JP6270409B2 - Photoelectric sensor - Google Patents

Description

  The present invention relates to a photoelectric sensor provided with display means.

  The photoelectric sensor is a first type that detects the presence / absence of a detection body (hereinafter referred to as “work”) based on the amount of received light, and a second type that detects the presence / absence of a work mainly based on the distance to the work. There is. This second type of photoelectric sensor is called a “distance setting type photoelectric sensor”. Patent Documents 1 and 2 disclose the first type. Patent Document 3 discloses the second type.

  Depending on the shape of the photoelectric sensor, it can be roughly classified into a box type (Patent Document 2) and a slim type (Patent Documents 1 and 3). FIG. 35 shows a photoelectric sensor disclosed in Patent Document 2 as a typical example of a box-type photoelectric sensor. FIG. 36 shows a photoelectric sensor disclosed in Patent Document 3 as a typical example of the slim photoelectric sensor.

  Referring to FIG. 35 that discloses a box-type photoelectric sensor, reference numeral 1 indicates a head unit, reference numeral 2 indicates a main unit, and the main unit 2 corresponds to a box-type photoelectric sensor. The main unit 2 includes an amplifier. The head unit 1 is connected to the main unit 2 via cables 3a and 3b.

  The sensor head unit 1 emits laser light and receives reflected light that has been reflected by the workpiece W. The main unit 2 detects the presence / absence of a workpiece by comparing the amount of received light (current value) received by the sensor head unit 1 with a preset threshold value.

  The main unit 2 has an upper surface 2a that is rectangular in plan view, that is, an operation surface, and a first display portion 4 and a second display portion 5 that extend in the lateral direction are arranged in the central region of the upper surface 2a. . The 1st, 2nd display parts 4 and 5 are comprised by 7 segment LED. As can be understood from FIG. 35, a relatively large number is displayed on the first display unit 4 positioned relatively upward, while a small number is displayed on the second display unit 5 positioned below.

  On the upper surface 2 a of the main unit 2, a bar display unit 6 is provided with a plurality of indicator lamps (LEDs) arranged side by side in the upper left portion, and a laser emission indicator is provided below the bar display unit 6. 7 is disposed.

  On the upper surface 2 a of the main unit 2, hold mode indicators 8 a and 8 b are disposed on the left of the second display unit 5. On the upper surface 2a of the main unit 2, a mode switch 9 and a setting switch 10 are further arranged on the right side of the first and second display portions 4 and 5, and an up switch arranged side by side on the lower side. An adjustment switch 11 including 11u and a down switch 11d is provided. The output of the main unit 2 is performed through a cable indicated by reference numeral 12.

  36 which discloses a slim photoelectric sensor, reference numeral 20 indicates a head unit, and reference numeral 21 indicates a main unit. The main unit 21 corresponds to a distance setting type photoelectric sensor. The head unit 20 includes a light projecting element constituted by a laser diode and a light receiving element having a light receiving surface constituted by a two-divided PD (photodiode), and one divided light receiving surface receives N side (Near side) light. The other divided light receiving surface constitutes the F side (Far side) light receiving surface. The difference between the amount of light received by the N-side light receiving surface and the amount of light received by the F-side light receiving surface is supplied from the head unit 20 to the main unit 21 through the first cable 22. A drive control signal for the light emitting element is supplied from the main unit 21 to the head unit 20 through the second cable 23 that connects the head unit 20 and the main unit 21.

  The main unit 21 calculates the detection distance of the workpiece W based on the difference between the amount of light received by the N-side light receiving surface and the amount of light received by the F-side light receiving surface received from the head unit 20 (difference in received light amount).

  On the elongated upper surface 21a of the main unit 21, that is, the operation surface, an elongated display portion 24 is disposed at the center in the longitudinal direction. The display unit 24 is composed of an 8-digit 7-segment LED. An indicator 25 for displaying a comparison result between the detection distance and the reference distance is disposed at one longitudinal end of the elongated upper surface 21a. One button switch 26 is disposed adjacent to one end of the display unit 24 in the longitudinal direction, a swing switch 27 is disposed adjacent to the other end of the display unit 24, and the other end of the main unit 21. The other button switch 28 is arranged. Using these switches 26 to 27, the display mode of the display unit 24 can be switched and various settings or setting values can be adjusted. In FIG. 36, reference numeral 29 indicates an output cable, and reference numeral 30 indicates a lid.

  Patent Document 1 relates to a slim photoelectric sensor, and the items displayed on the first and second display units when the first and second display units are configured by dividing an 8-digit 7-segment LED into two parts, and The display transition is described in detail. For example, an example in which “current value (light reception amount)” is numerically displayed on the first display unit and “threshold value” is numerically displayed on the second display unit is disclosed.

JP JP 2005-210720 A (Patent No. 4023621) USP 6,555,806 JP JP 2007-33097 A

  As can be easily understood from the detailed description of Patent Documents 1 to 3 and FIGS. 35 and 36, the photoelectric sensor has an upper surface 2a having a limited area in both a box type (FIG. 35) and a slim type (FIG. 36). (FIG. 35) and 21a (FIG. 36) are provided with an indicator, a display unit (7-segment LED), and various switches.

  By the way, photoelectric sensors are becoming more multifunctional and further miniaturized. The number of button switches cannot be increased as this multi-function and miniaturization progresses. Of course, the improvement which deteriorates a user's operativity is not permitted. From the viewpoint of user operability, as shown in Patent Documents 1 to 3, numerical functions are assigned to each of a limited number of button switches and displayed on a display unit using a 7-segment LED. Various efforts have been made such as displaying a character that can be displayed with a 7-segment LED so that the meaning of each numerical value can be visually understood. A typical example is that the 8-digit 7-segment LED disclosed in Patent Document 1 is divided into two to display different types of items (information) at the same time, and by operating a limited number of switches. The items (information) to be displayed in the section are changed, the displayed set values are adjusted, and the like.

  However, when a plurality of functions are assigned to one button switch, the user needs to store a specific button switch to be operated for each display screen.

  An object of the present invention is to provide a photoelectric sensor capable of increasing the degree of freedom of display on the display unit mounted on the photoelectric sensor and contributing to the improvement of user switch operability. is there.

  In order to achieve the above technical problem, a first feature of the photoelectric sensor of the present invention is that a dot matrix type display is adopted as a display unit. A typical example is a liquid crystal display. By adopting a dot matrix type display, the degree of freedom of display can be obtained as compared with 7-segment LED.

  Currently, touch panels are in widespread use. A second feature of the present invention is that a touch switch including the touch panel is provided in the display unit. All of the switches incorporated in the photoelectric sensor may be configured by touch switches, or a part of the switches may be configured by touch switches. By adopting the touch switch, the degree of freedom in designing the upper surface (operation surface) of the photoelectric sensor can be improved. For example, it is possible to further downsize the photoelectric sensor or enlarge the display unit.

  The third feature of the present invention is to display characters and characters that explain the function of the touch switch. The user knows the function of the touch switch from the characters and characters displayed on the display unit. Therefore, the user does not need to memorize the switch to be operated for each display screen and its function. All of the switches included in the photoelectric sensor may be configured by touch switches, or a part of the switches may be configured by mechanical switches. When a mechanical switch is included, it is preferable to display characters and characters that explain the function of the mechanical switch at a position adjacent to the mechanical switch. Conventionally, photoelectric sensors have adopted a short-pressing operation in which the switch is pressed for a short time and a long-pressing operation in which the switch is pressed for a relatively long time (for example, 3 seconds or more). Even in the present invention, a short press operation and a long press operation may be included. The short press and long press may be displayed on the display unit.

  Other objects and effects of the present invention will become apparent from the following detailed description of the present invention.

