DE29817816U1 - Device for operating motion detectors - Google Patents

Description

PB 2088/GM 02 October 1998

Applicant: INSTA ELEKTRO GMBH & CO. KG 58511 Lüdenscheid

Device for operating motion detectors

The present invention relates to a device for operating one or more motion detectors according to the preamble of claim 1.

Motion detectors are mainly used in electrical installation technology to switch on one or more light sources when movement is detected and the brightness falls below a brightness that is usually adjustable and measured by the device. This threshold is often referred to as the twilight threshold. Motion detectors with different principles are known for this purpose. In addition to the passive infrared motion detectors that are mainly used, there are also those whose sensors are based on ultrasound, radar or measuring electrical capacity. Combined sensors are also possible, whereby the sensor signals are evaluated using various, sometimes very extensive algorithms. After switching on, the motion detector remains switched on for a fixed or adjustable period of time, known as the run-on time. In the meantime, with most device types, the run-on time is restarted with each further movement detected. Motion detectors for lighting control generally only evaluate the motion signal once they have switched on the lighting and ignore the brightness signal, since the lighting is often above the set twilight threshold due to the light being switched on. Fig. 1 shows a block diagram of a state-of-the-art motion detector with a load switch LS, a power supply SV, an evaluation unit AE, optional adjusters ES and the sensor system SE, whereby this sensor system consists of at least one motion sensor and at least one brightness sensor.

Motion detectors have very different detection fields due to different requirements. It often happens that the desired detection area cannot be covered by a single motion detector. One example is the lighting of a long garden path. Several detectors are used to detect motion. If movement is detected and there is insufficient daylight, the entire path should then be illuminated. At first glance, it makes sense in such cases to connect the power outputs of the motion detectors in parallel. The control of the lighting is referred to as a load switch here; this can be done, for example, with a relay or an electronic switch that contains at least one bipolar transistor, TRIAC, MOSFET or IGBT. However, parallel connection has a serious disadvantage: As soon as the first motion detector switches on the lighting, the brightness of the other motion detector(s) can also be set to a level that is above the respective twilight threshold. This means that the load is not switched on when movement is detected. If the first motion detector no longer detects a motion signal and the follow-up time has expired, the lighting is switched off. The darkness that now arises causes one of the other motion detectors to switch the light back on when the brightness threshold is exceeded and movement is detected at the same time. The lighting that goes out briefly is usually perceived as disturbing and possibly dangerous. The following methods are currently known to enable uninterrupted lighting:

A first device is assumed to consist of a number of motion detectors, which is referred to here as M. Each of the motion detectors 1 to M outputs a separate signal for movement, here called "movement", and light intensity, here called "LUX". The signal to switch on the lighting is formed from the signals of all motion detectors in a central power unit using the logical operations AND and OR:
Output signal = (Bewl OR Bew2 ... OR BewM) AND LUXm, where m can be selected from 1...M.

The disadvantage of this system is that a central power unit must be used and that the wiring between the power unit and the motion sensors is done with a telecommunications cable. Such cables are unusual in the electrical installation industry, and the connection is somewhat more complicated than the usual cables for the 230 V supply. The process is used by various installation technology manufacturers. For example, the following products from GIRA Giersiepen GmbH & Co. KG, Postfach 1220, 42461 Radevormwald can be used for this process: System sensor 180/16, no. 84002, catalog 1998, page 176. System power unit no. 84902, ibid.

