AT14574U1 - Sensor for motion detection - Google Patents

Abstract

Sensor (A) for detecting movement for a lighting system (BA), wherein the sensor (A) monitors a certain detection range (B) and the brightness of the lighting system (BA) can be controlled depending on the sensor (A), comprising a housing, a arranged in the housing detection electronics and optics, wherein the sensor is designed so that a distance from the optics to the detection electronics can be changed to allow an adaptation of the detection range (B) to the mounting height (h1, h2).

Description

description

SENSOR FOR MOTION DETECTION

The invention relates to a sensor for detecting movement for a Beleuchtungsanla¬ge according to the preamble of claim 1 and a lighting system with at least one light source according to the preamble of claim 10.

TECHNICAL AREA

Such methods are used to control operating devices for lighting and are used in lighting systems to turn on and off bulbs with the help of a central control unit and adjust the brightness. Normally, the light sources are driven by control gear. The operating devices are grouped into groups and can be controlled by one or more central control units. The term bulbs refers to both gas discharge lamps and halogen lamps or light emitting diodes (LEDs). Such a light source can be arranged individually or together with other light sources in a luminaire, which can also contain the operating device.

STATE OF THE ART

In the prior art, lighting systems already have Bewegungssenso¬ren. So far, the detection ranges of the sensors are fixed or not easily changeable.

PRESENTATION OF THE INVENTION

It is the object of the invention to provide a sensor for detecting movement for a Be¬leuchtungsanlage, wherein the sensor can monitor a certain detection range B and depending on the sensor, the brightness of the lighting system can be controlled, and the detection range can be adjusted.

This object is achieved according to the invention for a generic device by denkennzeichnenden features of claim 1. Particularly advantageous embodiments of the invention are described in the subclaims.

The invention relates to a sensor for detecting movement of a Beleuchtungsanla¬ge, wherein the sensor monitors a certain detection range and depending on the sensor by means of control commands, in particular the brightness of the lighting system can be controlled, comprising a housing, a detection electrode arranged in the housing and an optic, wherein the sensor is designed such that a distance from the optics to the detection electronics can be changed to allow an adaptation of the detection range to the mounting height.

The invention also relates to a lighting system with at least one lamp, wherein the lamps are driven by at least one operating device depending on a sensor.

In this way, it is possible to provide a motion sensor for a lighting system whose detection range can be easily adjusted.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

The invention will be explained in more detail with reference to the accompanying drawing. 1 shows an embodiment of a lighting installation with a sensor according to the invention. FIG. 2 shows an embodiment of a lighting installation according to the state of the art. [0011] FIG

TECHNOLOGY FIGS. 3 to 6 show embodiments of a sensor according to the invention. The invention will be explained below with reference to an exemplary embodiment of a lighting installation BA and a sensor A for such a lighting installation BA.

The invention will be described below with reference to an exemplary embodiment of a lighting system BA with a central control unit 12, a control unit 10, the operating devices 1, T, 1 ", 1, x, 1, coupled to the network via the control unit 10. y and further Steuergeräten11, 13, 14 explained.

The present invention can be used in all types of control gear for Leuchtmit¬tel. The use of very different bulbs is possible, it can be used in particular gas discharge lamps, halogen lamps or inorganic or organic light-emitting diodes.

The operating devices 1, T, 1 ", 1, x, 1, y, the central control unit 12 and the control unit 10 are part of a lighting system BA.

In addition, further control devices 11, 13, 14 connected to the bus line 21.

The various controllers 11, 13, 14 are also referred to as actuators and may be various sensors such as motion or brightness sensors, but also user-controllable actuators such as switches, buttons, or touch-sensitive screens with a user interface for lighting control.

The bus line 21 is designed as a two-wire data line which transmits a digital signal with a low DC voltage as the control command. By way of example, a data transmission in accordance with the DALI standard is transmitted via the bus line 21. The interface circuits of the operating devices 1, T, 1 ", 1, x, 1, y, the central control unit 12 and the control unit 10 are capable of receiving control commands in accordance with the DALI standard.

It should be noted that the data transmission of the control commands via the bus line 21 does not have to be wired, but it can for example be transmitted wirelessly via a radio link or via a power line communication (PLC) via the power supply network 20. Standardized transmission methods analogously to the DALI standard for wired data transmission exist for the transmission variants mentioned, wherein according to the method according to the invention a modified data transmission can take place via the same bus line 21. But it is also possible that the bus line 21 is designed for the transmission of probe signals. The central control unit 12 can be a pushbutton which, in a simple variant, short-circuits the bus line 21 when actuated. However, the pushbutton can also be supplied with mains voltage and the bus line can transmit a pushbutton signal supplied with mains voltage.

The central control unit 12 can control via the bus line 21 single or multiple Be¬triebsgeräte 1 of bulbs, and they can receive and also send digital control commands. In the case of a corresponding switch-off command on the bus line 21, which is received and evaluated by the control unit 10, the control unit 10 can disconnect the connected operating devices 1 from the grid in order to reduce their power consumption to 0. As a result, the operating devices 1 are transferred from the operating state into an idle state. The control unit 10 continues to monitor the bus line 21 for control commands and can store them.

The grid connection and disconnection of the operating devices 1 from the mains supply is effected by a mains breaker 5. This mains breaker 5 may be a switch, such as a semiconductor switch or a relay. The mains breaker 5 can be integrated in the control unit 10 or can be controlled by a control output of the control unit 10.