It is a figure for demonstrating the example of a display applicable to the display of the display part of a photoelectric sensor to the example of the rectangular display part of a box-type photoelectric sensor. It is a figure for demonstrating the other display example applicable to the display of the display part of a photoelectric sensor for the example of the rectangular display part of a box-type photoelectric sensor. It is a figure for demonstrating the example of a display suitable for the display of the rectangular display part of a box-type photoelectric sensor. It is a figure for demonstrating the other example of a display suitable for the display of the rectangular display part of a box-type photoelectric sensor. It is a figure for demonstrating the modification of the example of a display shown in FIG. FIG. 6 is a diagram for explaining a modification of the display example illustrated in FIG. 5. It is a figure for demonstrating the modification of the example of a display shown in FIG. It is a figure for demonstrating the example of arrangement | positioning of the switch which added the function of the touch switch to a part of display part of a box-type photoelectric sensor. It is a figure for demonstrating the other example of arrangement | positioning of the switch which added the function of the touch switch to a part of display part of a box-type photoelectric sensor. It is a figure for demonstrating another example of arrangement | positioning of the switch which added the function of the touch switch to a part of display part of a box-type photoelectric sensor. It is a figure for demonstrating another example of arrangement | positioning of the switch which added the function of the touch switch to a part of display part of a box-type photoelectric sensor. It is a figure for demonstrating the example of a display suitable for the display of the display part of a slim type photoelectric sensor. It is a figure for demonstrating the other example of a display suitable for the display of the display part of a slim type photoelectric sensor. It is a figure for demonstrating another example of a display suitable for the display of the display part of a slim type photoelectric sensor. It is a figure for demonstrating the modification of the example of a display shown in FIG. It is a figure for demonstrating the modification of the display example shown in FIG. It is a figure for demonstrating the example of arrangement | positioning of the switch which added the function of the touch switch to a part of elongate display part of a slim type photoelectric sensor. It is a figure for demonstrating another example of arrangement | positioning of the switch which added the function of the touch switch to a part of elongate display part of a slim type photoelectric sensor. It is the figure which looked at the operation surface (upper surface) of the box-shaped distance setting type photoelectric sensor of an Example from the top. It is a figure for demonstrating the aspect of eight input / outputs which can be set by the connection of the input / output line of the photoelectric sensor of an Example. It is a figure for demonstrating button operation required for the transition and setting of the initial setting screen of the photoelectric sensor of an Example. It is a figure for demonstrating the setting of an analog upper limit and / or an analog lower limit. It is a figure for demonstrating the operation | movement of DATUM mode contained in a detection mode, and a threshold value setting method. It is a figure for demonstrating operation | movement of the distance mode contained in detection mode, and a threshold value setting method (two-point tuning). It is a figure for demonstrating the other threshold value setting method (full auto tuning) in distance mode. It is a figure for demonstrating another threshold value setting method (1 point tuning) in distance mode. It is a figure for demonstrating operation | movement of the window mode contained in detection mode, and a threshold value setting method (two-point tuning). It is a figure for demonstrating the other threshold value setting method (one point tuning) in window mode. It is a figure for demonstrating the setting method of the display part of the display part in operation | use (RUN) mode, and the screen structure in each display aspect. It is a figure for demonstrating the operation of the manual tuning which enables adjustment and resetting of a threshold value directly while the photoelectric sensor of an Example is operate | moving in operation (RUN) mode. It is a figure for demonstrating the example of arrangement | positioning of the touch switch of the display part of a photoelectric sensor. It is a figure for demonstrating the example which comprises the switch function required for a photoelectric sensor with the touch switch of a display part. It is a figure for demonstrating the example of arrangement | positioning of the touch switch of the photoelectric sensor provided with three switches. It is a figure for demonstrating the other example of arrangement | positioning of the touch switch of the photoelectric sensor provided with three switches. It is a perspective view of the conventional box type photoelectric sensor extracted from patent document 2. It is a perspective view of the conventional slim type photoelectric sensor extracted from patent document 3.

  Before describing preferred embodiments of the present invention based on the attached drawings, the conceptual configuration of the present invention will be described below. The present invention has a first feature in that a dot matrix type display is adopted as the display portion of the photoelectric sensor. A typical example of a dot matrix type display is a liquid crystal display (LCD), but an organic EL display may also be used. Of course, a black and white display may be used, but a color display is typically employed.

Box type display examples (FIGS. 1 to 7) :
Reference numeral 100 in FIGS. 1 to 7 indicates a rectangular display unit that can be suitably used for the box-type photoelectric sensor described with reference to FIG. 35. The rectangular display unit 100 is a dot matrix type display (specifically, In particular, it is composed of a liquid crystal display.

  In the display example of FIG. 1, numerical values or characters are displayed in the main region 102 occupying most of the area of the display unit 100. According to this display example, for example, a numerical value of 4 to 6 digits can be displayed side by side and large. A typical example of this display is a current value (distance and received light amount) during operation (RUN) of the photoelectric sensor. Of course, when the numerical information is displayed in the main area 102 as a large number, a character such as character information indicating the meaning of the numerical value or a state related to the numerical value may be displayed on the left or right. Good.

  In addition, when displaying character information in the main area 102, a large number of characters can be displayed. When character information is displayed in the main area 102, for example, the current value or the set value is preferably displayed as a small number at a side position of the main area 102.

  In the display example of FIG. 2, the main region 104 occupying most of the area with the left side facing the display unit 100 does not interfere with one side of the main region 104, for example, adjacent to the left side and the main region 104. An example in which the sub-region 106 is arranged at the position is shown. As shown in the figure, the sub-region 106 may be divided into two sub-regions 106A and 106B so as not to interfere with each other vertically.

  In the display example of FIG. 2, typically, the main numerical information that the user needs most is displayed large in the main area 104, and the sub numerical information that the user wants to reference is displayed relatively small in the sub area 106. Is done. A typical example of this display is a display mode when the set value (threshold value) of the photoelectric sensor is changed. While displaying the current value (distance or received light amount) that changes every moment in the main area 104, the threshold value may be displayed in the first or second sub-area 106A, 106B. When there are two threshold values, the first threshold value may be displayed in the first sub area 106A and the second threshold value may be displayed in the second sub area 106B.

  In addition, the display example of FIG. 2 is suitable for displaying error and warning, communication status with the host device side, and the like as character information. While displaying the character information in the main area 104, numerical information, current value, and threshold value related to the character information can be displayed using the sub area 106.

  Of course, the character information may be displayed in one of the first and second sub-regions 106A and 106B, and the numerical information may be displayed in the other region. Further, when displaying numerical information in the main area 104 and the first and / or second sub-areas 106A and 106B, a character meaning the meaning of this numerical value may be displayed on the left or right.

  In the display example of FIG. 3, the display unit 100 is divided into upper and lower parts, and the first and second areas 108A and 108B are arranged. The first and second areas 108A and 108B have different numerical information of the same size. May be displayed. In addition, an area for displaying characters such as letters and symbols may be added to the left empty space of the first and second areas 108A and 108B. Of course, you may make it display the character which means the meaning of this numerical value on the left or the right of the numerical information displayed on the 1st, 2nd area | region 108A, 108B.

  The display example of FIG. 4 is divided into a main area 110 occupying most of the display unit 100 and a sub-area 112 positioned below the main area 110, and main numerical information most needed by the user is displayed in a large number in the main area 110. However, it is convenient to display sub-information (numerical values or characters) that the user wants to refer to in the sub-region 112 with relatively small numbers. In addition, an area for displaying characters such as letters and codes may be added to the space left on the left side of the main area 110 and the sub area 112. Further, as indicated by an arrow in FIG. 4, the sub region 112 may be disposed on the upper side and the main region 110 may be disposed on the lower side.

