KR20200111765A - Photoelectric sensor and multi-beam photoelectric sensor - Google Patents

Abstract

The photoelectric sensor 11 includes a light-transmitting portion 12 for transmitting light, a light-receiving portion 13 for receiving light, a plurality of auxiliary output terminals 30 capable of outputting a high-level or low-level signal to the outside, a light-transmitting portion, and A control unit 20 is provided for controlling the light receiving unit and outputting the set output information through the auxiliary output terminal, and the control unit compares the amount of light received by the light receiving unit and a plurality of threshold values to obtain a light receiving level divided into three or more steps. The received light amount is converted, and the received light level is output in binary through a plurality of auxiliary output terminals.

Description

Photoelectric sensor and multi-beam photoelectric sensor

The present invention relates to a photoelectric sensor and a multi-optical axis photoelectric sensor.

As a kind of photoelectric sensor, a multi-optical axis photoelectric sensor including a plurality of light transmitting elements and a plurality of light receiving elements is mentioned. Patent Literature 1 describes a multi-optical-axis photoelectric sensor including a display that displays information indicating the amount of light received by the light-receiving element.

Japanese Patent Publication No. 2002-124168

A plurality of such photoelectric sensors are installed in a factory, for example. In this case, in order to grasp the amount of light received by each photoelectric sensor, it is necessary to check the indicator and go around. Therefore, it takes time to grasp the amount of light received by the plurality of photoelectric sensors. On the other hand, if a configuration for outputting the amount of light received is newly provided, there is a fear that the configuration of the photoelectric sensor becomes complicated.

An object of the present invention is to provide a photoelectric sensor and a multi-optical axis photoelectric sensor capable of grasping the amount of light received with a simple and easy configuration.

Hereinafter, the means for solving the said subject and its effect are described.

A photoelectric sensor that solves the above problem includes a light transmitting unit for transmitting light, a light receiving unit for receiving light, a plurality of auxiliary output terminals capable of outputting a high level or low level signal to the outside, and controlling the light transmitting unit and the light receiving unit, And a control unit for outputting the set output information through the auxiliary output terminal, and the control unit converts the received light amount into a light reception level divided into three or more steps by comparing the received light amount received by the light receiving unit with a plurality of threshold values. And outputs the light-receiving level in binary through a plurality of the auxiliary output terminals.

According to this configuration, the light-receiving level can be externally output through the auxiliary output terminal that outputs output information. That is, there is no need to newly install a configuration only for outputting the light-receiving level. By outputting the light-receiving level through the auxiliary output terminal, for example, the light-receiving level can be determined through an external terminal such as a computer connected to the photoelectric sensor. Therefore, it is possible to grasp the amount of light received with a simple and easy configuration.

In the photoelectric sensor, it is preferable that the control unit outputs information indicating a correspondence relationship between the plurality of auxiliary output terminals to which the light-receiving level is output, and each digit of a binary number indicating the light-receiving level.

According to this configuration, a correspondence relationship between a plurality of auxiliary output terminals and a binary number indicating a light-receiving level can be grasped. Therefore, it is possible to reduce the possibility that the connection destination of the signal line connected to the auxiliary output terminal is wrong.

In the photoelectric sensor, the control unit determines the light receiving level through the auxiliary output terminal different from the auxiliary output terminal configured to output the output information different from the light receiving level among the plurality of auxiliary output terminals. It is desirable to print it out.

According to this configuration, it is possible to output the light-receiving level through an unused auxiliary output terminal among a plurality of auxiliary output terminals. Therefore, it is possible to output the light-receiving level and output information different from the light-receiving level through a plurality of auxiliary output terminals.

In the photoelectric sensor, the control unit, when setting to output the light-receiving level through the auxiliary output terminal, to output the light-receiving level when the number of auxiliary output terminals for which the output information is not set is insufficient It is desirable to indicate that the number of required auxiliary output terminals is insufficient.

According to this configuration, it is possible to inform the user that the number of auxiliary output terminals required for outputting the light-receiving level is insufficient.

In the photoelectric sensor, a transmitter having the light transmitting unit and a light receiving unit having the light receiving unit are provided, and the light receiving unit has an output terminal capable of outputting a control signal, and the auxiliary output terminal is provided on the emitter. desirable.

According to this configuration, a photoelectric sensor can be suitably configured.

