• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to an automatic door sensor (10, 30) for monitoring a detection area comprising a first detection unit (12, 34a, b, c, d) and a second detection unit (14, 36a, b, c , d) for detecting an object within the detection zone, to which is connected an internal control unit (24, 44). The sensor further comprises a first output port (18, 38a, b, c, d) dedicated to the output of the signal associated with the first detection unit (12, 34a, b, c, d), and a second port output signal (20, 39a, c, d) dedicated to the output of the signal associated with the second detection unit (14, 36a, b, c, d), and an input port (16, 40a, b) which is connected to the internal control unit (24); the sensor further comprises configuration means (22, 32a, b, c, d) which allows the configuration of at least two alternative transmission modes.
    公开号:BE1023563A9
    申请号:E20155816
    申请日:2015-12-11
    公开日:2017-05-10
    发明作者:Laurent Sarlette;Théodoros Campas;Emmanuel Eubelen
    申请人:Bea Sa;
    IPC主号:
    专利说明:

    The invention relates to a sensor for automatic doors according to claim 1.
    It is known that a sensor for an automatic door monitoring a detection zone comprises a first detection unit, in particular for motion detection, and a second detection unit, in particular for detecting the presence of an object to be detected. inside a detection zone.
    Gate sensors known in the state of the art comprise an internal control unit, to which a first detection unit and a second detection unit are connected.
    The sensor further comprises a first output dedicated to the output of the signal associated with the first detection unit which is connected to the internal control unit, and a second output dedicated to the output of the signal associated with the second detection unit, and a digital input port adapted to receive a digital input signal which is connected to the internal control unit.
    According to a first mode, - single bit message output mode -, an output signal is outputted on the first output port, the output signal being either a source signal of the first detection unit, or a signal which is created on the basis of an input signal received via the digital input and the source signal supplied by the first detection unit. According to this first mode, an output signal is outputted to the second output port, the output signal being either a source signal of the second detection unit, or a signal that is created based on a signal of the second output unit. input received via the digital input and the source signal supplied by the second detection unit. In this mode, each output provides a "single bit message," meaning that information about a detection state (detecting / not detecting) of only one detection unit is provided continuously. This information may in particular be applied by a conventional output port, for example an electronic switch, a semiconductor relay or a current or voltage source.
    The output ports are intended to be connected to an external gate control unit to control the gate with respect to the detected signals. Such conventional external gate controllers accept a single bit message on their respective input ports.
    For this reason, the wiring of a sensor is rather difficult because it is necessary to have a line for each detection unit.
    It is an object of the invention to improve the wiring conditions for a door sensor which comprises at least two sensor units.
    According to the invention, a known sensor as described above, further comprises a configuration means which allows a configuration of the sensor in at least two alternative transmission modes, where except for the output mode of "single bit message" at least one second mode, "multi-bit message output mode", may be selected. A "multi-bit message" has a certain message duration / a predefined message duration, a digital signal, so states alternating between 0 and 1 are transmitted. A transmission mode combines a certain input mode and a certain output mode.
    The configuration means may be implemented in the form of a software component allowing the internal control unit to switch between states of different configuration.
    The configuration means may also be implemented in the form of a mechanical switch, such as a DIP switch.
    According to another embodiment, the configuration means may be implemented in the form of contacts which are connected by a wire.
    In the "multi-bit message output mode", a combined output signal is created based on a source signal that is provided by the first detection unit and the source signal that is provided by the second detection unit. . The "multibit message" contains detection state information (detecting / not detecting) of at least two detection units of at least one sensor. This combined information signal is output to the first and / or second output port.
    The sensor can also provide different input modes. There is, for example, an "input mode without message", a "single bit message input mode" and a "multi-bit message input mode". The sensor can be set in combined transmission modes, for example, "multi-bit message input" and "multi-bit message output".
    According to such a transmission mode, a signal may also be a combined signal which is created on the basis of the digital input signal containing a "multi-bit message" and the source signal which is provided by the first detection unit and the The source signal supplied by the second detection unit is output as a "multi-bit message" on the first and / or second output port.
    According to this concept, the status information (detecting / not detecting) of the two detection units can be transmitted via a single output port. By connecting the output port to a next input port of a sensor, a signal referring to at least two detection units can be transferred as a "multi - bit message" via a single physical line.
