JP7404141B2 - Inspection lighting system and control device - Google Patents

Description

TECHNICAL FIELD The present invention relates to an inspection lighting system that includes a split light-emitting type inspection lighting device, and a control device that controls the inspection lighting device.

In recent years, when inspecting the surface of products (workpieces) in factories, etc., so-called split-emission type inspection lighting devices, which have a ring-shaped light-emitting surface divided into a plurality of individually dimmable light-emitting areas, have become popular. Sometimes used. This split light emitting type inspection lighting device is configured such that each light emitting region emits light independently of each other according to a predetermined light emitting sequence consisting of a plurality of steps. Thereby, for example, surface defects can be extracted with good contrast by sequentially irradiating the workpiece with light from different directions and processing the captured images.

By the way, when using such a split light emitting type inspection lighting device, the adjustment of each light emitting region set for each step is required so that the user can check and adjust the light emitting sequence settings of multiple light emitting regions. A setting screen showing a light emission mode such as a light value may be displayed on the display. For example, Patent Document 1 discloses such a setting screen that displays a list of light emitting modes for all steps of each light emitting region in a matrix form using characters such as numbers. The user looks at the setting screen, checks the light emission sequence of the plurality of light emission areas, and adjusts it.

Japanese Patent Application Publication No. 2018-181589

However, in the above-mentioned system that displays a list of the light emitting modes for each step of each light emitting area using numbers or other characters, as the number of light emitting areas or the number of steps increases, the screen becomes full of numbers. There is a problem in that it is not easy to understand the settings of the light emitting sequence, and it is difficult to adjust them.

The present invention has been made in view of these problems, and provides an inspection lighting system having a plurality of individually dimmable light-emitting regions, in which the settings of the light-emitting sequences of the plurality of light-emitting regions can be easily grasped, and The main objective is to make adjustments easier.

That is, the inspection lighting system according to the present invention includes a plurality of individually dimmable light emitting regions, and each light emitting region is configured to emit light independently of each other according to a predetermined light emitting sequence consisting of a plurality of steps. In the inspection illumination device, the light emitting mode set for each step of each light emitting region is such that the light emitting region is taken as one of the vertical axis and the horizontal axis, and the step is taken as the other of the vertical axis and the horizontal axis. and a display section that displays a list on the screen in a matrix, the display section displaying a bar at each position of the matrix, and depending on the mode of each bar, the step indicated by the position and the mode of light emission in the light emitting area are indicated. Characterized by expressing.

With such a configuration, the light emission mode such as the dimming value for each step of each light emitting area is displayed in a list using bars instead of numbers or other characters, so the number of light emitting areas and the number of steps can be displayed in a list. Even if the number increases, the screen will not be filled with characters, and the user can visually grasp the image of the light emitting state for each step of each light emitting region by the form of the bar. This makes it easier for the user to understand the lighting sequence settings for multiple lighting areas and make adjustments easier than when lighting modes such as dimming values are expressed in text. Become.

In the inspection lighting system, the display section expresses the dimming value of the light emitting area by the color of the bar as the light emission mode, expresses the light emission time of the light emitting area by the length of the bar, and It is preferable that the light emission delay time of the light emitting region is expressed by the position of the end of the light emitting region.
In this way, the user can visually grasp the dimming value, light emission time, and light emission delay time for each step of each light emitting area, making it easier to set the light emission sequence of multiple light emitting areas. This will make it easier to understand and make adjustments.

In the inspection lighting system, the display section displays the matrix so that the light emitting area is on the vertical axis and the step is on the horizontal axis, and the bar is arranged so that the length direction thereof is on the matrix. It is preferable to display it so that it coincides with the horizontal axis direction.
In this way, the horizontal axis of the matrix is set as the time axis, and the length direction of the bar is aligned with this time axis direction, so that the light emitting time and light emitting delay time for each step of each light emitting region can be grasped more visually. It's easy to do.

In the inspection lighting system, when one or more of the plurality of bars is selected by a user's selection operation, the display unit displays a setting value of a light emission mode indicated by the selected bar together with the matrix. It is preferable to do so.
With such a device, the user can grasp the setting value of the light emitting mode for each step of each light emitting region, and thus can more easily adjust the setting of the light emitting sequence of each light emitting region.