A multi-optical-axis photoelectric sensor that solves the above problem includes a plurality of light-transmitting parts that transmit light, a plurality of light-receiving parts that receive light, a detection part that performs detection based on a comparison of the amount of light received by the light-receiving part and a threshold value, and a detection result of the detection part. A plurality of auxiliary output terminals capable of outputting a signal of a high level or low level based on a set condition, and the light transmitting unit and the light receiving unit are controlled to transmit set output information through the auxiliary output terminal. A multi-optical-axis photoelectric sensor having an output control unit, wherein the control unit detects a detection margin divided into three or more steps by comparing an amount of light received by the light receiving unit with a plurality of threshold values, and the plurality of auxiliary output terminals The detection margin is output in binary.

According to this configuration, the detection margin can be output through the auxiliary output terminal that outputs output information. That is, it is not necessary to newly install a configuration only for outputting the detection margin. By outputting the light-receiving level through the auxiliary output terminal, for example, the light-receiving level can be determined through an external terminal such as a computer connected to the photoelectric sensor. Therefore, it is possible to grasp the amount of light received with a simple and easy configuration.

According to the photoelectric sensor of the present invention, the amount of received light can be grasped with a simple and easy configuration.

1 is a perspective view showing an embodiment of a photoelectric sensor.
2 is a block diagram showing an electrical configuration of a photoelectric sensor.
3 is a schematic diagram showing a setting screen.
4 is a diagram showing a table showing a correspondence relationship between a light-receiving level and a signal output from an auxiliary output terminal.

Hereinafter, an embodiment of a photoelectric sensor will be described with reference to the drawings.

As shown in FIG. 1, the photoelectric sensor 11 includes a light-transmitting portion 12 to transmit light and a light-receiving portion 13 to receive light. The light-transmitting part 12 has a light-transmitting element, such as a light-emitting diode, for example. The light-receiving unit 13 has a light-receiving element such as a photo transistor.

The photoelectric sensor 11 includes a light transmitter 14 having a light transmitting portion 12 and a light receiving device 15 having a light receiving portion 13. The light transmitter 14 and the light receiver 15 are formed in a columnar shape. The light transmitting device 14 of the present embodiment has a plurality of light transmitting portions 12. The plurality of light transmitting portions 12 are positioned so as to be lined up over the longitudinal direction of the light transmitting unit 14. The light receiving device 15 of the present embodiment has a plurality of light receiving portions 13. The plurality of light-receiving portions 13 are positioned so as to be lined up over the longitudinal direction of the light-receiving device 15.

The light transmitter 14 and the light receiver 15 are disposed so that the light transmitting part 12 and the light receiving part 13 face each other. Thereby, an optical axis L extending from the light transmitting part 12 toward the light receiving part 13 is formed. In this embodiment, a plurality of optical axes L are formed. That is, the photoelectric sensor 11 of the present embodiment is configured as a multi-optical axis photoelectric sensor, a so-called light curtain. The photoelectric sensor 11 detects an article by blocking the optical axis L from the article, that is, blocking light.

The photoelectric sensor 11 includes a display unit 16 that displays the amount of light received by the light receiving unit 13 as a light receiving level. The display unit 16 includes, for example, an indicator light, a liquid crystal screen, and the like. The display unit 16 of the present embodiment is provided on the light receiver 15. The display unit 16 may be provided on the emitter 14 or may be provided on both the emitter 14 and the light receiver 15. In addition to the light-receiving level, the display unit 16 may display the operating state of the photoelectric sensor 11.

The photoelectric sensor 11 converts the amount of light received by the light receiving unit 13 into a light receiving level. The light-receiving level is divided into at least three stages. The photoelectric sensor 11 of the present embodiment converts the amount of light received by the light-receiving unit 13 to one of light-receiving level 0, light-receiving level 1, light-receiving level 2, and light-receiving level 3. That is, in this embodiment, the light-receiving level is divided into four stages. The larger the amount of light received, the greater the level of light received. When the optical axis L is blocked, the amount of light received by the light-receiving unit 13 becomes a light-receiving level of 0. The light-receiving level 0 indicates that the photoelectric sensor 11 is in a light-shielding state. The light-receiving level 1, the light-receiving level 2, and the light-receiving level 3 indicate that the photoelectric sensor 11 is in a light incident state.

The display unit 16 displays the converted light reception level. For example, when there is an article between the light-transmitting portion 12 and the light-receiving portion 13, since the optical axis L is blocked by the article, the display unit 16 displays the light-receiving level 0. By checking the light-receiving level displayed on the display unit 16, the user can grasp the magnitude of the amount of light received by the light-receiving unit 13.

The display unit 16 may display the detection margin instead of the light-receiving level. The detection margin indicates the margin of the amount of light received by the light receiving unit 13 in the photoelectric sensor 11 in the light incident state. That is, the detection margin corresponds to the light-receiving level 1, the light-receiving level 2, and the light-receiving level 3. For example, the display unit 16 displays one of a detection margin 1, a detection margin 2, and a detection margin 3 based on the amount of light received by the light receiving unit 13. The larger the received light amount, the larger the detection margin. In this case, the display unit 16 may display whether the photoelectric sensor 11 is in a light-incident state or a light-shielding state separately from the detection margin.