    The signal can be transmitted as serial data. By disposing a configuration means for switching between these two modes of "multi-bit message" and "single bit message" communication, the sensor can be easily adjusted to single sensor applications, in which a single The sensor is connected to an external gate controller, or a multiple sensor application, in which the sensors are connected in series and communicate via serial communication through the same port as in the single sensor application.
    The input port, which is conventionally used for monitoring purposes, namely to trigger a test output in a "single bit message input" mode, may be configured to accept a "bit message". multiple ", in particular serial data. This data can be taken into account by providing an output signal based on the first detection unit and the second detection unit. According to this transmission mode, the serial data can be transferred using conventional single bit message ports.
    In another advantageous embodiment, the configuration means are able to switch to another transmission mode, "decoding mode", in which the digital input signal contains a "multi-bit message" signal. The digital input signal, which is received via the digital input port, is decoded and outputted to the corresponding first and second outputs as a signal containing a "single bit message".
    The input signal containing the detection status information of two previous sensor detection units connected in series can be retrieved by the internal control unit. This data can be resolved and a "single bit message" can be applied to the output ports of a last one of multiple sensors connected in series to communicate with the external gate controller in a conventional manner. In this case, the sensors connected in series are seen as a single sensor by the external gate controller.
    Usually, it is defined that, if at least one sensor of the series connected sensors detects an object with a detection unit, a detection signal is communicated to the external gate controller.
    The serial data may include a frame having certain values (eg, bits), each value being dedicated to a detection unit. There may be a defined value for a frame that is associated with the detection state of the detection unit, ie "1" if the detection unit detects an object and "0" if the detection unit does not detect an object.
    By connecting the active output port to an input port of a next sensor, the serial data can be transferred in such a way that the values for the respective sensor units are updated by each sensor. This means that if a sensor receives a frame in which the value of a first detection unit is set to "0" by a previous sensor, the control unit may change this value to "1" if the first detection unit the sensor analyzing the data detects an object. A modified "multi-bit message" can then be transferred to the next sensor.
    According to another advantageous embodiment, the first detection unit and the second detection unit are implemented either for motion detection or for presence detection, or the first detection unit is implemented in the form of a presence detection unit and the second detection unit is implemented as a motion detection unit. A sensor according to the invention may also comprise more than two detection units. The data is then adjusted accordingly. The detection unit may, for example, be a microwave detector, a laser detector.
    The outputs of the sensor can be implemented in the form of a semiconductor relay or an electronic switch, in particular an optoMOS, an optocoupler, an open collector transistor, in particular an eMOSFET type transistor.
    The problem of using a switch conventionally providing a "single bit message" is that the switches are enhanced to meet the requirements of providing a "single bit message". Very good properties are known for opto-isolated components such as an optocoupler, an optoMOS.
    According to the invention, it has been found by the inventors that the optoelectronic switches can vary very greatly with respect to timing conditions. For example, there are manufacturing tolerances or distortions induced by changes in temperature. To apply a "multi - bit message" to a system using optoelectronic switches, a reference signal is used, which is stored in the internal control unit of the sensor.
    According to another aspect of the invention, in a "multi-bit message" mode, a calibration signal is provided. To enable analysis of the received corrupted message signal, a calibration signal is sent in advance of the message signal. The received calibration signal is compared with the stored reference signal. From this comparison, the different parameters are evaluated and can then be taken into account by the appropriate resolution of the next message signal. The advantage of using a calibration frame is that the overall distortion effects can be taken into account, namely the distortion effects of the output switch encoding the "multibit message" as well as distortion effects. appearing by receiving the "multi-bit message" on the input port.
    Preferably, the reference signal as well as the calibration signal are square signals. By using a square signal, the significant rise and fall times of the switch can be easily evaluated since they depend solely on a single parameter.
    According to the invention, the same type of sensor can be used in a single sensor application or in a serial type application. For example, within a serial connection of three sensors, a first sensor can be set in a configuration state, - generation state -, in which the sensor can output a communication frame on the first output on the basis of the source signals of the first detection unit and the second detection unit.
    The second sensor is connected in series with the first sensor by connecting the input port of the second sensor to the first output port of the first sensor. The second sensor then receives coded data containing information from the first and second sensor units of the first sensor. The second sensor is set in a second configuration state, - sending state -. In this state, the sensor may receive a signal containing multi-bit information and update the data with respect to the source signal received by the first and second detection units and output the updated data signal to the first and second detection units. exit port.