A second device is known, in which one device forms the main station (Hst) and is the only device that evaluates the illuminance. Other devices are referred to as active extensions (Nst). When movement is detected, the extension switches a signal to the extension line, which is evaluated by the main station: Output signal = (BewHst OR BewNstl ... OR BewNstN) AND LuxHst.
Here, BewNst means movement detected by the extension, LuxHst means the brightness falls below a threshold value at the main unit. With this device, it is possible to differentiate the extension signal due to coding at mains potential. With extension signals from motion detectors, the lighting is only switched on if the brightness falls below the threshold value at the main unit. If the phase potential is applied to the extension line from a normal button, this always switches the lighting on, as the person pressing it wants additional lighting. As soon as the run-on time has elapsed, the lighting is switched off again. As long as movement is detected by one of the connected motion detectors, the run-on time is started again. The disadvantage of this method is the variety of devices, as there must be main units and extension units with different functions. For example, the following products from GIRA Giersiepen GmbH & Co. KG, Postfach 1220, 42461 Radevormwald can be used for this process: Automatic switch insert with relay contact no. 83500, catalog 1998, page 171; Automatic switch comfort attachment no. 83316, catalog 1998, page 173; Automatic switch extension insert no. 84600, catalog 1998, page 171; Automatic switch system attachment no. 84216, catalog 1998, page 174.

A third device is known, whereby each motion detector has equal rights and can evaluate the light intensity in addition to the motion signal. A central device serves as the power unit here. The motion detectors are connected in parallel to a two-wire line. This two-wire line serves firstly to supply the motion detectors, secondly to provide feedback of the switching signal and thirdly to signal the motion detection to the central power unit. The necessary differentiation of the operating modes is achieved by half-wave coding of the two-wire line. This device is advantageously used for automatic staircase lighting. The disadvantage of this system is that a central power unit must be used and the number of motion detectors is limited. The following products from GIRA Giersiepen GmbH & Co. KG, Postfach 1220, 42461 Radevormwald can be used for this process:

Automatic switch REG Automat No. 82900, catalog 1998, page 172; Automatic switch Impulse insert No. 82500, catalog 1998, page 171; Automatic switch system attachment No. 84216, catalog 1998, page 174.

The patent application "Passive infrared motion detector with a button/opener", DE 196 25 719.0, describes a device in which a motion detector can be put into different operating states by interrupting the power supply. The advantage here is that the existing installation can be used for subsequent installation. The disadvantage is that the operating mode is reached by serial pressing and cannot be displayed.

Based on the state of the art, the invention is based on the task of improving the operation of motion detectors in such a way that this operation is enabled by one or more buttons and/or control elements and/or sensor/actuator combinations of the building system technology for selecting operating modes such as "alarm operating mode" or "permanent on" and feedback of operating modes and operating states such as "alarm message" without a central power unit with minimal installation effort and without disruptive dark phases.

This object is achieved with the features of claim 1. Further advantageous design features and embodiments of the invention are contained in the subclaims.

The invention will be explained and described in more detail using two exemplary embodiments according to Figures 2 to 3. It shows:

Fig. 1: a block diagram of a motion detector according to the state of the art;

Fig. 2: a first device with motion detectors, a button, a sensor/actuator combination and a load;

Fig. 3: a second device with motion detectors, a button, a control element, a sensor/actuator combination and a load.

Fig. 2 shows the connection of the components of the device designed according to the invention, in which the load line LL is used to signal the operating state of the device. This means that the installation effort is very low. A switching element designed for the current flowing through the load must be used as the button T. The same applies to the actuator of the sensor/actuator combination SAK. According to the invention, all connected motion detectors and the sensor/actuator combination detect the potential transition from zero potential N to phase potential L on the load line LL. It is irrelevant whether this transition is caused by pressing the button T, the sensor/actuator combination SAK or by switching on the load LAST by a motion detector 1 to M. The change in potential is evaluated by an evaluation unit AE that has been expanded according to the invention and causes all connected motion detectors to switch on the load for the set period of time and all connected motion detectors to subsequently ignore the brightness signal, so that each individual motion detector resets the set follow-up time when it detects further movement. When the last load switch LS of one of the motion detectors 1 to M is switched off, the load LAST is switched off.