  The display example of FIG. 5 is also a modification of the display example of FIG. The sub regions 112 described with reference to FIG. 4 may be divided into first and second sub regions 112A and 112B in a side-by-side arrangement that does not interfere with each other. In addition, an area for displaying a character such as a character may be added to an empty space on the left side of the main area 110. Further, as indicated by arrows in FIG. 5, the first and second sub-regions 112A and 112B may be arranged on the upper side, and the main region 110 may be arranged on the lower side.

  The display example of FIG. 6 is also a modification of the display example of FIG. As can be seen from FIG. 6, the first and second sub-regions 112A and 112B may be arranged vertically, and the first and second sub-regions 112A and 112B are arranged offset to the left and right. Also good. Of course, different numerical information may be displayed in each of the first and second sub-regions 112A and 112B, but numerical information is displayed in one of the first and second sub-regions 112A and 112B, and the other Character information may be displayed on the screen. In addition, an area for displaying a character such as a character may be added to an empty space on the left side of the main area 110 and the first and second sub areas 112A and 112B. Further, as indicated by an arrow in FIG. 6, at least one of the first and second sub-regions 112A and 112B may be disposed on the main region 110, and the main region 110 may be disposed below the main region 110.

  The display example of FIG. 7 is also a modification of the display example of FIG. As can be seen from FIG. 7, in this display example, the first and second sub-regions 112A and 112B are arranged vertically, and the first and second sub-regions 112A and 112B are aligned vertically. An example of display is shown. Also in the display example of FIG. 7, an area for displaying characters such as characters may be added to the empty space on the left side of the main area 110. In addition, an area for displaying characters such as characters may be added to the empty space on the left side of the first and second sub-areas 112A and 112B. Further, as indicated by an arrow in FIG. 7, at least one of the first and second sub-regions 112A and 112B may be disposed on the main region 110, and the main region 110 may be disposed below the main region 110.

  Also in the display examples of FIGS. 4 to 7, characters such as characters or symbols indicating the meaning of the numerical values may be displayed on the left or right of the numerical information displayed in the main area 110 and the sub area 112. Needless to say.

  Referring to FIG. 7 again, the display example shown in FIG. 7 proposes that the rectangular display unit 100 displays information in three upper and lower stages. In the uppermost main display area 110, the current value is typically displayed. A set value (threshold value) is typically displayed in the middle first sub-region 112A. These current values and threshold values have four digits in this example. When the set value number is displayed smaller than the current value number, a blank appears below the middle row. Using this blank, the second set value may be displayed in the lower second sub-region 112B described above. When the second sub area 112B is set from one end to the other end in the width direction of the display unit 100, character information may be displayed using the second sub area 112B. Of course, when the number of characters constituting the character information (the number of terms) is large, a character size suitable for the second sub-region 112B may be selected. When the number of characters (the number of terms) is large, the character size becomes small. However, if the character size is such that the user can read without looking away, the user can immediately recognize the character string.

  Of course, the character information displayed in the second sub-region 112B varies depending on the display screen. For example, a large-size character may be used for a display such as a warning display for prompting the user's attention. However, the character size of the character information displayed in the second sub-region 112B is unified except in such a special case. It is good to do.

  The display examples described above with reference to FIGS. 1 to 7 may be appropriately used depending on the information displayed on the display unit 100. Conventionally, switching of the display unit 100 and switching of the operation mode of the photoelectric sensor have been performed using various switches, and a display form that is easy for the user to visually recognize as the display is switched and the operation mode is changed. May be adopted as appropriate.

  Conventionally, switching of the operation mode of the photoelectric sensor, transition of display information, adjustment of set values, and the like have been performed using mechanical switches. A typical example is a button (push) type switch, and a swing type switch is also used for adjusting a set value. As the number of switches increases, the area occupied by the display unit 100 must be relatively reduced. In other words, as the number of mechanical switches is smaller, the area occupied by the display unit 100 can be relatively enlarged, or the degree of design freedom for further downsizing the photoelectric sensor can be obtained.

Configuration example of a box-type touch switch (FIGS. 8 to 11) :
Currently, touch panels are in widespread use. This touch panel is a display in which a position input device such as a liquid crystal display and a touch switch is combined, and a pressure-sensitive type and a capacitance type are widely used. The touch panel is also called “touch screen” or “touch screen”.

  Although the entire area of the display unit 100 may be configured by a touch panel, a touch switch may be disposed in a part of the display unit 100 to partially add a touch panel function. 8 to 11 are diagrams for explaining an arrangement example of the touch switch 130. FIG. 8 shows an example in which the first touch switch 130A is arranged on the left side of the display unit 100, and the function of the first switch 120A is assigned to the first touch switch 130A. FIG. 8 shows an example in which the second and third button type (mechanical) switches 120B and 120C are arranged side by side under the display unit 100. The second and third switches 120B and 120C may be arranged vertically on the right side of the display unit 100.

  FIG. 9 shows an example in which the first, second, and third touch switches 130A, 130B, and 130C are arranged. The function of the button-type second switch 120B is assigned to the second touch switch 130B, and the function of the button-type third switch 120C is assigned to the third touch switch 130C. In the example disclosed in FIG. 9, the first touch switch 130 </ b> A is disposed on the left side of the display unit 100, and the second and third touch switches 130 </ b> B and 130 </ b> C are disposed side by side on the lower end of the display unit 100. Show. As a modification of the arrangement example illustrated in FIG. 9, the second and third touch switches 130 </ b> B and 130 </ b> C may be arranged vertically on the right side of the display unit 100. In addition, the first touch switch 130 </ b> A may be disposed at the lower end of the display unit 100.

  FIG. 10 shows an example in which the first switch 120A is arranged below the display unit 100, and the second and third touch switches 130B and 130C are arranged vertically on the right side of the rectangular display unit 100. As a modification of the arrangement example of FIG. 10, the second and third touch switches 130 </ b> B and 130 </ b> C may be arranged side by side at the lower end of the display unit 100.

  FIG. 11 shows an example in which the first touch switch 130A is arranged on the left side of the lower end of the display unit 100, and the second and third touch switches 130B and 130C are arranged vertically on the right side of the display unit 100. The first touch switch 130 </ b> A may be disposed on the upper end portion of the display unit 100.

  The button-type first switch 120A and the first touch switch 130A are equivalent, and for example, a function of switching the display by a long press of 3 seconds or more or a short press of 1 second or less is given. Further, the button-type second switch 120B and the second touch switch 130B are equivalent. For example, the selectable items displayed on the display unit 100 are moved up one by one or displayed on the display unit 100. An up function for increasing a numerical value (typically a set value) is added. The button-type third switch 120C and the third touch switch 130C are equivalent. For example, the selectable items displayed on the display unit 100 are moved down one by one, or the numerical values ( A down function is typically provided for reducing the set value).

  By adding a touch panel function to at least a part of the display unit 100, installation of a mechanical switch can be omitted, and accordingly, the degree of freedom of enlarging the display unit 100 can be obtained.

Slim type display examples (FIGS. 12 to 16) :
A reference numeral 200 in FIGS. 12 to 16 indicates an elongated display unit that can be suitably used in a slim photoelectric sensor. The elongated display unit 200 is configured by a dot matrix type display (specifically, a liquid crystal display).

  In the display example of FIG. 12, numerical values or characters are displayed in the main region 202 occupying most of the area of the elongated display unit 200. According to this display example, for example, a numerical value of 4 to 8 digits can be displayed side by side and large. A typical example of this display is a current value (distance and received light amount) during operation (RUN) of the photoelectric sensor. Of course, you may make it display the character which means the meaning of this numerical value, the state relevant to this numerical value, etc. on the left or right of a numerical value. In addition, when displaying character information in the main area 202, a large number of characters can be displayed. When displaying character information in the main area 202, for example, a sub-area 204 for displaying a current value or a set value with a relatively small number may be arranged beside the main area 202 (FIG. 13).