It is preferable that the inspection lighting system is configured to change the setting value of the light emission mode when it receives a predetermined input operation from a user while the setting value of the light emission mode is displayed together with the matrix.
In this way, the user can change the setting value of the light emitting mode for each step of each light emitting region while imagining the light emitting sequence of the entire light emitting region, making it easier to adjust the light emitting sequence settings of each light emitting region. can.

The inspection lighting system changes the step indicated by the operated bar position and the light emitting time in the light emitting region when the position of the longitudinal end of the bar is moved by the user's drag operation. It is preferable that the configuration is as follows. Preferably, when the position of the bar is moved by the user's drag operation, the step indicated by the operated bar position and the light emission delay time in the light emitting region are changed.
In this way, there is no need to enter numerical values when changing the settings for the light emitting time and light emitting delay time, and these settings can be changed extremely easily by simply performing intuitive operations. . Furthermore, since the bar displayed on the screen is changed by directly operating the bar, it is easy to imagine the changed light emitting time and light emitting delay time, and it is possible to more easily adjust the light emitting sequence settings of each light emitting region.

The inspection illumination system also includes a plurality of the inspection illumination devices, and the display unit arranges the matrix indicating the light emission mode for each step of the light emitting region included in each of the inspection illumination devices on one screen. It is desirable to display it.
In this way, it is possible to understand and adjust the light emission sequence settings of a plurality of inspection lighting devices on one screen.

Further, the control device of the present invention includes a plurality of individually dimmable light emitting regions, and each light emitting region is configured to emit light independently of each other according to a predetermined light emitting sequence consisting of a plurality of steps. The device controls the light emitting mode of each step of each light emitting region, with the light emitting region being taken as one of the vertical axis and the horizontal axis, and the step being taken as the other of the vertical axis and the horizontal axis. The display unit includes a display unit that displays a list on a screen in a matrix, and the display unit displays a bar at each position of the matrix, and the mode of each bar represents the step indicated by the position and the light emission mode in the light emitting area. It is characterized by
Such a control device can provide the same effects as the inspection lighting system of the present invention.

According to the present invention configured in this way, in an inspection lighting system having a plurality of individually dimmable light-emitting regions, it is possible to easily understand the setting of the light-emitting sequence of the plurality of light-emitting regions, and to easily adjust the setting. be able to.

FIG. 1 is a schematic diagram showing the overall configuration of an inspection lighting system according to the present embodiment. FIG. 2 is a perspective view schematically showing the configuration of the inspection lighting device of the same embodiment. FIG. 3 is a functional block diagram of the inspection lighting system according to the embodiment. FIG. 3 is a schematic diagram showing a light emission sequence setting screen of the same embodiment. FIG. 7 is a schematic diagram showing a light emission sequence setting screen of another embodiment.

An embodiment of an inspection lighting system 100 according to the present invention will be described below with reference to the drawings.

The inspection lighting system 100 of this embodiment is used for surface inspection of a workpiece W such as a product in a factory or the like. Specifically, as shown in FIG. 1, this inspection illumination system 100 includes an inspection illumination device 1 that is provided between a workpiece W and an imaging device C and irradiates inspection light onto the workpiece W; A control device 2 that controls the light emission mode of the lighting device 1 is provided. As shown in FIG. 2, this inspection lighting device 1 is of a so-called split light emitting type in which its light emitting surface 12 is divided into a plurality of light emitting regions 121 that can be individually dimmed. The light emitting regions 121 are configured to emit light independently of each other according to a predetermined light emitting sequence consisting of a plurality of steps based on the control signal. The setting of the light emitting sequence of each light emitting region 121 is displayed on the light emitting sequence setting screen 3 of the display D connected to the control device 2, so that the user can confirm it. Each part will be explained below.

As shown in FIGS. 1 and 2, the inspection lighting device 1 includes a casing 11 that is ring-shaped and has an inner circumferential surface 111 that is inclined toward the central axis 11a; It is provided with a ring-shaped light emitting surface 12 formed on an inner circumferential surface 111. A plurality of light sources 13 (specifically, light emitting diodes) are held so as to be uniformly arranged on the inner peripheral surface 111 of the casing 11, and a light emitting surface 12 is formed by the plurality of light sources 13. Note that this light emitting surface 12 may be constituted by a light diffusing plate or the like provided in the light emission direction of the plurality of light sources 13, or may be constituted by the plurality of light sources 13 themselves held in the casing 11 so as to be exposed. good.

