Abstract: In a projector or an optical receiver, a master device produces pieces of definition information that determines timings of detection processes in the device including its own device and transmits the pieces of definition information to the slave device. The master device simultaneously transmits commands to require operations of internal timers to be synchronized with each other to the other slave devices in response to elapse of a time corresponding to a period in which a circulating period of the detection processes of the sensors proceeds by a predetermined cycle. Each of the slave devices corrects the timer in response to the command, and determines a timing at which a detection process should be performed with reference to a time point for correction on the basis of the definition information matched with its own device to execute the detection process.

Abstract: A sensor apparatus includes multiple pairs that each include a light emitting element and a light receiving element configured to receive light emitted from the light emitting element, and, in response to optical axes formed in a region between the light emitting elements and the light receiving elements entering a blocked state, senses a sensing target moving in the region. In an initial state, sensing is performed using a sensing optical axis composed of a portion of the optical axes, and when an optical axis of the sensing optical axis used in sensing in the initial state is blocked, the number of optical axes included in the sensing optical axis is increased so as to expand the sensing optical axis.

Abstract: For a manufacturing machine that moves in and out of a detection area of a multi-optical axis photoelectric sensor, floating blanking and blanking monitoring are activated without outputting a stop signal to stop the manufacturing machine every when the manufacturing machine moves out of the detection area. A detection processing unit performs, when at least one of the plurality of optical axes is constantly interrupted by the object, floating blanking of outputting the detection signal upon determining that the number of optical axes in an interrupted state is greater than a preset maximum optical axis number, and blanking monitoring of outputting the detection signal upon determining that the number of optical axes in an interrupted state is smaller than a preset minimum optical axis number, and activates or deactivates the floating blanking and the blanking monitoring based on the signals received by the signal reception unit.

Abstract: A detection processing unit determines, in a detection area including optical axes formed between emitter elements and receiver elements, whether each optical axis is in an interrupted state after optical axis selection corresponding to one scan, and outputs a detection signal based on the determination result. When at least one of the optical axes is constantly interrupted by an object movable within the detection area, the detection processing unit outputs the detection signal upon determining that the number of optical axes in an interrupted state is greater than a preset maximum optical axis number, and also outputs the detection signal upon determining that the number of optical axes in an interrupted state is smaller than a preset minimum optical axis number.

Abstract: Provided is a multi-axis photoelectric sensor that outputs a high-level signal while a detection area is not shielded and stops the signal output when the detection area is shielded, wherein a sequence of a change in a non-shielded state and in a shielded state of the detection area formed by optical axes and inputs from muting sensors are divided into a plurality of stages for monitoring, and muting processing is executed when the stages progress normally. When an abnormality in the sequence is detected in a stage being monitored, indicator lights are blinked by a number of times corresponding to the stage in which the abnormality has been detected, to provide a notification of a stage in which the abnormality has been detected.

Abstract: A multiple optical axis photoelectric sensor capable of performing muting processing adapted to a plurality of kinds of workpieces having different heights without the need for complicated pre-setting according to the kinds of workpieces, is provided. The multiple optical axis photoelectric sensor is provided with a light projecting device and a light receiving device, which forms a plurality of optical axes together with the light projecting device. In at least one portion of a detection area, which is set according to the optical axes, a muting area for nullifying the result of detection of blocked light is set up. A sensor system acquires a range of blocked light corresponding to the blocked optical axis during passage of a workpiece, and alters the muting area of the multiple optical axis photoelectric sensor from a first range to a second range.

Abstract: A start-up time of a production facility is shortened while generation of a muting error is suppressed, whereby productivity is improved. A multiple-optical-axis photoelectric sensor system includes a projector, an optical receiver, a light blocking determination unit configured to make a light blocking determination whether each of optical axes formed between the projector and the optical receiver is in a light blocking state, and a muting processor configured to temporarily disable the light blocking determination on condition that a detection signal input from an external muting instrument changes according to a predetermined sequence. The muting processor determines the sequence of the detection signal from the muting instrument during the muting by dividing the sequence into a plurality stages. The muting processor accumulates and analyzes measurement information acquired in each stage, and decides an optimum setting value for a muting operation condition based on an analysis result.

Abstract: In a projector or an optical receiver, a master device produces pieces of definition information that determines timings of detection processes in the device including its own device and transmits the pieces of definition information to the slave device. The master device simultaneously transmits commands to require operations of internal timers to be synchronized with each other to the other slave devices in response to elapse of a time corresponding to a period in which a circulating period of the detection processes of the sensors proceeds by a predetermined cycle. Each of the slave devices corrects the timer in response to the command, and determines a timing at which a detection process should be performed with reference to a time point for correction on the basis of the definition information matched with its own device to execute the detection process.

Abstract: Provided is a multi-axis photoelectric sensor (S) that outputs a high-level signal while a detection area is not shielded and stops the signal output when the detection area is shielded, wherein a sequence of a change in a non-shielded state/shielded state of the detection area formed by optical axes and in inputs from muting sensors (A1, B1, A2, B2) is divided into a plurality of stages for monitoring, and muting processing is executed on a condition that the stages progress normally. When an abnormality in the sequence is detected in a stage being monitored, indicator lights (10, 20) are blinked by the number of times corresponding to the stage in which the abnormality has been detected, to make notification of the type of the stage in which the abnormality has been detected.

Abstract: A process circuit sets a plurality of light emitting elements in a state in which light is not emitted through a process circuit, and receives a signal S1 corresponding to received ambient light from each of a plurality of light receiving elements. The process circuit generates light receiving information (data DT) showing the light receiving state of the ambient light with respect to each predetermined number of light receiving elements among the plurality of light receiving elements. The process circuit transmits the data DT to the outside. The personal computer receives the data DT through a communication unit and displays it. In a sensor SNS, the amount of light received can be displayed with respect to each optical axis by the personal computer. Thus, an operator can find the light receiving state of the ambient light in more detail than the conventional sensor.

Abstract: A process circuit sets a plurality of light emitting elements in a state in which light is not emitted through a process circuit, and receives a signal S1 corresponding to received ambient light from each of a plurality of light receiving elements. The process circuit generates light receiving information (data DT) showing the light receiving state of the ambient light with respect to each predetermined number of light receiving elements among the plurality of light receiving elements. The process circuit transmits the data DT to the outside. The personal computer receives the data DT through a communication unit and displays it. In a sensor SNS, the amount of light received can be displayed with respect to each optical axis by the personal computer. Thus, an operator can find the light receiving state of the ambient light in more detail than the conventional sensor.