  The display example shown in FIG. 14 shows an example in which a main region 206 occupying the central portion of the elongated display unit 200 and a sub-region 208 are arranged adjacent to the right side of the main region 206. As shown in the figure, the sub-region 208 may be divided into a first and a second sub-region 208A, 208B vertically. In the display example of FIG. 14, typically, the main numerical information that the user needs most is displayed large in the main area 206, and the sub numerical information that the user wants to reference is relatively small in the sub area 208. Is displayed. A typical example of this display is a display mode when the set value (threshold value) of the photoelectric sensor is changed. While displaying the current value (distance or received light amount) that changes every moment in the main area 206, the threshold value may be displayed in the first or second sub-area 208A, 208B. When there are two threshold values, the first threshold value may be displayed in the first sub-region 208A and the second threshold value may be displayed in the second sub-region 208B.

  FIG. 15 is a modification of the display example shown in FIG. In the display example shown in FIG. 15, a main area 206 is arranged on the right side of the elongated display unit 200, and a sub area 208 is arranged on the left side of the main area 206.

  FIG. 16 is a modification of the display example shown in FIG. In the display example shown in FIG. 13, when displaying character information in the main area 202, a sub area 204 for displaying numerical values with relatively small numbers is arranged on the left of the main area 202. You may arrange | position to the right of the area | region 202 (FIG. 16). Further, in FIG. 16, numerical values are displayed with relatively large numbers in the sub-region 204. This can also be applied to the sub-region 204 shown in FIG. Of course, numerical values may be displayed in the sub-region 204 with relatively small numbers.

Configuration example of slim type touch switch (FIGS. 17 and 18) :
FIG. 17 shows an example in which a touch switch is arranged on a part of the elongated display unit 200 to partially add a touch panel function. Of course, you may comprise the whole area | region of the elongate display part 200 with a touchscreen. FIG. 17 shows an example in which the first touch switch 130A is arranged at the left end portion of the display unit 200, and the function of the first switch 120A is assigned to the first touch switch 130A. In the example of FIG. 17, a mechanical swing switch 120 </ b> B & C is preferably disposed adjacent to the right end of the display unit 200.

  FIG. 18 shows an example in which the second touch switch 130B is arranged at the left end of the display unit 200 and the third touch switch 130C is arranged at the right end. In the example of FIG. 18, the first switch 120 </ b> A may be disposed adjacent to the left end of the display unit 200.

Example (FIG. 19 etc.) :
FIG. 19 is a plan view of the photoelectric sensor 300 of the embodiment. This photoelectric sensor 300 is a distance setting type photoelectric sensor and is a box type. Patent Document 3 (JP JP-2007-33097 A) described above is a slim type distance setting type photoelectric sensor, but the internal configuration of the photoelectric sensor 300 is substantially the same as Patent Document 3 (JP JP 2007-33097 A). Therefore, the disclosure of Patent Document 3 is incorporated in this specification, and the detailed description thereof is omitted.

  Referring to FIG. 19, the rectangular display unit 100 described with reference to FIGS. 1 to 7 is disposed on the upper surface 300 a of the photoelectric sensor 300, that is, the operation surface. A button type (mechanical) first switch 120 </ b> A is disposed on the left side of the display unit 100. The first switch 120A is referred to as a “SET switch” in this embodiment. Of course, the mechanical first switch 120A may be formed of a touch switch.

  In the lower part of the display unit 100, the second and third touch switches 130B and 130C are arranged side by side. The second touch switch 130B located on the left side is referred to as a “DISP switch” or “up switch”, while the third touch switch 130C located relatively on the right side is referred to as a “MENU switch” or “down switch”.

  With continued reference to FIG. 19, an output indicator lamp 302 is disposed at the left end portion of the upper surface 300 a of the photoelectric sensor 300. Input / output of the photoelectric sensor 300 is performed through the cable 304. Here, the photoelectric sensor 300 according to the embodiment has a function of only displaying the detected distance on the display unit 100 without performing the output operation.

  FIG. 19 shows an example in which up and down characters 122 indicated by triangles are displayed on the up switch 130B and the down switch 130C at the lower end of the display unit 100. The characters 122 of the up symbol 122u and the down symbol 122d use the second and third touch switches 130B and 130C for up / down operations for numerical values and selection such as threshold adjustment and selection of a display menu, which will be described later. It may be displayed on the display unit 100 only on occasion, or a display method that attracts the user's attention such as blinking or changing the display color may be adopted.

  Referring to FIG. 20, the photoelectric sensor 300 according to the embodiment has eight types by changing the connection method of the first and second input / output lines 306 (black lines) and 308 (white lines) included in the input cable 304. One can be set from the input / output modes. Reference numeral 310 in FIG. 20 indicates a power line (brown), and reference numeral 312 indicates a ground line (blue). Reference numeral 314 indicates an input load.

  With continued reference to FIG. 20, (1) “Out1 + Out2” allows the black line 306 to be assigned to output 1 and the white line 308 to be assigned to output 2. (2) In “Input + Out1”, the black line 306 can be assigned to the external input, and the white line 308 can be assigned to the output 1. (3) In “Out1 + Analog”, the black line 306 can be assigned to the output 1 and the white line 308 can be assigned to the analog output. (4) In “Input + Analog”, the black line 306 can be assigned to the external input, and the white line 308 can be assigned to the analog output.

Initial setting (FIGS. 21 and 22) :
After the user obtains the photoelectric sensor 300, a screen for initial setting is displayed on the display unit 100 when the power is turned on for the first time or when initialization is executed. The initial setting will be described with reference to FIG. First, a screen for selecting input / output is displayed on the display unit 100 (S1). An input / output mode corresponding to the input / output wiring described with reference to FIG. 20 is selected in step S1.

  Specifically, when the SET switch 120A is pressed for a short time (pressed down for a short time of 1 second or less), a list of “Out1 + Out2,” “Input + Out1,” “Out1 + Analog,” and “Input + Analog” are displayed on the display unit 100 side by side. The The user can select a corresponding input / output mode by depressing the up switch 130B or the down switch 130C. When a desired input / output mode is selected, the setting is performed by pressing the SET switch 120A for a short time, and the set input / output mode is displayed as characters (for example, “Out1 + Out2”). With this setting, as described with reference to FIG. 20, the assignment to the black line 306 and the white line 308 is executed.

  When the down switch 130C is depressed, the next screen is displayed. In the figure, S2 shows a screen when the input / output mode of “Out1 + Out2” or “Input + Out1” is set. S3 shows a screen when the input / output mode of “Out1 + Analog” and “Input + Analog” is set.

  In the figure, input can be selected on the screen shown in S2. On the other hand, whether the analog input is current or voltage can be set by the screen shown in S3. S4 and S5 subsequent to S3 may be performed in the detailed setting described later, but in this embodiment, they are included in the initial setting.

  The analog lower limit value can be set on the screen of step S4. On the other hand, the analog upper limit value can be set on the screen of step S5. When it is desired to change the numerical value displayed in S4 or S5, the numerical value of the display is changed by pressing the SET switch 120A for a short time (pressing down for 1 second or less) and then pressing the up switch 130B or the down switch 130C. When the desired numerical value is reached, the numerical value is set by depressing the SET switch 120A. FIG. 22 is a diagram for explaining setting of the analog upper limit value and the analog lower limit value. When the initial set value is “0” (lower limit value) for 4 mA and “5000” (upper limit value) for 20 mA, “2000” (lower limit value) for 20 mA and 20 mA for the user's hand. Shows an example in which “4000” (upper limit value) is set.

  When the setting of the upper limit value and the lower limit value is completed, the screen is switched to the next screen of S6 by depressing the down switch 130C. NPN or PNP can be set using the screen of S6.