In this embodiment, the light emitting surface 12 is divided into 12 light emitting areas 121 that can be individually dimmed. The plurality of light emitting regions 121 have the same shape and are formed at regular intervals around the central axis 11a of the inner circumferential surface 111 of the casing 11. That is, the plurality of light emitting regions 121 are formed so as to be axially symmetrical with respect to the central axis 11a of the inner circumferential surface 111 of the casing 11 as an axis of symmetry. Each light emitting region 121 is formed by a plurality of light sources 13, and the plurality of light sources 13 are configured to be controlled for each unit forming each light emitting region 121 based on a control signal transmitted from the control device 2. ing.

The control device 2 is for dimming and controlling the plurality of light emitting regions 121 included in the inspection lighting device 1. Specifically, the control device 2 is a so-called computer equipped with a CPU, memory, etc., and the CPU and its peripheral devices cooperate according to a predetermined program stored in the memory to set the light emission sequence as shown in FIG. 21, the light emission control section 22, and the display section 23. Each functional unit will be explained below.

The light emitting sequence setting unit 21 stores settings of light emitting sequences for each light emitting region 121 included in the inspection lighting device 1. This light emission sequence is composed of a plurality of steps (here, 10 steps), and in each step, the light emission mode for each light emission region 121 is individually set. The light emission mode includes, for example, a dimming value of the light emitting region 121, a light emission time, a light emission delay time, and the like.

The light emitting sequence setting section 21 also functions as a setting changing section that changes the stored setting of the light emitting sequence of each light emitting region 121. Specifically, the light emission sequence setting unit 21 receives an input operation from the user using an input means I such as a mouse, a keyboard, or a touch panel, and sets the light emission value such as the dimming value set for each light emission area 121 in each step. It is configured to change the aspect.

The light emission control unit 22 causes each light emitting region 121 of the inspection lighting device 1 to emit light independently of each other. Specifically, the light emission control section 22 refers to the light emission sequence stored in the light emission sequence setting section 21 and applies power to each light source 13 so that each light emission region 121 independently emits light according to this light emission sequence. configured to supply.

The display section 23 refers to the light emission sequence setting of each light emitting region 121 stored in the light emission sequence setting section 21, and causes the display D to display a light emission sequence setting screen 3 showing this on a single screen. Specifically, as shown in FIG. 4, the display section 23 displays the light emission mode set for each step of each light emitting area 121 in a matrix M with the light emitting area 121 on the vertical axis and the step on the horizontal axis. Display the list on the light emission sequence setting screen 3. In this matrix M, each light emitting region 121 is displayed in order from the beginning along the vertical axis, and each step is displayed in order from the beginning along the horizontal axis. Further, this matrix M is divided into rectangular cells R (squares) for each step of each light emitting region 121, and within each cell R, steps and light emitting regions 121 indicated by the position of the cell R are set. The lighting mode is displayed.

In the inspection illumination system 100 of the present embodiment, the display unit 23 is displayed at each position of the matrix M, as shown in FIG. The bar B is displayed on each side, and the mode of each bar B is configured to express the step indicated by the position and the light emission mode set in the light emitting area 121.

Specifically, the display unit 23 displays one rectangular bar B in each cell R so that the length direction matches the horizontal axis direction of the matrix M. Here, as shown in FIG. 4, the display unit 23 expresses the dimming value of the light emitting area 121 by the color of the bar B (for example, differences in color, shading, brightness, intensity, saturation, etc.) as the light emission mode. However, the length of the bar B represents the light emitting time of the light emitting region 121, and the relative position of the bar B within the cell R represents the light emitting delay time of the light emitting region 121.

As shown in FIG. 4, the display section 23 displays the color of bar B brighter as the setting value of the dimming value becomes larger, and the color of bar B becomes brighter as the setting value of the dimming value becomes smaller. Display colors darker. It is preferable that the display unit 23 displays the color of the bar B so that the color of the bar B is the same as the color of the light emitted from the corresponding light emitting area 121.

Furthermore, to express the light emission time, the display unit 23 displays the length of the bar B (that is, the distance between both ends along the horizontal axis direction) in proportion to the magnitude of the set value of the light emission time. . Specifically, the larger the set value of the light emitting time is, the longer the bar B is displayed, and the smaller the set value of the light emitting time is, the shorter the bar B is displayed.