According to the invention, the evaluation device AE in each motion detector 1 to M evaluates the potential transition from phase potential P to zero potential N on the load line LL in order to lock the evaluation units of all motion detectors 1 to M for a specified period of time. Otherwise, incorrect evaluations could occur during the switch-off process due to electrical interference on the lines or - if the sensors are passive infrared sensors - due to the cooling of switched-off lamps. The evaluation unit in each motion detector advantageously contains a microcontroller or an application-specific integrated circuit, also known as ASIC.

The device described in Figure 2 can be used, for example, with passive infrared motion detectors where there is a desire for a simple parallel connection of several detectors and/or for an external activation of the device independently of motion detection.

In the circuit of the second device designed according to the invention shown in Fig. 3, a separate, single-core extension line NL that is not galvanically isolated from the low-voltage network is used to control the device. The phase potential L serves as the reference potential for this extension line NL. The basic principle of the invention is that each motion detector of the device feeds a constant current into the extension line NL, whereby the voltage is limited to a maximum value of e.g. 42 V. With the help of a purely passive control device - in the simplest case this is a switching element with a series-connected Z-diode - the signal of the extension line NL can be set to a fixed voltage value greater than zero volts. The principle of current output and control by clamping to a certain voltage value is well known from the field of electronic ballasts as a 1 to 10 V control, but here with galvanic isolation from the network.

Through careful determination, different voltage values can be assigned to different control commands or status signals on the extension line NL. The principle applies that the voltage to which the extension line is set has a priority assigned to the voltage level and can be overridden by control commands or status signals with lower assigned voltage values. The control command with the highest priority is the voltage zero volts against phase, i.e. the direct connection of the extension line to phase potential L. This can be achieved, for example, with any commercially available installation button.

Starting from the idle state of the device according to Fig. 3, i.e. the lighting is switched off and there is no motion detection, the first motion detector that detects movement and at the same time a brightness value below the twilight threshold signals this by clamping the extension line to a specified, lower value than in the idle state. This signal is evaluated by all motion detectors 1 to M in the device and as a result the load switch LS is switched on by all motion detectors and only the motion signal is evaluated, but no longer the brightness signal. As soon as another motion detector detects movement, it in turn also clamps the voltage on the extension line to the same voltage value.

In devices according to Fig. 3, the evaluation of the extension line NL is carried out by all motion detectors 1 to M in the same way and simultaneously. It is therefore irrelevant whether the load LAST is switched by one, several or all motion detectors 1 to M. For this reason, the connection of motion detector M to the load line LL in

Fig. 3 shown in dashed lines. It is also possible to divide the total load LOAD between the load switches of several motion detectors and is recommended for distributed loads in order to keep the switch-on and operating currents of the load switches low. When allocating a partial load to each motion detector, it is therefore possible in principle to control motion detectors 1 to M differently. This different control can be done by programming each motion detector.

In devices according to Fig. 3, in which relays are used as load switches LS in motion detectors 1 to M, the relays can be provided with potential-free contacts. This allows the load to be distributed across two or all three phases of the low-voltage network. If a first phase is used to control the device and one or both other phases of the three-phase network are used for the load switching, the device can no longer be put out of operation by a short circuit of the load. This is particularly important if the device is also used to detect burglars and vandals.

In the device according to Fig. 3, phase potential L can be applied to the extension line NL using a button. All connected motion detectors 1 to M evaluate this signal. As long as the motion detectors in the device have not detected any movement (rest position), each motion detector is switched on and the corresponding run-on time is started by pressing a button. If, however, the load is switched on, all motion detectors are switched off by pressing button T. According to the invention, the evaluation device AE in each motion detector 1 to M evaluates this button press in order to lock the evaluation units of all motion detectors 1 to M for a specified period of time. Otherwise, incorrect evaluations could occur during the switch-off process due to electrical interference on the lines or - if the sensors are passive infrared sensors - due to the cooling down of switched-off lamps. After this time, the motion detectors are ready again, i.e. as soon as the lighting of one of the motion detectors 1 to M is below the twilight threshold and movement is detected, this motion detector switches the device back on. The button is therefore used to switch off the load if the twilight threshold is exceeded without the lighting switched on by the device and continuous retriggering, i.e. resetting of individual follow-up times, must be expected. With the device described, only a small current flows through the button.