    A third sensor can be connected in series to the second sensor by connecting the first output of the second sensor to the input port of the third sensor. The third sensor can be set in a third configuration state, - decoding state -. In the decoding state, the third sensor receives a multi - bit data signal through its input port, containing the combined information of the first and second sensor units of the first and second sensors. The internal control unit can decode this information and update it with respect to its own first and second sensor units. In - the decoding state -, the sensor outputs a single bit signal on the first output based on the updated information with respect to the first detection unit for all three sensors, and a signal single bit on the second output port based on updated information of the second detection units of all three sensors. The first and second output ports of the third sensor may be connected to an external gate controller. The three sensors appear as a single sensor for the external door control unit.
    The cabling can simply be realized by a single physical line, since all the information of all the detection units can be transmitted in the form of serial data by a serial protocol using the conventional single bit outputs dedicated to a certain detection unit. Other potential advantages, features, and applications of the present invention may be derived from the following description, taken in conjunction with the embodiments illustrated in the drawings.
    Throughout the description, the claims and the drawings, these terms and associated reference signs will be used as defined in the attached list of reference signs. On the drawings are represented:
    Figure 1 is a schematic view of a sensor according to the invention in a single bit message transmission mode;
    Figure 2 is a schematic view of a sensor according to the invention in a multi-bit message output transmission mode;
    Figure 3 is a schematic view of a sensor according to the invention in a multibit message input decoding / single bit message output decoding mode;
    Figure 4 a schematic view of three sensors according to the invention in a series chain installation;
    Figure 5 is a schematic view of a single sensor application.
    Figure 1 shows a schematic view of a sensor 10. The sensor 10 includes a motion detection unit 12 and a presence detection unit 14. The motion detection unit 12 and the presence detection unit 14 are able to detect an object within their surveillance zone. The motion detection unit 12 and the presence detection unit 14 output a signal containing a message indicating that an object has been detected or not. The message is marked for example "1" if an object is detected by the presence detection unit 14, but no movement is detected, so the message associated with the motion detection unit 12 is marked 0 .
    The sensor 10 comprises an input port 16 for receiving an input signal, and at least two output ports 18, 20, each output port being assigned to the output of either the motion detection message or the output message. presence detection. In addition, the sensor includes a configuration means 22 for selecting a certain transmission mode. According to Figure 1, the configuration means 22 is implemented as a DIP switch having three switching states. The sensor 10 according to Figure 1 is set in a single bit message transmission mode. This means that the internal control unit 24 is set to a single bit message input, which could be a monitoring test signal, to trigger the current output of the current sensor detection states. The input message is marked 1. By using the single bit message transmission mode, the internal control unit is set to output a single bit message on each output 18, 20. According to the Figure 1, the first output port 18 is set to output the detection state information according to the detection state of the motion detection unit 12 and, therefore, the single bit message outputted is also marked 0. The second output port 20 is set to a single bit message according to the detection state of the presence detection unit 14 and the output message is marked 1.
    This single bit message transmission mode is used for single sensor applications, in which a single sensor is connected to a conventional external gate controller.
    Figure 2 shows a schematic view of a sensor 10 set in a multi-bit message / no message message output transmission mode. The sensor 10 has the same detection units 12, 14, input port 16 and output ports 18, 20 and the configuration means 22 and the internal configuration unit 24 are the same as those described in FIG. In contrast to Figure 1, the DIP switch 22 is set in a multi-bit message / no message message output transmission mode. In this mode, the information associated with the detection state of the presence detection unit 14 and the motion detection unit 12 are combined in a multi bit message that is output to the first port of output 18. The multi-bit message is tagged with the 1-0 bit sequence. The first bit of the message represents the presence detection state and the second bit represents the motion detection state. The message may contain additional information in the form of a header or the like in the serial protocol style, for example.
    Figure 3 shows a schematic view of a sensor 10 according to the invention in a multi-bit message input / single bit message output mode. The sensor 10 has the same detection units 12, 14, the input port 16 and the output ports 18, 20 and the configuration means 22 and the internal configuration unit 24 are the same as those described in FIG. 1.
    According to Figure 3, the DIP switch is set in a third mode, which is a multi-bit message input / single bit message output mode. In this mode, the internal control unit is set to evaluate a multiple bit message received through the input port 16. This message may be sent through an output by a previous sensor 10, that is, Figure 2.