Furthermore, the display unit 23 expresses the light emission delay time by the relative position within the cell R of the leading end B _b of the bar B in the horizontal axis direction. Specifically, the smaller the set value of the light emitting delay time is, the closer the position of the leading end _Bb of the bar B is to the position of the leading end _Rb of the cell R, and the larger the set value of the light emitting delay time is. The display is made such that the position of the leading end _Bb of the bar B is further away from the position of the leading end _Rb of the cell R. When the set value of the light emission delay time is zero, display is made so that the position of the leading end _Bb of the bar B and the position of the leading end _Rb of the cell R match.

The display unit 23 also displays, when one or more of the bars B in the matrix M is selected by the user's selection operation using a mouse or the like, the step indicated by the position of the selected bar B and the light emitting area 121. The set value of the light emission mode is displayed together with the matrix M in numbers and letters. For example, as shown in FIG. 4, the setting value of the light emitting mode indicated by the selected bar B is displayed as a pop-up P in the vicinity of the bar B or overlaid on the bar B.

Here, the light emission sequence setting unit 21 receives an input operation such as a keyboard operation from the user when the bar B is selected and the set value of the light emission mode is displayed together with the matrix M, and The step indicated by the position B and the setting value of the light emitting mode in the light emitting region 121 are changed.

The light emission sequence setting unit 21 also controls, when the positions of the ends B _b and B _e in the longitudinal direction of the bar B are moved and the length thereof is changed by the user's drag operation, the light emitting sequence setting unit 21 adjusts the length of the bar B subjected to the drag operation. It is configured to change the step indicated by the position and the light emitting time in the light emitting area 121. Furthermore, when the position of the leading end _Bb of the bar B is moved by the user's drag operation, the light emission sequence setting unit 21 sets the step indicated by the dragged bar B and the light emission delay in the light emitting area 121. Configured to change the time.

In addition to the matrix M, the light emission sequence setting screen 3 also displays a plurality of setting input columns in which the user inputs detailed settings of the light emission sequence. Specifically, as shown in FIG. 4, there is a light emission interval input field (text input field) T1 in which the user inputs the length of the time interval of each step, and a light emission mode indicated by the bar B selected by the user's selection operation. A light emission mode input field (text input field) T2 in which the user inputs setting values, an end point input field (text input field) T3 in which the user enters the number of the final step of the light emission sequence, and a preset light emission sequence. (For example, (1) sequential light emission, (2) n sequential light emission, (3) full light emission, etc.) in the light emission sequence selection input field S1 and the inspection lighting device 1 for setting the light emission sequence. A device selection field S2 is displayed. The light emission mode input field (text input field) T2 includes a light control value input field T21 for inputting a light control value, a light emission time input field T22 for inputting a light emission time, and a light emission time input field T22 for inputting a light emission delay time. A light emission delay time input field T23 is displayed.

According to the inspection illumination system 100 of the present embodiment configured in this way, the light emission mode such as the dimming value for each step of each light emitting region 121 is expressed in the form of a bar B instead of numbers or other letters and displayed in a list. Therefore, even if the number of light emitting areas 121 and the number of steps increase, the screen will not be filled with characters. The user can visually grasp the image of the light emission mode of each light emitting area 121 for each step based on the mode of the bar B. This makes it easier for the user to understand the lighting sequence settings for each lighting area and make adjustments easier than when lighting modes such as dimming values are expressed in text. .

<Other embodiments>
Note that the present invention is not limited to the above embodiments.

Although the inspection illumination device 1 of the embodiment is a ring illumination including the ring-shaped light emitting surface 12, the present invention is not limited to this. In other embodiments, any lighting may be used, such as flat lighting or dome lighting. Further, each light emitting area 121 does not need to be formed in the same casing 11, and may be formed in different casings 11. Moreover, the inspection lighting device 1 of other embodiments may not include the casing 11. The present invention can be applied to any lighting system as long as it includes a plurality of individually dimmable light emitting areas 121. Further, the light source 13 is not limited to being held so as to be housed within the casing 11, but may be held so as to be exposed from the casing 11, for example.

In the embodiment described above, the display section 23 displays the light emitting mode set for each step of each light emitting region 121 in a matrix M with the light emitting region 121 on the vertical axis and the step on the horizontal axis. Not limited to. The display unit 23 of another embodiment may display the light emitting mode set for each step of each light emitting region 121 in a matrix M having the light emitting region 121 on the horizontal axis and the step on the vertical axis.