In the simplest expansion stage of the device according to Figure 3, the following three operating modes exist: The first operating mode is the rest position, in which the extension line is clamped to the highest voltage, e.g. 42 V. The second operating mode is the active position described above with a lower fixed voltage to which the extension line NL is clamped. The third operating mode is the short circuit of the extension line against phase, e.g. by pressing a button. This simple expansion stage can be used, for example, when connecting presence detectors in order to achieve a simple option for switching them off when movement is constantly detected but artificial lighting is no longer required.

In this expansion stage, the coding of the extension line could also be carried out by half-wave coding, as is known in the prior art and was described as the third device in the prior art. According to the invention, however, the method described here offers possibilities for significantly expanding the functionality by introducing further operating modes, which can be used as further defined

Voltage values are shown on the extension line. Figure 3 shows a single control element BE, but according to the invention several control elements can also be connected in parallel. The control element BE is able to transmit control commands to the motion detectors 1 to M of the device by clamping the extension line NL to different voltage values. All motion detectors 1 to M of the device are able to evaluate these voltage values and thus, for example, set different operating modes. The motion detectors of the device can in turn report the set operating state back to the control unit or units by clamping the extension line to defined voltage levels that can be evaluated by the control elements. The process inevitably means that these feedback signals are assigned higher voltage values than the control commands of the control element BE.

An example of the described functional extension of the device according to Fig. 3, in which the fixed voltages U5 to Un can be generated in each motion detector 1 to M and the fixed voltages Uo to U4 can be generated in each control element BE to clamp the extension line NL, is listed in the following table, without going into the technical implementation of the individual operating modes in every case:

1) Uo= OV ¹ ^ Control command from button T or control element BE to switch on or off.

Switching off and switching to standard operation (highest priority) Control command for switching to "Permanently On" mode
Control command for switching to "Permanently Off" operating mode
Control command for switching to "presence simulation" operating mode Control command for switching to "alarm mode" operating mode
Status message of the operating mode "Permanently On"
Status message of the operating mode "Permanently Off"
Status message of the operating mode "presence simulation"
Status message of the operating mode "alarm mode", alarm triggered

Status message of the operating mode "alarm mode", no alarm triggered Status message switched load in standard operation
Status message idle state in standard operation (lowest priority)

The first method described with reference to Figure 2 and the second method described with reference to Figure 3 can be combined. This means that the switch-on state of the parallel-connected load circuit outputs is evaluated using the signal on the load line LL, while the other status messages are evaluated according to the second method independently of the state of the load line LL.

In the setup according to Figure 3, a four-way multifunction pushbutton sensor known from building system technology or an eight-way multifunction pushbutton sensor in conjunction with an application-specific insert can be used as a control element BE with several buttons and LEDs for optical feedback.

When the operating modes are reported back, a sufficiently high electrical power is dropped on the control element BE to be able to supply the circuit of the control element. The short-term collapse of the operating voltage of the control element BE due to the operation of the control element BE or a button T can be prevented by means of a suitable capacitor or accumulator. The control element requires

2) Ui > U ₀ 3)U ₂ >Ui 4) _U3 > _U2 5) _U4 > _U3 6) _U5 > _U4 7) _U6 > _U5 8) _U7 > _U6 9) _U8 > _U7 10) _U9 > _U8 ll)Uio>U ₉ 12) U _n > U ₁₀

Self-supply does not necessarily require the connection of the neutral conductor N. The number of control elements that can be connected in parallel in this way is determined by the constant current supplied by the motion detectors 1 to M and the power consumption of the control elements BE.

The "Alarm mode" operating mode is listed in the table above. In contrast to the standard operating mode, in which lighting is to be switched on for the convenience of the user, in the "Alarm mode" operating mode a motion detection as mentioned in the "Alarm triggering" table can be reported to the control element. The ambient brightness should not be evaluated in alarm mode in order to be able to trigger an alarm regardless of the ambient brightness.

