image pickup unit picks up an image of a predetermined area of the substrate a plurality of times based on the reception of the single image pickup operation trigger signal from the main control unit. The inspection apparatus according to claim 1, wherein the inspection unit is configured to control the illumination unit so that illumination light is irradiated in synchronization with an operation. When the sub-control unit determines that the inspection result for the substrate is acceptable, the sub-control unit transmits information indicating that the inspection result for the substrate is acceptable to the main control unit, and the inspection result for the substrate The inspection according to claim 1, wherein when it is determined that the inspection result is not acceptable, information indicating that the inspection result for the substrate is not acceptable and image information of the substrate are transmitted to the main control unit. apparatus. A storage unit for storing a pass / fail determination program for determining pass / fail as an inspection result for the substrate and an imaging operation program for causing the imaging unit to perform an imaging operation;
The inspection apparatus according to claim 1 , wherein the storage unit is disposed in the vicinity of the inspection head or the inspection head.

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