The photoelectric sensor 11 is generally used in a factory. Therefore, when dust, debris, etc. floating in the factory adhere to the light transmitting part 12 and the light receiving part 13, the light-receiving level becomes small. For this reason, the user can maintain the photoelectric sensor 11 at an appropriate timing by checking the light-receiving level. As a factor in which the light-receiving level decreases, there is aging deterioration of the light-transmitting portion 12 and the light-receiving portion 13 in addition to adhesion of dust and dust. In this case, by checking the light-receiving level, the photoelectric sensor 11 can be changed at an appropriate timing. The user can also grasp the shift of the optical axis L by checking the light-receiving level.

Even in the case where the detection margin is displayed on the display unit 16, the user can maintain the photoelectric sensor 11 at an appropriate timing by checking the detection margin. The larger the detection margin is, the more accurately the article can be detected. The reason for this is that if the detection margin is small, for example, only a slight vibration is exerted on the light emitter 14 and the light receiver 15, and the photoelectric sensor 11 enters the light-shielding state from the light incident state.

The light transmitter 14 and the light receiver 15 are synchronized with each other. The transmitter 14 and the light receiver 15 may be synchronized by a cable or by light.

As shown in FIG. 2, the photoelectric sensor 11 includes a control unit 20 that controls the light transmitting unit 12 and the light receiving unit 13. The control unit 20 includes, for example, a CPU and a memory. In this embodiment, the control unit 20 is provided in each of the light emitter 14 and the light receiver 15. The control unit 20 of the emitter 14 is referred to as the first control unit 21, and the control unit 20 of the light receiver 15 is referred to as the second control unit 22. The first control unit 21 controls the light emitter 14. The second control unit 22 controls the light receiver 15.

The control unit 20 may be provided only on one of the light transmitter 14 and the light receiver 15. For example, the control unit 20 may be provided only on the light projector 14. In this case, the first control unit 21 installed in the emitter 14 controls the emitter 14 and the light receiver 15. For example, the control unit 20 may be provided only on the light receiver 15. In this case, the second control unit 22 installed in the light receiver 15 controls the emitter 14 and the light receiver 15. In the present specification, when there is no need to distinguish between the first control unit 21 and the second control unit 22, it is simply referred to as the control unit 20.

The control unit 20 converts the received amount of light into a light-receiving level by comparing the amount of light received by the light receiving unit 13 with a threshold value. The control unit 20 stores a plurality of threshold values. The control unit 20 stores three threshold values, for example, a first threshold, a second threshold, and a third threshold. The first threshold is a value smaller than the second threshold. The second threshold is a value smaller than the third threshold. The control unit 20 converts the received amount of light into a light-receiving level by comparing the amount of light received by the light receiving unit 13 with a first threshold value, a second threshold value, and a third threshold value. When there are a plurality of light-receiving units 13, the control unit 20 compares the smallest received amount of light received from the plurality of light-receiving units 13 and a threshold value.

When the amount of light received by the light-receiving unit 13 is smaller than the first threshold, the control unit 20 converts the amount of received light into a light-receiving level of 0. When the light-receiving amount received by the light-receiving unit 13 is greater than the first threshold and less than the second threshold, the control unit 20 converts the received light amount as a light-receiving level 1. When the amount of light received by the light-receiving unit 13 is larger than the second threshold and smaller than the third threshold, the control unit 20 converts the received amount of light into a light-receiving level 2. When the light-receiving amount received by the light-receiving unit 13 is greater than the third threshold, the control unit 20 converts the received light amount as a light-receiving level 3. In this way, the control unit 20 functions as a conversion unit that converts the amount of light received by the light receiving unit 13 into a light receiving level.

When the amount of light received by the light-receiving unit 13 reaches a light-receiving level of 0, the photoelectric sensor 11 is in a light-shielded state. The control unit 20 detects that the optical axis L is blocked by the amount of light received by the light receiving unit 13 being smaller than the first threshold. In other words, the control unit 20 detects an article positioned between the light transmitting unit 12 and the light receiving unit 13 by the amount of light received by the light receiving unit 13 at a light receiving level of 0. In this way, the control unit 20 functions as a detection unit for detecting an article located between the light transmitting unit 12 and the light receiving unit 13. The control unit 20 as a detection unit performs detection based on the comparison of the amount of light received by the light receiving unit 13 and a threshold value.