  When various settings are completed on the setting screens S1 to S6 described above and the down switch 130C is depressed, an end screen of S7 is displayed. In addition, what is necessary is just to push down the up switch 130B to return to the setting screen of S1-S6. When the end screen of S7 is displayed, the operation of the photoelectric sensor 300 is switched to the operation (RUN) mode by pressing the SET switch 120A for a short time.

Detection mode (FIGS. 23 to 28) :
The photoelectric sensor 300 includes “DATUM mode”, “distance mode”, and “window mode” as operation (RUN) modes (detection modes). Selection and setting of the detection mode can be performed in this detailed setting mode by switching the operation of the photoelectric sensor to a detailed setting mode described later.

DATUM mode (FIG. 23) :
This DATUM mode is a detailed setting mode described later, and is set by selecting “Standard” from the detection mode options of the photoelectric sensor 300.
(1) Operation during operation (RUN) :
In the DATUM mode, an arbitrary background, that is, a reference plane is set to “0”, and the height from the reference plane is displayed on the display unit 100. Then, the output is inverted between the near-side first threshold value (A) and the far-side second threshold value (-A) across the reference plane.

  “NO” shown in FIG. 23 means normally open, and when the workpiece is positioned between the first and second threshold values, an OFF signal is output, which is closer than the first threshold value (A). An ON signal is output when the workpiece is positioned farther (Far) than the position (Near) and the second threshold (−A).

  “NC” shown in the figure means normally closed, and when the workpiece is positioned between the first and second threshold values, an ON signal is output, which is closer to the first threshold value (A) (Near ) And the second threshold value (−A), the OFF signal is output when the workpiece is located farther (Far).

(2) Setting :
Referring to FIG. 23, after positioning the reference surface BS, first, the SET switch 120A is first pressed shortly, and then long-pressed so that the first and second threshold values are set across the reference surface BS. Is done. When it is desired to change the value of the distance “A” from the reference plane BS for automatically setting the first and second threshold values (A, −A), it can be performed with detailed settings described later. Also, the value of hysteresis (Hys) can be changed by detailed setting.

  Setting of the DATUM mode is completed when the user simply presses and holds the SET switch 120A. Of course, immediately after the setting is completed, the photoelectric sensor 300 returns to the RUN mode and operates in the DATUM mode.

Distance mode (FIGS. 24-26) :
This distance mode is set by selecting “distance” from the detection mode options of the photoelectric sensor 300 in the detailed setting mode described later.
(1) Operation (RUN) operation (FIG. 24) :
Referring to FIG. 24, in the distance mode, the distance from photoelectric sensor 300 to the workpiece is detected, and the detected distance is displayed on display unit 100. In contrast to the threshold value (A), in the case of normally open (NO), an OFF signal is output when the workpiece is located farther (Far) than the threshold value (A). An ON signal is output when the workpiece is positioned closer to the threshold (A). In the case of normally closed (NC), on the contrary, when the workpiece is located farther (Far) than the threshold (A), an ON signal is output and closer to the threshold (A). An OFF signal is output when the workpiece is positioned at the near position.

(2) Setting :
There are three types of threshold value setting methods in the distance mode: (A) two-point tuning method, (B) full-auto tuning method, and (C) one-point tuning method.

(A) Two-point tuning method :
Referring to FIG. 24, after positioning work W distally (Far), SET switch 120A is short-pressed. Next, after the workpiece W is positioned proximally, the SET switch 120A is short-pressed. As a result, a threshold value is set between the distal (Far) and the proximal (Near).

(B) Full auto tuning method (Fig. 25) :
This full auto-tuning method can be effectively applied when the detection body, that is, the workpiece W cannot be placed, for example, when the workpiece W cannot be placed like the workpiece W conveyed by the conveyor.

  Referring to FIG. 25, first, long-pressing SET switch 120A in a state without workpiece W (reference surface BS). Next, the workpiece W is detected in a state where the SET switch 120A is kept pressed. Thereby, the threshold value A is set between the reference surface BS and the height of the workpiece W.

(C) One-point tuning method (FIG. 26) :
This one-point tuning method can be effectively applied when the detection object, that is, the workpiece W can be placed at the upper limit (distal).

  Referring to FIG. 26, after positioning work W, SET switch 120A is pressed long. As a result, the threshold value (A) is set at a position proximal from the workpiece W by a predetermined distance. This predetermined distance, that is, the margin can be set by detailed setting described later.

Window mode (FIGS. 27 and 28) :
This window mode is set by selecting “Window” from the detection mode options of the photoelectric sensor 300 in the detailed setting mode described later.
(1) Operation during operation (RUN) :
Referring to FIG. 27, the distance from photoelectric sensor 300 is displayed on display unit 100. Then, the output is inverted at the set distal threshold (Far) and proximal threshold (Near).

(2) Setting :
There are two threshold value setting methods in the window mode: (A) two-point tuning method (FIG. 27) and (B) one-point tuning method (FIG. 28).

(A) Two-point tuning method (Fig. 27) :
Referring to FIG. 27, after positioning work W distally (Far), SET switch 120A is short-pressed. Next, after the workpiece W is positioned proximally, the SET switch 120A is short-pressed. Thereby, a distal threshold value (Far) and a proximal threshold value (Near) are set.

(B) One-point tuning method (FIG. 28) :
Referring to FIG. 28, after the workpiece W is positioned distally (Far), the SET switch 120A is long pressed. Accordingly, a distal threshold value (Far) is set, and a proximal threshold value (Near) that is a predetermined distance away from the distal threshold value (Far) is set. When it is desired to change the value of the predetermined distance, it can be performed with detailed settings described later.

Setting of display mode during operation (RUN) (FIG. 29) :
The display mode of the display unit 100 during operation can be set even while the photoelectric sensor 300 is in operation. When the photoelectric sensor 300 is in the operation mode, the display mode change mode can be entered by pressing and holding the up switch 130B.

  Referring to FIG. 29, when the display mode change mode is entered, items included in the selection menu are displayed on display unit 100 as two character strings in the vertical direction. There are four selectable character strings: (1) Standard, (2) Peak Bottom, (3) Bar (4) Simple, each of which clearly shows the outline of the display mode. By pressing the up switch 130B or the down switch 130C for a short time, an intended item can be selected from these items. Next, the selected display mode can be set by short-pressing the SET switch 120A. Thereby, a display mode can be switched by a simple operation during operation (RUN).

  FIG. 29I shows an example in which the “Standard” display mode is set. This display example is a case where there is one threshold value, and when there are two threshold values, the first threshold value and the second threshold value are displayed side by side. As can be seen from (I) of FIG. 29, in the screen configuration in the “Standard” display mode, the current value “4567” is displayed as a large number, and below that, a threshold value, that is, a set value, is displayed as a relatively small number. “2345” is displayed. Of course, the current value and the set value may be displayed in the same color, but may be displayed in different colors.

  FIG. 29 (II) shows an example in which the “Peak Bottom” display mode is set. As can be seen from (II) of FIG. 29, in the screen configuration in the “Peak Bottom” display mode, the current value “4567” is displayed as a large number, and below that, a peak value “2345” is displayed as a relatively small number. And the bottom value “6789” are displayed side by side. The peak value and the bottom value may be displayed in the same color, but may be displayed in different colors. “P” seen on the left side of the peak value “2345” means that the numerical value “2345” is the peak value. “B” seen on the left side of the bottom value “6789” means that the numerical value “6789” is the bottom value.

  FIG. 29 (III) shows an example in which the “Bar” display mode is set. As can be seen from (III) of FIG. 29, in the screen configuration in the “Bar” display mode, the current value “1845” is displayed as a large number, and a bar extending in the horizontal direction is displayed below the current value. This bar means the position where the workpiece W is located between the upper limit value and the lower limit value. Incidentally, in a photoelectric sensor that displays the magnitude of the amount of received light, the margin of the amount of received light can be displayed using this bar.