    This signal is solved by the internal control unit 24 according to a predefined protocol. The internal control unit 24 knows that the first message bit is associated with the presence detection unit and that the second bit is associated with the motion detection unit of a previous sensor 10. internal control compares the received message bits with the detection state information of the motion detection unit 14 and the presence detection unit 12 connected to the internal control unit 24. It adjusts the output 18 corresponding to the presence detection unit 12 to a single bit message which is a result of a logic or comparison of the received detection state and the detection state measured by the presence detection unit 12 This also applies to the motion detection unit 14 and its corresponding output 20.
    In this transmission mode, a multi-bit message can be resolved and allows communication of multiple sensors to communicate with an external gate controller having a single bit message entry. By the arrangement of such a configurable sensor in the three transmission modes explained, a connection of two sensors in series is possible.
    An advanced function of a sensor having four modes of transmission is explained in more detail in Figure 4, in which a series string of three sensors is shown.
    Figure 4 shows a series chain arrangement of three identical sensors 30a, 30b, 30c in different modes, represented by the position of the black dot within the configuration means 32a, 32b, 32c. The sensors 30a, 30b, 30c are connected in series with each other, the first sensor 30a and the last sensor 30c of the chain being connected to an external gate control unit 50. The first sensor 30a is set in a control mode. single-bit message / multi-bit message output entry. Upon receiving a single bit message from the gate controller via its input port 40a, it outputs the detection state of the detection units 34a, 36a as a multibit message on the first port 38a. The second output port 39a is not connected. The manner in which this output is generated by the internal control unit 44a has already been explained in FIG. 2. Such a multi-bit message (0-0) is then transferred to the input port 40b of the next sensor 30b. The multi-bit message is updated with respect to the detection state of the detection units 34b, 36b by a logical "OR" comparison. An updated multi-bit message (1-0) is then transferred via the output port 38b of the second sensor 30b. This signal is then received by a third sensor 30c which is set in a single bit message output / single bit message output mode. As already described in FIG. 3, the multi-bit signal is decoded by the internal control unit and compared with the detection state of the detection units 34c, 36c, and outputted as a message to the control unit. single bit, the presence detection being assigned to the first output port 38c and the motion detection output being assigned to the second output 39c. The outputs, outputting a single bit message, are connected to the inputs of a gate control unit 50. In view of the conventional gate control unit 50, the series string arrangement appears as of a single sensor.
    Figure 5 shows a sensor 30d in a single sensor application, in which the configuration means 32d is set in a single bit message transmission mode as described in Figure 1. A conventional external door controller 52 is operated and connected accordingly. A single bit message, based on the detection state of the first detection unit 34d and the second detection unit 36d, is transmitted to the external gate controller 52 via the first output port 38d and the second output port 38d. output port 39d.
    According to the invention, the same type of sensor can be used easily in a single sensor application as well as in a multiple sensor application only by adjusting the modes of operation, using only a connecting wire.
    List of reference signs 10 sensor 12 motion detection unit 14 presence detection unit 16 input port 18 first output port 20 second output port 22 configuration means 24 internal control unit 30a, b, c, d sensor 32a, b, c, d configuration means 34a, b, c, d motion detection unit 36a, b, c, d presence detection unit 38a, b, c, d first output port 39a, c, d second output port 40a, b input port 44a internal control unit 50 external control unit 52 external control unit
    权利要求:
    Claims (14)
    [1]
    A sensor (10, 30) for an automatic door monitoring a detection zone comprising: a first detection unit (12, 34a, b, c, d) and a second detection unit (14, 36a, b, c, d ) for detecting an object within the detection zone, an internal control unit (24, 44), to which the first detection unit (12, 34a, b, c, d) and the second detection unit (14, 36a, b, c, d) are connected, the sensor further comprises: a first output port (18, 38a, b, c, d) dedicated to the output of the signal associated with the first detection unit ( 12, 34a, b, c, d) which is connected to the internal control unit (24, 44a), and a second output port (20, 39a, c, d) dedicated to the output of the signal associated with the second detection unit (14, 36a, b, c, d) which is connected to the internal control unit (24, 44a), and an input port (16, 40a, b) which is connected to the internal control unit (24); the sensor further comprises: configuration means (22, 32a, b, c, d) which allows the configuration of at least two alternative transmission modes, according to a first transmission mode a first output mode being set in which a signal based on the source signal supplied by the first detection unit (12, 34a, b, c, d) is outputted to the first output port (18, 38a, b, c, d) and / or a signal based on the source signal supplied by the second detection unit (14, 36a, b, c, d) is outputted to the second output port (20, 39a, c, d), and in a second mode a second output mode being set in which a combined output signal is created based on: - the source signal supplied by the first detection unit (12, 34a, b, c, d) and - of the source signal provided by the second detection unit (14, 36a, b, c, d) and outputted to the first output port (18, 38a, b, c, d) and / or the second output port (20, 39a, c D).