When the device is in alarm mode, the load switches can be controlled so that the lighting switches to flashing mode or deliberately remains dark. An acoustic warning message is also possible on each motion detector. To prevent false alarms during alarm mode, the evaluation of the motion signals can be assessed according to stricter criteria than in standard mode, which requires the fastest possible motion detection. For example, during alarm mode, only several consecutive movements trigger the alarm.

In certain operating modes, in particular in the case of the listed feedback of an alarm being triggered to the BE control element, a circuit in the control element is possible that triggers an acoustic alarm, for example using a commercially available piezo buzzer. There are various options for switching off the displayed alarm message. The alarm message can be acknowledged and switched off by pressing the specified alarm button on the BE control element. Another possible implementation is to switch off the alarm by pressing any button on the BE control element.

A problem with motion detector devices is the fact that if motion is continuously detected, the circuit does not switch off the lighting even if there is sufficient daylight available. For this reason, the light can be switched off manually in the device described in Fig. 3. In addition, there is an automatic option for switching off the lighting if a light sensor with evaluation to measure the amount of daylight is used as the control element BE. This is connected to phase L and the extension line NL and can power itself as with the manually operated control elements. If this sensor detects sufficient daylight and recognizes through the evaluation of the extension line that the load is switched on in the normal operating mode, the light sensor circuit can give the control command to switch off the lighting by briefly short-circuiting phase L and the extension line NL, equivalent to operating a manual button T.

Claims (23)