  FIG. 29 (IV) shows an example in which the “Simple” display mode is set. As can be seen from (IV) of FIG. 29, in the screen configuration in the “Simple” display mode, the current value “1845” is displayed as a large number that occupies most of the display unit 100. In the display examples of (I) to (IV) in FIG. 29, “1” and “2” are displayed in the upper left side of the display unit 100. The “1” and “2” are photoelectrical. This means whether the numerical information displayed on the output channel of the sensor 300, that is, the display unit 100 of the photoelectric sensor 300, is the numerical value related to the first channel (ch.1) or the numerical value related to the second channel (ch.2). . It is preferable to adopt a display method that is easy for the user to recognize, such as brightly displaying the channel number being displayed or blinking.

  As can be seen from the examples of display modes that can be switched during operation (RUN) with reference to (I) to (IV) of FIG. 29, in each display mode, in addition to the current value, the output channel, the set value There are bottom value and peak value. In addition, as will be described later, when there are two hold values, margins, and setting values, the first and second setting values can be included in the operating display mode.

  As described above with reference to FIG. 29, the display mode change mode can be entered by long pressing the up switch 130B during operation (RUN). In this display mode change mode, “Standard”, “Peak Bottom” Since menu guidance based on character information such as “” is displayed on the display unit 100, the user can easily select a display mode desired by the user. Moreover, since the screen of the selected display mode is displayed on the display unit 100 by depressing the SET switch 120A, the confirmation is easy. Further, regarding numerical information other than the current value displayed on the display unit 100, a character that directly indicates the meaning of the numerical value is displayed at a position adjacent to the displayed numerical value. You can immediately recognize the numerical value displayed on the screen. Therefore, in the middle of switching the display mode in the display mode change mode, the numerical value displayed on the display unit 100 one after another is a set value, a hold value, a peak value, or the like. Generation of misunderstanding of meaning can be prevented.

Adjustment and setting of threshold during operation (RUN) (FIG. 30) :
When adjustment of the threshold value, that is, resetting is required while the photoelectric sensor 300 is operating in the operation (RUN) mode, the threshold value can be directly adjusted in this operation mode (manual tuning). (FIG. 30).

(A) When the threshold value is one detection mode :
Referring to FIG. 30A, when the up switch 130B or the down switch 130C is pressed for a short time while operating in the operation (RUN) mode, the display unit 100 displays the current value “4567” with a large number above. Is displayed, and a setting value “2345” is displayed below it. As a modified example, “setting value” may be displayed on the main part of the display unit 100, and “current value” may be displayed at a position that does not interfere with the setting value, for example, on the side or lower part of the display unit 100.

  The set value displayed on the display unit 100 increases when the up switch 130B is pressed. In addition, when the down switch 130C is pressed, the numerical value of the set value decreases. When the numerical value displayed on the display unit 100 changes, the photoelectric sensor 300 operates based on the changed numerical value. When the desired value is reached, the photoelectric sensor 300 is left unattended, and three seconds later, the adjusted value is set, and the photoelectric sensor 300 operates under the newly set threshold value. The display of the photoelectric sensor 300 returns to the operation mode.

  Referring to (A) drawn at the top of FIG. 30, when the photoelectric sensor 300 is operating normally in the operation (RUN) mode, the display unit 100 uses almost the entire area to display the current value. The display form which displays is adopted. In the tuning screen shown below, the current value is displayed above, and the threshold value is displayed below. That is, the screen configuration in the operation mode is different from the screen configuration in multi-tuning, and a display form in which the current value and the threshold are displayed at the same time is adopted on the threshold setting screen. On the threshold value setting screen, the numerical value of the current value and the numerical value of the threshold value may be displayed as numbers having the same size, or the threshold value is displayed in the center of the display unit 100 and does not interfere with this. The current value may be displayed at the position. Furthermore, either one of the display set value and the current value may be displayed as a relatively large number, and the other may be displayed as a small number.

  In the illustrated example, the current value is displayed above and the threshold value is displayed below. Alternatively, the threshold value may be displayed above and the current value displayed below. Good.

  As a further modification, as described above, a threshold value is displayed on the main part of the display unit 100, and a current value is displayed with a relatively small number at a position that does not interfere with the display of the threshold value, for example, the left corner of the display unit 100. For example, the display form described above with reference to FIG. 2 may be adopted.

  Of course, the display color of the current value and the display color of the threshold value may be the same, but the current value and the threshold value may be displayed in different colors. Further, the threshold value may be blinked when the screen of the display unit 100 is switched to the manual tuning display, and the blinking may be terminated when the threshold value is adjusted and the setting is completed. As a modification, the display color of the threshold value may be changed during the adjustment of the threshold value and after the setting is completed. Further, the up / down character 122 (FIG. 19) may be blinked before the threshold setting is completed. Further, when the setting of the threshold value is completed, the display of the up / down character 122 may be lost.

(B) When the detection mode is “window mode” :
Referring to FIG. 30B, when the up switch 130B or the down switch 130C is pressed for a short time while operating in the operation (RUN) mode, the display unit 100 displays the current value “4567” with a large number on the upper side. Is displayed, and the first setting value “2345” and the second setting value “6789” are displayed side by side below. Next, when the SET switch 120A is pressed, the first or second set value can be selected. When the up switch 130B or the down switch 130C is pressed, the numerical value of the selected threshold value (setting value) changes. When the numerical value displayed on the display unit 100 changes, the photoelectric sensor 300 operates based on the changed numerical value. When the first and second threshold values become desired numerical values, the photoelectric sensor 300 is left to stand, and the adjusted numerical value is set three seconds later. Before the adjustment and setting of the threshold value are completed, the numerical value may blink, or the color for displaying the numerical value may be different between after setting and before setting. After this setting is completed, the photoelectric sensor 300 operates under the newly set threshold value.

  In the display example of FIG. 30B as well, as in FIG. 30A described above, the current value is displayed in almost the entire area of the display unit 100 when operating normally in the operation (RUN) mode. A display mode is adopted. On the tuning screen, a display form is set to display the first and second threshold values side by side below the current value. Also in this case, it goes without saying that the display method described above with reference to FIG. 30A may be adopted for the display of the threshold value selected from the first and second threshold values.

  You may employ | adopt the display mode of FIGS. 5-7 mentioned above regarding the display of this 1st, 2nd threshold value. As a further modification, the first and second threshold values are displayed in the first and second regions arranged side by side as described with reference to FIG. Alternatively, a display form in which the current value is displayed with a relatively small number may be employed.

(C) When “Out1 + Out2” input / output is set :
Referring to FIG. 30C, when the photoelectric sensor 300 is operating normally in the operation (RUN) mode, when the up switch 130B or the down switch 130C is pressed for a short time, the display unit 100 displays “Out 1”. The character and output 1 threshold (setting value) and the character “Out2” and output 2 threshold (setting value) are displayed vertically. By briefly pressing the up switch 130B or the down switch 130C, “Out1” or “Out2” can be selected.

  When the SET switch 120A is pressed for a short time, the display unit 100 is in a display mode in which the current value and threshold value of the selected “Out1” or “Out2” are displayed up and down. In this display mode, the numerical value of the current value is displayed as a large number, and the numerical value of the threshold value (setting value) is displayed as a small number below the numerical value. When the up switch 130B or the down switch 130C is pressed, the numerical value of the selected threshold value (setting value) changes. When the numerical value displayed on the display unit 100 changes, the photoelectric sensor 300 operates based on the changed numerical value. When the desired value is reached, the photoelectric sensor 300 is left unattended, and three seconds later, the adjusted value is set, and the photoelectric sensor 300 operates under the newly set threshold value. Of course, the display of the photoelectric sensor 300 returns to the operation mode.