    [2]
    2 - Sensor according to claim 1, characterized in that the configuration means (22, 32a, b, c, d) is adapted to select a transmission mode in which an output signal is created according to the signal of input received via the input port (16, 40a, b) and sent to the first output port (18, 38a, b, c, d) and / or the second output port (20, 39a, c d).
    [3]
    3 - Sensor according to claim 1 or 2, characterized in that the configuration means (22, 32a, b, c, d) is implemented in the form of a switch, for example a DIP switch.
    [4]
    4 - Sensor according to claim 1 or 2, characterized in that the configuration means (22, 32a, b, c, d) is implemented in the form of software on the internal control unit (24). , 44a).
    [5]
    5 - Sensor according to one of the preceding claims, characterized in that the configuration means (22, 32a, b, c, d) is adapted to select a transmission mode set to an input mode in which the signal input is a combined signal and the signal is decoded in conjunction with first sensor unit information (12, 34a, b, c, d) and second sensor unit information (14, 36a, b, c, d).
    [6]
    6 - Sensor according to one of the preceding claims, characterized in that the configuration means (22, 32a, b, c, d) is adapted to select a transmission mode in which the output signal is created on the basis information about the source signal provided by the first detection unit (12, 34a, b, c, d) and the source signal supplied by the second detection unit (14, 36a, b, c, d) and information of the input signal.
    [7]
    7 - Sensor according to one of the preceding claims, characterized in that the combined signal uses a serial protocol.
    [8]
    8 - Sensor according to one of the preceding claims, characterized in that the first output port (18, 38a, b, c, d) and / or the second output port (20, 39 a, c, d) includes a solid state relay.
    [9]
    9 - Sensor according to one of the preceding claims, characterized in that the first output port (18, 38a, b, c, d) and / or the second output port (20, 39a, c, d) comprises an electronic switch.
    [10]
    10 - Sensor according to claim 9, characterized in that the first output port (18, 38a, b, c, d) comprises an optoMos.
    [11]
    11 - Sensor assembly comprising at least a first sensor and a second sensor according to one of the preceding claims, wherein the input port (16, 40 a, b) of a second sensor is connected to the first output port ( 18, 38a, b, c, d) or the second output port (20, 39a, c, d) of the first preceding sensor.
    [12]
    Sensor assembly according to Claim 11, characterized in that the first sensor is set in the second input mode in which the combined signal is output to the first output port (18, 38a, b, c, d) and the second sensor is set in the first output mode.
    [13]
    13 - Sensor assembly according to one of the preceding claims 11 and 12, characterized in that the first detection unit (12, 34a, b, c, d) and / or the second detection unit (14, 36a, b , c, d) is implemented as a presence detection unit (14, 36a, b, c, d).
    [14]
    14 - Sensor assembly according to one of the preceding claims 11 to 13, characterized in that the first detection unit (12, 34a, b, c, d) and / or the second detection unit (14, 36a, b , c, d) is implemented as a motion detection unit (12, 34a, b, c, d).
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    同族专利:
    公开号 | 公开日
    BE1023563A1|2017-05-04|
    EP3032019A1|2016-06-15|
    BE1023563B1|2017-05-04|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE4344729C2|1993-12-27|1996-05-09|Siemens Ag|Control and / or regulation of a door|
    DE29513962U1|1995-08-31|1995-10-19|Feig Electronic Gmbh|Control device for power operated doors, gates and barriers|
    ES2572772T3|2005-01-21|2016-06-02|Bea S.A.|Sensor for use in automatic doors|
    DE202009000683U1|2009-01-16|2010-06-10|Feig Electronic Gmbh|Gate control system for a gate|
    JP5747067B2|2013-11-11|2015-07-08|株式会社ソリック|Automatic door control system|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    EP14197722.3|2014-12-12|
    EP14197722.3A|EP3032019A1|2014-12-12|2014-12-12|Sensor for object detection for automatic doors|
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