The control unit 20 may detect the detection margin by comparing the amount of light received by the light receiving unit 13 with a plurality of threshold values. In this case, the second threshold and the third threshold are threshold values for detecting the detection margin from the amount of light received by the light receiving unit 13. The first threshold value becomes a threshold value for detecting whether the photoelectric sensor 11 is in a light-incident state or a light-shielding state.

The control unit 20 detects an article based on a set detection condition. The detection conditions are conditions determined by a muting function, a blanking function, an interlock function, an external device monitor function, an application indicator function, a protection function, and the like that the photoelectric sensor 11 has. For example, the muting function is a function of temporarily preventing an article from being detected even when the amount of light received by the light receiving unit 13 becomes smaller than a first threshold. In other words, the muting function is a function that prevents detection of an article even in a light-shielded state. For example, the blanking function is a function of not detecting an article even when the amount of light received by some of the plurality of light receiving units 13 is less than the first threshold. That is, the blanking function is a function that prevents detection of an article even when a specific optical axis L is blocked. For these functions, valid or invalid is set by the user. When the blanking function is enabled, the control unit 20 detects the article based on the detection condition by the blanking function.

The photoelectric sensor 11 is connected to the controller 24. The photoelectric sensor 11 outputs a signal to the outside or inputs a signal from the outside through the controller 24. The transmitter 14 and the light receiver 15 are connected to the controller 24 via a plurality of signal lines 25. The light emitter 14 and the light receiver 15 of this embodiment are connected to the controller 24 by a 12-core cable having a plurality of signal lines 25.

The photoelectric sensor 11 includes a plurality of terminals to which the signal lines 25 are connected. The photoelectric sensor 11 includes an output terminal 27, a synchronization terminal 28 and 29, and an auxiliary output terminal 30. The photoelectric sensor 11 includes a power supply terminal (not shown) to which power is supplied, a test terminal (not shown), and the like.

The output terminal 27 is a terminal for outputting a control signal to the outside. The control unit 20 outputs a control signal through the output terminal 27 when the amount of light received by the light receiving unit 13 is greater than the first threshold. The control unit 20 stops outputting the control signal when the amount of light received by the light receiving unit 13 is smaller than the first threshold value, that is, when detecting an article. That is, the control signal is a signal based on the detection result of the photoelectric sensor 11. The output terminal 27 can output the detection result of the detection unit (control unit 20). The photoelectric sensor 11 is used as a safety device for stopping the operation of an external device electrically connected to the photoelectric sensor 11 by stopping the output of the control signal, for example. In this embodiment, the output terminal 27 is provided in the light receiver 15. The output terminal 27 may be provided on the light emitter 14.

The synchronization terminal 28 is provided on the light emitter 14. The synchronization terminal 29 is provided in the light receiving device 15. The emitter 14 and the light receiver 15 are synchronized by connecting the signal line 25 to the synchronization terminal 28 and the synchronization terminal 29. The light emitter 14 and the light receiver 15 of this embodiment are synchronized via the controller 24. In the photoelectric sensor 11 of the present embodiment, a signal is input from the controller 24 via the synchronization terminals 28 and 29.

A plurality of auxiliary output terminals 30 are provided. The photoelectric sensor 11 of this embodiment includes three auxiliary output terminals 30. The three auxiliary output terminals 30 are provided on the light emitter 14. The auxiliary output terminal 30 may be provided in the light receiving device 15 or may be provided in both the light transmitting device 14 and the light receiving device 15. Four or more auxiliary output terminals 30 may be provided. In this embodiment, the three auxiliary output terminals 30 are referred to as a first auxiliary output terminal 31, a second auxiliary output terminal 32, and a third auxiliary output terminal 33, respectively. In the present specification, when it is not necessary to distinguish between the first auxiliary output terminal 31, the second auxiliary output terminal 32, and the third auxiliary output terminal 33, it is simply referred to as auxiliary output terminal 30. .

The auxiliary output terminal 30 is a terminal for outputting a high-level or low-level signal to the outside. The auxiliary output terminal 30 can output the set output information. The type of output information output from the auxiliary output terminal 30 is determined by the user. The control unit 20 sets output information output from the auxiliary output terminal 30 through an operation from the controller 24, for example. In this way, the control unit 20 functions as a setting unit that sets output information output from the auxiliary output terminal 30. The control unit 20 can set output information for each auxiliary output terminal 30. Therefore, the 1st auxiliary output terminal 31, the 2nd auxiliary output terminal 32, and the 3rd auxiliary output terminal 33 can each output different output information.

The auxiliary output terminal 30 is used for outputting information other than the detection result, while the output terminal 27 outputs the detection result. The general photoelectric sensor 11 has an auxiliary output terminal 30. The user outputs the output information required by each from the auxiliary output terminal 30.