  In the case of FIG. 30C as well, it goes without saying that the display method described above with reference to FIG.

Advanced settings :
The operation of the photoelectric sensor can be switched from the operation (RUN) mode to the detailed setting mode by long-pressing the down switch 130C. Examples of menus that can be set (selectable) using the detailed setting mode are: (1) Response time, (2) Output logic of each output, (3) Detection mode of each output, (4) Each output Timer time, (5) hysteresis, (6) light receiving sensitivity, (7) analog lower limit value, (8) analog upper limit value, (9) output hold setting or setting cancellation, (10) brightness of display unit 100 Etc.

  Each setting item transitions by pressing the up switch 130B or the down switch 130C. When a desired setting item is displayed on the display unit 100, a menu that can be set is displayed on the display unit 100 by pressing the SET switch 120A for a short time, and can be selected by using the up switch 130B or the down switch 130C. . In addition, in the case of an item for resetting a numerical value such as hysteresis, it can be reset to a desired numerical value by the up switch 130B or the down switch 130C.

  This detailed setting mode is ended by pressing the SET switch 120A for a short time with the characters “detailed setting end” displayed on the display unit 100, and the photoelectric sensor 300 returns to the operation (RUN) mode.

  The display mode of the rectangular display unit 100 of the distance setting type photoelectric sensor 300 has been described above. However, the display mode of the slim type photoelectric sensor 200 is substantially the same. The same applies to the display of a photoelectric sensor that detects the presence / absence of the workpiece W based on the amount of received light.

Other arrangement examples of the touch switch (FIGS. 31 to 34) :
FIGS. 31 to 34 exemplify the slim photoelectric sensor 220 to which the elongated display unit 200 is applied, but the following description is also applied to the box photoelectric sensor 300 (rectangular display unit 100). Is possible.

  A slim photoelectric sensor 220 illustrated in FIG. 31 has a mechanical SET switch (first switch) 120 </ b> A at the left end of the display unit 200. The elongated display unit 200 is divided into left and right parts, for example, the second touch switch 130B is disposed on the left half, and the third touch switch 130C is disposed on the right half.

  (I) of FIG. 31 shows a state where the threshold adjustment screen is displayed on the display unit 200. A relatively large numerical value “4567” is a current value, and a relatively small numerical value “2345” on the right side thereof is a threshold value. Still referring to FIG. 31 (I), note that up / down triangular symbols 122u, 122d are displayed on the second and third touch switches 130B, 130C. The triangular symbols 122u and 122d are displayed on the display unit 200 in order to clearly indicate the functions and arrangement positions of the second and third touch switches 130B and 130C.

  The up / down symbols 122u and 122d can be used to change the setting value (threshold value) up and down and to switch the display screen to the previous page or the subsequent page by operating the second and third touch switches 130B and 130C. When the second and third touch switches 130B and 130C are active, that is, when the operation of the switches 130B and 130C can be received by the photoelectric sensor 220, it is preferable to display.

  FIG. 31 (II) shows a state in which the response time setting item is displayed on the display unit 200 in the detailed setting mode. For example, the photoelectric sensor 220 on which this display screen is displayed accepts switching from the setting item “Response Time” (response time) to the screen display of the next setting item and / or the response time selection value “20 ms”. In the state of accepting (determining), a symbol or character 131 indicating “determination” is displayed at the left end of the display unit 200 adjacent to the first switch 120A, and a page feed symbol or character is displayed at the right end. A character 132 is displayed. In this display state, the photoelectric sensor 220 does not accept the operation of the second touch switch 130B.

  FIG. 32 is a diagram for explaining an example in which all switch operations of the photoelectric sensor 220 such as a setting operation, an up / down operation, and a selection operation are performed with two switches. The display unit 200 includes a second touch switch 130B and a third touch switch 130C that are divided into left and right, and the two touch switches 130B and 130C are provided as necessary every time the display screen of the display unit 200 is switched. Different functions are assigned.

  When the elongated display unit 200 is divided into two and the two touch switches 130B and 130C are arranged, the touch switches 130B and 130C having a relatively large area can be prepared with respect to the elongated display unit 200. A function of recognizing the sliding operation of the fingertip may be given to at least one of the second and third touch switches 130B and 130C occupying this relatively large area. Of course, even when the display unit 200 is divided into three parts and the three touch switches 130A, 130B, and 130C are arranged side by side, a function of recognizing a fingertip slide operation may be given to at least one of them.

  According to this, in addition to (1) an operation of tapping a fingertip, that is, a tap operation (short pressing operation), (2) a long pressing operation with a fingertip for a long time (for example, 3 seconds or more), (3) a slide for sliding the fingertip Different functions can be provided for each of the three types of operations. As a result, the number of switches can be reduced (for example, two).

  In addition, the amount of setting value (threshold value) increase / decrease and the speed of increase / decrease change depending on the amount of pressure of the fingertip or the contact area of the fingertip when the touch switch 130B (130C, 130A) is long pressed with the fingertip You may make it make it.

  Further, the touch switch 130B (130C, 130A) is accepted to slide the fingertip in the horizontal direction (longitudinal direction of the elongated display unit 200), and the fingertip is moved in the vertical direction of the touch switch 130B (130C, 130A) (of the elongated display unit 200). The operation of sliding in the width direction may not be accepted.

  When a slide operation for moving the fingertip while touching the touch switch 130B (130C, 130A) from right to left or from left to right is recognized, for example, the display threshold value may be increased or decreased. Good. More specifically, for example, when the fingertip is slid from right to left, the display threshold value is increased. Conversely, when the fingertip is slid from left to right, the display threshold value is increased. You may make it go down. In this case, the speed at which the threshold value increases or decreases may be changed according to the speed of the fingertip slide operation. Designed to speed up the threshold value relatively quickly when sliding quickly, and relatively slow the threshold value up and down when sliding slowly. May be.

  Further, when the finger is flipped up following the slide operation, the speed at which the threshold value is increased or decreased may be changed according to the speed at the time of the finger. Designed to relatively increase the speed at which the threshold value increases / decreases when jumping quickly, and to relatively slow the speed at which the threshold value increases / decreases when flipping slowly. May be. In addition, after the fingertip is released from the touch switch 130B (130C, 130A), touching the touch switch 130B (130C, 130A) with the fingertip again may stop the up / down of the display threshold. Thereby, the setting operation can be performed while visually observing the display hidden by the fingertip to be touched by moving the fingertip away from the display unit 200.

  As another modification, the amount of slide movement of the fingertip touching the touch switch 130B (130C, 130A) is recognized, and the speed at which the threshold value is increased or decreased or the amount to be increased or decreased is changed according to the amount of slide movement. You may make it make it.

  Needless to say, the slide operation described using the touch switch 130B (130C, 130A) as an example is also applicable to the rectangular display unit 100 described above. The first to third touch switches 130A, 130B, and 130C described above are collectively referred to as a touch switch 130. When the screen displayed on the display units 100 and 200 is not set, the touch switch The erroneous recognition prevention function 130 may be activated. Then, when the photoelectric sensors 220 and 300 are operating in the operation (RUN) mode, for example, when a slide operation with the touch switch 130 is recognized, the erroneous recognition preventing function may be canceled. With this release, a normal tap operation and a long press operation are recognized. In addition, it is preferable to restore the erroneous recognition prevention function under certain conditions. For example, the false recognition prevention function may be automatically activated when the touch switch 130 is not operated for a certain period of time. In addition to the slide operation, the misrecognition prevention function may be canceled when a simultaneous tap operation at two locations of the touch switch 130 or an alternating tap operation at two locations is recognized. At this time, when an operation other than the operation for canceling the misrecognition prevention function is recognized, it is preferable to notify the display units 100 and 200 with an indication that the misrecognition prevention function is in operation, lighting, or a buzzer. . On the other hand, when an operation for canceling the misrecognition prevention function is recognized, it is preferable to notify the display units 100 and 200 that the misrecognition prevention function has been cancelled.