PB 2088/GM 02 October 1998 Applicant: INSTA ELEKTRO GMBH & CO. KG 58511 Lüdenscheid Protection claims 1. Device for operating one or more motion detectors, which can also be connected to an installation bus of the building system technology, whereby the detectors each consist of at least sensors, an evaluation unit, a power supply and a load switch and can also be operated by means of one or more buttons and/or one or more operating elements, characterized in that the motion detectors (1 to M) located in the device transmit the condition for switching on a common load (LAST) to one another on a common connecting line, which is designed as a load line (LL, Fig. 2) or the analog coded extension line (NL, Fig. 3) at mains potential, and the switching on of the load is maintained at least as long as one of the motion detectors (1 to M) signals motion detection. 2. Device according to claim 1, characterized in that by means of a button (T, Fig. 2) which applies phase potential (L) to the load line (LL), the lighting dependency of the motion detectors (1 to M) is overridden and the load (LAST) remains switched on at least as long as one of the connected motion detectors (1 to M) detects movement. 3. Device according to claim 1, characterized in that each motion detector (1 to M) feeds a constant current or, when idle, a constant voltage based on phase potential (L) into the extension line (NL), and that the motion detectors transmit the condition for switching on a common load (LAST) to each other by evaluating the extension voltage and by clamping the extension voltage to a fixed voltage value, and that by means of a button (T, Fig. 3) or control element (BE), which applies phase potential (L) to the extension line (NL) when actuated for the first time, whereby the lighting dependency of the motion detectors is overridden and the load (LAST) remains switched on at least as long as one of the connected motion detectors (1 to M) detects movement and switches off the common load (LAST) by further actuation of a button (T) or control element (BE). 4. Device according to claim 1 and 3, characterized in that operating elements (BE) with several operating surfaces are used, which assign different operating modes to the motion detectors (1 to M) of the device by clamping the extension line (NL) to a fixed voltage value related to phase potential (L). 5. Device according to claim 1, 3 and 4, characterized in that the motion detectors (1 to M) report the current operating state of the device to the control elements (BE) of the device by clamping the extension line (NL) to a fixed voltage value related to phase potential (L), which is evaluated and displayed there. 6. Device according to claim 1 and 3 to 5, characterized in that each control element (BE) supplies itself via the voltage available between the phase line (L) and the extension line (NL). 7. Device according to claim 1 and 3 to 5, characterized in that known touch sensors of building system technology can also be used as operating elements (BE). 8. Device according to claim 1 and 3 to 5, characterized in that an operating mode can be set with control elements (BE) which switches the load on for a functionally dependent period of time or permanently, and that this operating mode can also be reported back to the control elements (BE). 9. Device according to claim 1 and 3 to 5, characterized in that an operating mode can be set with control elements (BE) which switches off the load for a functionally dependent period of time or permanently, and that this operating mode can also be reported back to the control elements (BE). 10. Device according to claim 1 and 3 to 5, characterized in that the operating mode twilight function can be set with control elements (BE), which switches the load on at dawn and/or dusk for a function-related period of time, and that this operating mode can also be reported back to the control elements (BE). 11. Device according to claim 1 and 3 to 5, characterized in that the operating mode presence simulation can be set with control elements (BE), which switches the load on during twilight and darkness for approximately random or learned periods of time, and that this operating mode can also be reported back to the control elements (BE). 12. Device according to claim 1 and 3 to 5, characterized in that the operating mode of the alarm function can be set with control elements (BE), which detects movement with a higher false detection suppression regardless of the ambient brightness, and that this operating mode can also be reported back to the control elements (BE). 13. Device according to claim 1, 3 to 5 and 12, characterized in that in the alarm function operating mode, motion detection is reported to the control elements (BE) and is displayed there optically and/or acoustically as an alarm message. 14. Device according to claim 1 and 3 to 5 and 12, characterized in that the motion detectors (1 to M) cyclically switch the load (LOAD) on and off or leave it switched off and/or emit an acoustic warning signal as an alarm message. 15. Device according to claim 1, 3 to 5 and 12 to 14, characterized in that in the alarm function mode the alarm message is switched off by actuating a button (T, Fig. 3) or any control surface of a control element (BE). 16. Device according to claim 1 and 3 to 5, characterized in that by actuating a button (T, Fig. 3) or any control surface of a Control element (BE) the evaluation of the adjusters (ES, Fig. 1) in the evaluation unit (AE) of the motion detectors (1 to M) is permitted for a specified period of time. 17. Device according to claim 1 and 3 to 5, characterized in that by actuating a specific operating surface of an operating element (BE), the evaluation of the adjusters (ES, Fig. 1) in the evaluation unit (AE) of the motion detectors (1 to M) can be alternately unlocked and locked, and that the relevant operating state can also be reported back to the operating elements (BE). 18. Device according to claim 1 and 3, characterized in that an automatic control element with a daylight sensor is provided as the control element (BE), which briefly applies phase potential (L) to the extension line (NL) and thus causes the lighting to be switched off, wherein, if necessary, the control element with a daylight sensor supplies itself via the voltage available between the extension line (NL) and phase (L). 19. Device according to claim 1, characterized in that after the load has been switched off in the evaluation unit (AE, Fig. 1) in each of the motion detectors (1 to M) of the device, the re-switching on of the load by one or more of the motion detectors is prevented by means of a short-term evaluation lock. 20. Device according to claim 1, characterized in that the signals on the load line (LL, Fig. 1 and 2) or the extension line (NL, Fig. 1 and 3) are transmitted to an evaluation unit (AE, Fig. 1) which contains a microcontroller or an application-specific integrated circuit ASIC. 21. Device according to claim 1 and 20 with motion detectors (1 to M) which use relays as load switches (LS), characterized in that the signal of the load line (LL) available at the respective evaluation unit (AE) according to the invention is additionally evaluated to optimize the switch-on time of the relay. 22. Device according to claim 1 and 3 with motion detectors (1 to M) which use relays as load switches (LS), characterized in that the relays are provided with potential-free contacts. 23. Device according to claim 1, characterized in that for integration into an installation bus of the building system technology, the load line (LL) or the extension line (NL) is evaluated and controlled by a sensor/actuator combination (SAK) in the same way as by a button (T) or by an operating element (BE).