The control unit 20 can output the light-receiving level through the auxiliary output terminal 30. The number of values that can be output by one auxiliary output terminal 30 is two. In contrast, the light-receiving level is divided into at least three stages. Therefore, the control unit 20 outputs the light-receiving level through the plurality of auxiliary output terminals 30. The control unit 20 converts the light reception level into a binary number in order to output the light reception level through the auxiliary output terminal 30. That is, the control unit 20 functions as a conversion unit that converts the light-receiving level into a binary number.

The light-receiving level divided into at least three stages is converted into a binary number of two or more digits by the control unit 20. For this reason, in order to output the light-receiving level in binary, at least two auxiliary output terminals 30 are required. The number of binary digits representing the light-receiving level and the number of auxiliary output terminals 30 required to output the light-receiving level coincide. In this embodiment, the light-receiving level is divided into four stages of a light-receiving level 0, a light-receiving level 1, a light-receiving level 2, and a light-receiving level 3. Therefore, in order to output the light-receiving level in binary, two auxiliary output terminals 30 are required.

The control unit 20 outputs the light-receiving level in binary through the plurality of auxiliary output terminals 30. Specifically, the control unit 20 outputs a light-receiving level divided into M steps (3≦M≦2^N) in binary through N (N is an integer of 2 or more) auxiliary output terminals 30 do. That is, when the light-receiving level is divided into three or four stages, the light-receiving level is output through the two auxiliary output terminals 30. When the light-receiving level is divided into any one of five to eight levels, the light-receiving level is output through the three auxiliary output terminals 30.

The control unit 20 may output the detection margin through the plurality of auxiliary output terminals 30 instead of the light receiving level. In this case, the control unit 20 converts the detection margin to binary. The detection margin is divided into at least three steps. The control unit 20 outputs the detection margin in binary through the plurality of auxiliary output terminals 30.

As shown in FIG. 3, the control unit 20 causes the setting screen 40 to be displayed on an external terminal such as a computer that is electrically connected to the photoelectric sensor 11 via the controller 24, for example. The setting screen 40 is a screen for setting output information output from the auxiliary output terminal 30. The user operates this setting screen 40 to select output information output from the auxiliary output terminal 30.

The control unit 20 sets output information selected by the user. The control unit 20 outputs the set output information through the auxiliary output terminal 30. The setting screen 40 may be displayed on the display unit 16. In this case, an operation unit such as a cursor key may be provided on the photoelectric sensor 11 to set output information. The setting screen 40 may be capable of setting not only output information but also detection conditions such as a muting function.

On the setting screen 40, a first selection box 41, a second selection box 42, and a third selection box 43 are displayed. The first selection field 41 is a field for selecting output information output from the first auxiliary output terminal 31. The second selection field 42 is a field for selecting output information output from the second auxiliary output terminal 32. The third selection field 43 is a field for selecting output information output from the third auxiliary output terminal 33.

A pull-down button 44 is provided in each of the first selection column 41, the second selection column 42, and the third selection column 43. When the pull-down button 44 is pressed down, a display field 45 in which items of selectable output information are arranged is displayed. In the display field 45, for example, "ON when muting", "OFF during muting", "ON when receiving light, OFF when blocking light", "ON when receiving light, OFF when blocking light", and "ON when locked out", Output information such as "OFF when locked out" is displayed. During muting, the muting function is enabled. When light is received, the light is received by the light receiving unit 13, that is, the photoelectric sensor 11 is not detecting an article. Therefore, when the light is received, the control unit 20 is outputting a control signal. The light-shielding period is a state in which the light-receiving unit 13 is shielded from light, that is, a state in which the photoelectric sensor 11 is detecting an article. Therefore, when the light is blocked, the control unit 20 is a state in which the output of the control signal is stopped. The lockout is a state in which the photoelectric sensor 11 is causing an abnormality.

From the auxiliary output terminal 30, two values of a high level signal and a low level signal are output. Therefore, the auxiliary output terminal 30 is used solely to confirm whether a specific function is turned ON or OFF, and whether the state of the photoelectric sensor 11 is normal or abnormal. When "ON at the time of muting" is selected, a high level signal is output from the auxiliary output terminal 30 while muting is functioning. When "OFF during muting" is selected, a high level signal is output from the auxiliary output terminal 30 while muting is not functioning. In this way, a signal is output from the auxiliary output terminal 30 in conjunction with ON and OFF of a specific function. Thereby, the user can grasp the state of the photoelectric sensor 11 through the controller 24. The auxiliary output terminal 30 is capable of outputting a high-level or low-level signal based on a set condition.