  In the example shown in FIG. 32, the threshold value “2345” can be adjusted by the second and third touch switches 130B and 130C. Therefore, the second touch switch 130B to which the function of decreasing the numerical value is assigned. The down symbol 122d is displayed in the portion, and the up symbol 122u is displayed in the portion of the third touch switch 130C to which the function of increasing the numerical value is assigned.

  When the display screen of the example (response time setting) described above with reference to (II) of FIG. 31 is displayed on the display unit 200, the confirmation (determination) function is assigned to the second touch switch 130B, and the third touch is performed. A display screen switching function may be assigned to the switch 130C.

  FIG. 33 shows an example in which the first to third touch switches 130 </ b> A, 130 </ b> B, and 130 </ b> C are installed on the display unit 200. Specifically, the elongated display unit 200 is divided into three in the longitudinal direction, and the first, second, and third touch switches 130A, 130B, and 130C are arranged in these three portions.

  Any function can be assigned to these three touch switches 130A, 130B, and 130C, and a function required on the display screen may be assigned according to the display screen. As can be seen from (I) of FIG. 33, in the illustrated example, the above-described setting screen of “Response Time” (response time) is illustrated. In this setting screen, a determination (determination) function is given to the first touch switch 130A located in the center, an up function is given to the second touch switch 130B located on the left, and a third touch switch 130C located on the right is assigned to the setting screen. The down function is given. Symbols or characters 131, 122u, and 122d that explain these functions are displayed below the lower end of the display unit 200, that is, below the first to third touch switches 130A to 130C. Of course, the symbols or characters 131, 122u, 122d for explaining the switch function may be displayed on the first to third touch switches 130A to 130C.

  The example shown in FIG. 34 is a modification of the example shown in FIG. 33 described above. That is, FIG. 34 shows another example in which the first to third touch switches 130A, 130B, and 130C are installed on the display unit 200. In the example illustrated in FIG. 34, the first touch switch 130 </ b> A is disposed at the left end portion of the display unit 200. On the other hand, the second and third touch switches 130 </ b> B and 130 </ b> C are arranged side by side at the right end of the display unit 200.

  In addition to characters 131, 122u, 122d such as symbols for explaining the function of each touch switch 130A, 130B, 130C, a display that clearly indicates the difference between short press and long press of each touch switch 130A, 130B, 130C (for example, lighting) And differentiating by flashing and differentiating by flashing speed) and characters ("S" (meaning short press) and "L" (meaning long press)) may be additionally displayed. A character may be displayed instead of or in addition to the character explaining the function of the touch switches 130A, 130B, and 130C. Further, when a mechanical switch is included in a part of the photoelectric sensor switch, a character or a character explaining the function assigned to the mechanical switch is displayed at a position adjacent to the mechanical switch. Is preferred.

Examples of information to be displayed on the display unit in the photoelectric sensor having a general meaning are as follows.
(1) Regarding output, ON / OFF, analog current value or analog voltage value, channel number, L-on / D-on setting state.
(2) Regarding the current value, distance, received light amount, degree of coincidence, margin, channel number, current value after presetting, current value after shifting.
(3) For hold, peak value, bottom value.

(4) Regarding the set value, threshold value, channel number, lower limit value, upper limit value, first and second threshold values of the window.
(5) Regarding the status of the photoelectric sensor, whether there is key lock, abnormal status such as errors and warnings, external input ON / OFF status, external input function operating status, preset status, APC status, communication with the host device Status, communication status with slave unit, set detection mode.
(6) Others include display upside down display, horizontal writing / vertical writing, tag display, display language switching, photoelectric sensor type and serial number.
Of the above display information, the display that changes in time series is output ON / OFF, current value, and external input.

  As a display method of the display units 100 and 200, in the case of numerical display, the size, color, shading, blinking, bar display, and waveform display of time series information can be given.

As a display mode of the display units 100 and 200 when the box-type or slim-type photoelectric sensor is operating normally in the operation (RUN) mode, only the current value is displayed, and the current value and the threshold value (set value) are displayed. Besides the simultaneous display, the following combinations can be listed.
(1) Simultaneous display of current value and hold value
(2) Simultaneous display of current value, hold value and output status,
(3) Simultaneous display of current value, threshold value and output status,
(4) Simultaneous display of current value and margin

(5) Simultaneous display of current value, margin and output status,
(6) Simultaneous display of current value and bar display
(7) Simultaneous display of current value, bar display and output status
(8) Simultaneous display of the current value of the first channel and the current value of the second channel,
(9) Simultaneous display of the current value of the first channel, the current value of the second channel, and the output state.

100 Rectangular display (for box photoelectric sensor)
120A Button-type first switch (SET switch)
120B Button type second switch (up switch)
120C Button type third switch (down switch)
122u Up symbol 122d Down symbol 131 Decision symbol 132 Page feed symbol 130A First touch switch (SET switch)
130B 2nd touch switch (up switch)
130C 3rd touch switch (down switch)
200 Slender display (for slim photoelectric sensor)
220 Slim Type Photoelectric Sensor 300 Box Type Photoelectric Sensor of Example

Claims (8)

A photoelectric device that detects the amount of light received or distance using light, compares the detected current amount of light received or distance with a set threshold value, and outputs an ON signal and an OFF signal to the outside according to the comparison result. A sensor,
A display unit disposed on the operation surface and configured by a matrix display;
A plurality of operation switches disposed on an operation surface for adjusting the threshold value and setting a plurality of setting items of the photoelectric sensor ;
The threshold value is adjusted by operating the operation switch during the operation mode, and a plurality of setting items of the photoelectric sensor are sequentially displayed on the display unit by operating the operation switch during the setting mode. ,
At least one of the plurality of operation switches is constituted by a touch switch provided in the display unit,
The display unit displays a character or a character that explains the function of the operation switch configured by the touch switch ,
The operation switch composed of the touch switch, a photoelectric sensor, wherein Rukoto provided on the screen display of the threshold adjustment screen or the setting items are displayed on the display unit. The plurality of operation switches are composed of first, second and third switches,
The first switch is a mechanical switch;
The photoelectric sensor according to claim 1, wherein the second and third switches are the touch switches.   The photoelectric sensor according to claim 2, wherein a character or a character that explains a function of the first switch is displayed at a position adjacent to the first switch of the display unit. The photoelectric sensor according to claim 1, wherein all of the plurality of operation switches are configured by the touch switch. The touch switch has a function of adjusting a setting value displayed on the display unit, and the setting value displayed on the display unit can be adjusted by bringing a fingertip into contact with the touch switch. Item 5. The photoelectric sensor according to any one of Items 1 to 4 . 6. The function according to claim 5 , wherein different functions are assigned to the touch switch by a short press operation of pressing the touch switch with a fingertip for a relatively short time and a long press operation of pressing the touch switch with a fingertip for a relatively long time. Photoelectric sensor. The touch switch has different functions for a short press operation for pressing the touch switch with a fingertip for a relatively short time, a long press operation for pressing the touch switch with a fingertip for a relatively long time, and a slide operation for sliding the fingertip on the touch switch. The photoelectric sensor according to claim 5, which is assigned to When a sliding operation from one to the other is recognized by the touch switch on the threshold adjustment screen displayed on the display unit during the operation mode, the threshold value is increased, and the touch switch is used to increase the threshold value. The photoelectric sensor according to claim 5, wherein when the sliding operation from the other to the one is recognized, the threshold value is decreased.

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