Although the display unit 23 of the embodiment displays on one screen the settings of the light emission sequence for the light emission region 121 included in one inspection lighting device 1, the display unit 23 is not limited to this. The display unit 23 of another embodiment may display the settings of the light emission sequences of the light emission regions 121 included in the plurality of inspection lighting devices 1 on one screen, as shown in FIG. 5 . In this case, the display unit 23 may display a matrix M indicating the light emitting mode for each step of the light emitting region 121 included in each inspection illumination device 1, side by side on one screen.

In the embodiment described above, the functions of the light emission sequence setting section 21, the light emission control section 22, and the display section 23 are configured to be performed by a single control device 2, but the present invention is not limited to this. In other embodiments, these functions may be performed by different control devices 2. Further, the display D may be included in the control device 2.

In addition, it goes without saying that the present invention is not limited to the embodiments described above, and that various modifications can be made without departing from the spirit thereof.

100...Inspection lighting system 1...Inspection lighting device 121...Light emitting area 23...Display section M...Matrix B...Bar

Claims (10)

An inspection lighting device comprising a plurality of individually dimmable light emitting regions, each light emitting region being configured to emit light independently of each other according to a predetermined light emitting sequence consisting of a plurality of steps;
The light emitting modes set for each step of each light emitting region are listed on a screen in a matrix with the light emitting region on one of the vertical and horizontal axes and the step on the other of the vertical and horizontal axes. a display section for displaying;
The display section is
Displaying a bar at each position of the matrix, and expressing the step indicated by the position and the light emission mode in the light emitting area according to the mode of each bar ,
As the light emission mode, at least
expressing the dimming value of the light emitting area by the color of the bar;
The length of the bar represents the light emitting time of the light emitting region, or
An inspection lighting system that expresses the light emission delay time of the light emitting region based on the position of the end of the bar . The display section has the light emitting mode,
Expressing the dimming value of the light emitting area by the color of the bar,
The length of the bar represents the light emitting time of the light emitting region, and
The inspection lighting system according to claim 1, wherein the light emission delay time of the light emitting region is expressed by the position of the end of the bar. The display section is
Displaying the matrix so that the light emitting region is on the vertical axis and the step is on the horizontal axis,
The inspection illumination system according to claim 1 or 2, wherein the bar is displayed so that its length direction coincides with the horizontal axis direction of the matrix. When one or more of the plurality of bars is selected by the user's selection operation,
The inspection illumination system according to any one of claims 1 to 3, wherein the display section displays a set value of the light emission mode indicated by the selected bar together with the matrix. 5. The inspection illumination system according to claim 4, wherein when a predetermined input operation from a user is received while the set value of the light emitting mode is displayed together with the matrix, the set value is changed. Claim 2, wherein when the position of the end in the length direction of the bar is moved by a drag operation by a user, the step indicated by the operated position of the bar and the light emission time in the light emitting area are changed. and the inspection lighting system according to any one of claims 3 to 5, which refers to claim 2. Quoting claims 2 and 2, wherein when the position of the bar is moved by a drag operation by a user, the step indicated by the operated bar position and the light emission delay time in the light emitting area are changed. The inspection lighting system according to any one of claims 3 to 6. comprising a plurality of the inspection lighting devices,
The inspection lamp according to any one of claims 1 to 7, wherein the display unit displays the matrix indicating the light emission mode for each step of each of the light emitting regions included in each of the inspection lighting devices, arranged on one screen. lighting system. The inspection illumination according to any one of claims 1 to 8, wherein the inspection illumination device includes a light emitting surface formed from a plurality of light sources, and the light emitting surface is divided into the plurality of light emitting regions. system. Controlling an inspection lighting device comprising a plurality of individually dimmable light emitting regions, each of which is configured to emit light independently of each other according to a predetermined light emitting sequence consisting of a plurality of steps. ,
A display unit that displays a list of light emission modes for each step of each of the light emitting regions on a screen in a matrix in which the light emitting region is taken as one of the vertical axis and the horizontal axis, and the step is taken as the other of the vertical axis and the horizontal axis. Equipped with
The display section is
Displaying a bar at each position of the matrix, and expressing the step indicated by the position and the light emission mode in the light emitting area according to the mode of each bar ,
As the light emission mode, at least
expressing the dimming value of the light emitting area by the color of the bar;
The length of the bar represents the light emitting time of the light emitting region, or
A control device that expresses the light emission delay time of the light emitting region based on the position of the end of the bar .