When the muting function is not enabled, "ON during muting" and "OFF during muting" are not displayed in the display field 45. That is, the item of the output information displayed in the display field 45 includes setting information of a set detection condition. The setting screen 40 may be configured such that "ON during muting" and "OFF during muting" cannot be selected when the muting function is not enabled.

The auxiliary output terminal 30 can output the light-receiving level. Therefore, in the display field 45, "light-receiving level" is displayed in the same manner as "ON during muting" and "ON during lockout". As described above, in order to output the light-receiving level, a plurality of auxiliary output terminals 30 are required. Therefore, the control unit 20, among the plurality of auxiliary output terminals 30, the light receiving level through the auxiliary output terminal 30 different from the auxiliary output terminal 30 set to output output information different from the light receiving level. It is desirable to print out. That is, the light-receiving level may be output through the auxiliary output terminal 30 in which the output information is not set. In this way, the light-receiving level and output information different from the light-receiving level can be output through the plurality of auxiliary output terminals 30. In the display field 45, "detection margin" may be displayed.

When the light-receiving level is set as the output information output from one auxiliary output terminal 30, the light-receiving level may be automatically set for the other auxiliary output terminal 30 whose output information is not set. For example, when the first selection box 41 and the second selection box 42 are not set, and output information different from the ``light-receiving level'' is set in the third selection box 43, the first selection box 41 When the "light-receiving level" is set to, the "light-receiving level" may be automatically set in the second selection field 42. In this case, in the second selection field 42 in which the output information is automatically set, the change of the output information may be prohibited. When the detection margin is set as output information output from one auxiliary output terminal 30, the detection margin may be automatically set for the other auxiliary output terminals 30 whose output information is not set.

When the control unit 20 is set to output the light-receiving level through the auxiliary output terminal 30, when the number of auxiliary output terminals 30 for which output information is not set is insufficient, the auxiliary output required to output the light-receiving level It is desirable to notify that the number of terminals 30 is insufficient. That is, in setting the light-receiving level as the output information, the control unit 20 may inform the meaning of when the number of auxiliary output terminals 30 for which the output information is not set is insufficient. For example, when the first selection box 41 is not set, and output information different from the ``light-receiving level'' is set in the second selection box 42 and the third selection box 43, When "light-receiving level" is set in the first selection column 41, it is sufficient to inform that the number of auxiliary output terminals 30 required for outputting the light-receiving level is insufficient. When the control unit 20 is set to output the detection margin through the auxiliary output terminal 30, when the number of auxiliary output terminals 30 for which the output information is not set is insufficient, the auxiliary necessary for outputting the light reception level It may be known that the number of output terminals 30 is insufficient.

The control unit 20 may inform by displaying on the setting screen 40 a message indicating that the number of auxiliary output terminals 30 required for outputting the light-receiving level is insufficient. The control unit 20 may notify by sounding a warning sound through the terminal on which the setting screen 40 is displayed. In this way, the control unit 20 functions as a notification unit notifying that the number of auxiliary output terminals 30 required for outputting the light-receiving level is insufficient. In this way, it is possible to inform the user that the number of auxiliary output terminals 30 required to output the light reception level is insufficient.

It is preferable that the control unit 20 outputs information indicating a correspondence relationship between the plurality of auxiliary output terminals 30 for outputting the light-receiving level and each digit of a binary number indicating the light-receiving level. For example, when setting to output the light-receiving level through the first auxiliary output terminal 31, if ``light-receiving level (1)'' is set in the first check box 41, the ``light-receiving level'' is set in the second check box 42 (2)" is set. When outputting the detection margin, the control unit 20 preferably outputs information indicating a correspondence relationship between the plurality of auxiliary output terminals 30 for outputting the detection margin, and each digit of a binary number indicating the light reception level. Do.

The numbers in parentheses at the end of the light-receiving level indicate the number of digits of the binary number indicating the light-receiving level. In this case, the signal output from the first auxiliary output terminal 31 represents the value of the first digit of the numerical value obtained by converting the light-receiving level into a binary number. The signal output from the second auxiliary output terminal 32 represents the value of the second digit of the numerical value obtained by converting the light-receiving level into a binary number. That is, the number with parentheses at the end of the light-receiving level is information indicating a correspondence relationship between the auxiliary output terminal 30 and each digit of a binary number. In this way, the correspondence between the signal output from the auxiliary output terminal 30 and each digit of the binary number can be grasped. Therefore, the possibility that the connection destination of the signal line 25 connected to the auxiliary output terminal 30 is wrong is reduced. You may set "light-receiving level (2)" in the 1st selection column 41. In this case, the "light reception level 1" is set in the second selection column 42. When outputting the detection margin, you may set the "detection margin (1)" in the first selection box 41 and the "detection margin (2)" in the second selection column 42. The numbers in parentheses at the end of the detection margin indicate the number of digits in the binary number indicating the detection margin.

As shown in Fig. 4, the light-receiving level is displayed by a combination of a high-level signal and a low-level signal output from the plurality of auxiliary output terminals 30. In Fig. 4, "H" represents a high level signal, and "L" represents a low level signal. 4 is an example of a conversion table indicating the light-receiving level in binary when the first auxiliary output terminal 31 and the second auxiliary output terminal 32 output the light-receiving level.

The control unit 20 outputs a low level signal from the first auxiliary output terminal 31 and the second auxiliary output terminal 32 when the amount of light received by the light receiving unit 13 is at a light reception level of 0. The controller 20 outputs a high level signal from the first auxiliary output terminal 31 and a low level signal from the second auxiliary output terminal 32 when the amount of light received by the light receiving unit 13 is at the light reception level 1 Output the signal. The controller 20 outputs a low level signal from the first auxiliary output terminal 31 and a high level signal from the second auxiliary output terminal 32 when the amount of light received by the light receiving unit 13 is at the light receiving level 2 Output the signal. The control unit 20 outputs a high level signal from the first auxiliary output terminal 31 and the second auxiliary output terminal 32 when the amount of light received by the light receiving unit 13 is the light receiving level 3. In this way, the control unit 20 outputs the light-receiving level. The control unit 20 may output the light-receiving level through the first auxiliary output terminal 31 and the third auxiliary output terminal 33, and the second auxiliary output terminal 32 and the third auxiliary output terminal 33 The light-receiving level may be output through.

In the case of outputting the detection margin, the control unit 20 outputs a high level signal from the first auxiliary output terminal 31 when detecting the detection margin 1 from the amount of light received by the light receiving unit 13 , Outputs a low-level signal from the second auxiliary output terminal 32. When the detection margin 2 is detected from the amount of light received by the light receiving unit 13, the control unit 20 outputs a low-level signal from the first auxiliary output terminal 31, and outputs a low level signal from the second auxiliary output terminal 32. Outputs a high level signal. The control unit 20 outputs a high level signal from the first auxiliary output terminal 31 and the second auxiliary output terminal 32 when detecting the detection margin 3 from the amount of light received by the light receiving unit 13.

Next, the action and effect of the above embodiment will be described.

(1) The auxiliary output terminal 30 is capable of outputting set output information. The control unit 20 converts the received amount of light into a light-receiving level by comparing the amount of light received by the light-receiving unit 13 with a threshold value, and outputs the light-receiving level in binary through the plurality of auxiliary output terminals 30. Thereby, the photoelectric sensor 11 can output the light-receiving level to the outside via the auxiliary output terminal 30 which outputs output information. That is, there is no need to newly install a configuration only for outputting the light-receiving level. By outputting the light-receiving level through the auxiliary output terminal 30, for example, the light-receiving level can be grasped through an external terminal such as a computer connected to the photoelectric sensor 11. Therefore, it is possible to grasp the amount of light received with a simple and easy configuration.

(2) The control unit 20 outputs information indicating a correspondence relationship between the plurality of auxiliary output terminals 30 to which the light-receiving level is output, and each digit of a binary number indicating the light-reception level. This makes it possible to grasp the correspondence between the plurality of auxiliary output terminals 30 and the binary number indicating the light-receiving level. Therefore, it is possible to reduce the possibility that the connection destination of the signal line 25 connected to the auxiliary output terminal 30 is wrong.

(3) The control unit 20 has a light-receiving level through an auxiliary output terminal 30 different from the auxiliary output terminal 30, which is set to output output information different from the light-receiving level among the plurality of auxiliary output terminals 30 Prints. This makes it possible to output the light-receiving level through the unused auxiliary output terminal 30 among the plurality of auxiliary output terminals 30. Therefore, the light-receiving level and output information different from the light-receiving level can be output through the plurality of auxiliary output terminals 30.

(4) The control unit 20, when setting to output the light-receiving level through the auxiliary output terminal 30, when the number of auxiliary output terminals 30 for which no output information is set is insufficient, to output the light-receiving level It signals that the number of necessary auxiliary output terminals 30 is insufficient. Thereby, it is possible to inform the user that the number of auxiliary output terminals 30 required for outputting the light-receiving level is insufficient.

(5) An output terminal 27 for outputting a control signal is provided in the light receiver 15. The auxiliary output terminal 30 for outputting output information is provided on the light emitter 14. In this way, the photoelectric sensor 11 can be configured suitably.

(6) The auxiliary output terminal 30 is capable of outputting set output information. The control unit 20 detects the detection margin divided into three or more steps by comparing the amount of light received by the light receiving unit 13 and a threshold value, and determines the detection margin in binary number through the plurality of auxiliary output terminals 30. Print. Thereby, the photoelectric sensor 11 can output the detection margin through the auxiliary output terminal 30 which outputs output information. That is, it is not necessary to newly install a configuration only for outputting the detection margin. By outputting the detection margin through the auxiliary output terminal 30, for example, the detection margin can be determined through an external terminal such as a computer connected to the photoelectric sensor 11. Therefore, it is possible to grasp the amount of light received with a simple and easy configuration.

This embodiment can be changed and implemented as follows. The present embodiment and the following modified examples can be implemented in combination with each other within a range not technically contradictory.

-The photoelectric sensor 11 may be formed including the emitter 14, the light receiver 15, and the controller 24. In this case, the controller 24 may be provided with the control unit 20.

-The setting screen 40 may be displayed by a program stored in an external terminal.

Information indicating a correspondence relationship between a plurality of auxiliary output terminals 30 and each digit of a binary number indicating a light-receiving level may be displayed other than the setting screen 40. For example, when the setting screen 40 is displayed on an external terminal, information indicating a correspondence relationship between the auxiliary output terminal 30 and each digit of a binary number may be displayed on the display unit 16.

-The detection unit may be provided separately from the control unit 20.

-The setting unit may be provided separately from the control unit 20.

-The conversion unit may be provided separately from the control unit 20.

-The conversion unit may be provided separately from the control unit 20.

The light-receiving level displayed on the display unit 16 may be displayed by a digital indicator or by a plurality of lamps.

-The display unit 16 does not need to display the light-receiving level. Since the light-receiving level is output from the auxiliary output terminal 30, the light-receiving level can be checked even if the display unit 16 is not displayed.

-The photoelectric sensor 11 does not need to be provided with the display unit 16.

In addition, this application is based on the Japanese patent application (Japanese Patent Application No. 2018-066797) for which it applied on March 30, 2018, The content is taken in as a reference during this application.

11... Photoelectric sensor (multi-optical axis photoelectric sensor), 12... Transmitter, 13... Light receiving unit, 14... Emitter, 15... Receiver, 20... Control unit (detection unit), 27... Output terminal, 30… Auxiliary output terminal, 31... 1st auxiliary output terminal, 32... Second auxiliary output terminal, 33... 3rd auxiliary output terminal.

Claims (6)

A light-transmitting part
A light receiving unit that receives light,
A plurality of auxiliary output terminals capable of outputting high-level or low-level signals to the outside;
A control unit for controlling the light transmitting unit and the light receiving unit to output set output information through the auxiliary output terminal,
The control unit converts the received light amount into a light reception level divided into three or more steps by comparing the received light amount received by the light receiving unit with a plurality of threshold values, and outputs the light reception level in binary through the plurality of auxiliary output terminals. , Photoelectric sensor. The method according to claim 1,
The control unit outputs information indicating a correspondence relationship between the plurality of auxiliary output terminals to which the light reception level is output, and each digit of a binary number indicating the light reception level. The method according to claim 1 or 2,
The control unit, among the plurality of auxiliary output terminals, outputs the light reception level through the auxiliary output terminal different from the auxiliary output terminal configured to output the output information different from the light reception level. The method of claim 3,
The control unit, when setting to output the light-receiving level through the auxiliary output terminal, when the number of the auxiliary output terminals for which the output information is not set is insufficient, the auxiliary output terminal required to output the light-receiving level A photoelectric sensor that signals that the number is insufficient. The method according to any one of claims 1 to 4,
A light transmitting device having the light transmitting part and a light receiving device having the light receiving part,
The light receiver has an output terminal capable of outputting a control signal,
The auxiliary output terminal is installed in the light emitter, photoelectric sensor. A plurality of light-transmitting portions to emit light
A plurality of light receiving units to receive light,
A detection unit that performs detection based on a comparison of the amount of light received by the light receiving unit and a threshold value;
An output terminal capable of outputting a detection result of the detection unit,
A plurality of auxiliary output terminals capable of outputting high-level or low-level signals according to the set conditions,
In the multi-optical axis photoelectric sensor comprising a control unit for controlling the light transmitting unit and the light receiving unit to output set output information through the auxiliary output terminal,
The control unit detects a detection margin divided into three or more steps by comparing a received amount of light received by the light receiving unit with a plurality of threshold values, and outputs the detection margin in binary through a plurality of the auxiliary output terminals, Multi-beam photoelectric sensor.

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