The control unit 10 can control a plurality of independent network connections and thus independently of one another independent operating devices 1 by being able to control or integrate several network connections. The independent operating devices 1 can be distinguished by different addresses from each other.

The power supply of the control unit 10 and the control units 11, 13, 14 and the central control unit 12 can follow via a built-in the control unit 10 bus supply. In this case, the bus supply can feed the bus line 21 by applying a transmission according to the so-called 'active low' principle. In such a transmission, a level of, for example, 12V is permanently applied while no data is being transmitted. In the case of data transmission, the level for transmitting a bit is pulled to a level lower than, for example, 2V.

In this way, a permanent voltage is applied to the bus line 21 and thus a supply of the control devices 10 and 11 via the bus line 21 is possible.

It may have the control unit 10 via its own power supply, which is coupled directly to the mains supply.

The central control unit 12 can query the state of the operating devices 1 via the Buslei¬tung 21.

Furthermore, the central control unit 12 can also be configured and controlled directly by a user via directly connected buttons or switches, through an interface to a programming device, through a touchscreen or other setting options.

Due to the direct control possibility, the user can also specify control commands, such as, for example, brightness values.

Within the lighting system BA with at least one luminous means, the luminous means, which are controlled by at least one operating device 1, T, 1 ", 1, x, 1, y depending on commands of a central control unit 12, can have an address. Already at the time of delivery of the operating devices 1, T, 1 ", 1'x, 1 ', a preset address L can be stored in the operating devices 1, 1', 1", 1, x, 1, y.

In the following, an embodiment of the construction of sensors according to the invention will be described.

The sensor A for a lighting system BA is used for motion detection and monitors a certain detection range B and depending on the sensor A can be controlled by means of control commands in particular the brightness of the lighting system BA.Der detection range B can be adjusted.

The detection range B of the motion sensor can be adjusted according to the mounting height during startup.

2, a problem of the prior art is shown. Different mounting heights h1 and h2 result in a correspondingly different detection area (ef1 or ef2) of the sensor A if no adaptation of the detection area B to the mounting height takes place.

According to the invention, an adaptation of the detection range B to the mounting height is possible, as will be explained below.

The sensor A has a housing. In the housing, a detection electronics 35 is arranged. The housing further has an optic 33. Sensor A preferably has an infrared sensor, preferably a passive infrared sensor (PI R), as detection electronics 35. The sensor is designed so that a distance from the optics 33 to the detection electronics 35 can be changed to allow an adaptation of the detection range B.

The optics 33 of the sensor A is preferably formed as a lens. In particular, the lens consists of a plurality of individual lenses and thus the sensor image is duplicated. In the example of Fig. 4, the lens has four single lenses.

To cover a desired detection area B, the sensor element of the detection electronics 35 is multiplied by a lens. This lens is designed depending on the application, for example, ceiling sensors to a certain height and thus designed with a certain angle. Ideally, the images of the sensor elements of the detection electronics 35 should be adapted to the size of the objects to be detected.

In the prior art, different lenses must therefore be produced for corresponding heights in order to be able to offer motion sensors for different ceiling heights. So far, therefore, different motion sensors had to be offered.

According to the invention, the angles of the respective images of Erfas¬sungselektronik be changed for an image and thus their position in space.

By adjusting the distance between the detection electronics 35 with the sensor element and the lens, which is calculated to a fixed focal point, the size of the sensor images and the detection angle can be adjusted. In this way, it is possible to offer a movement sensor for a wide range, which can be set to the appropriate height during installation.

If the focal point is changed by adjusting the distance between the detection electronics 35 with the sensor element and the lens (f2 to f1), the detection angle is also changed (from a2 to a1). Thus, also the detection range B of the movement sensor can be changed and the detection area can be adjusted accordingly. For example, the detection area B can be changed so that the detection area remains the same for different mounting heights. Figure 3 shows such an example of detection by means of a motion sensor for two different heights.

FIG. 4 shows an example of detection by means of a motion sensor for two different heights. Thus, since the optic 33 in the form of a lens of the motion sensor A is composed of a plurality of individual lenses, the sensor image is duplicated or multiplied depending on the configuration of the single lenses. In this example, four sensor elements are used for one image.

FIG. 5 shows an example of an embodiment of a movement sensor according to the invention for two different heights. The adjustment of the distance from the optical system 33 to the detection electronics 35 takes place in this example by means of a displacement of the printed circuit board 36, on which the detection electronics 35 are arranged. Two positions can be selected in this example, once for a detection height of 5 to 9 meters, and a second detection altitude of 9 to 14 meters. The displacement of the printed circuit board takes place via a rotating mechanism. By means of a type of adjusting screw 34, which is accessible on the back of the movement sensor, a shift of 0.5 mm to 2 mm can be achieved by a 90 degree rotation, wherein the circuit board on which the detection electronics 35 is arranged, with respect to the Optics 33 is shifted.

Such displacement may be accomplished by rotating the set screw 34 with the set screw seated in a thread 37 and connected to the circuit board 36 such that rotation of the set screw 34 results in displacement of the circuit board 36 and thus the sensing electronics 35 relative to the optic 33 causes.

The printed circuit board 36, on which the detection electronics 35 is arranged, can also be shifted, for example, by a displacement of a lower part 31 of the housing with the printed circuit board 36 in relation to the optical system 33, for example by a corresponding latching of the lower housing part 31 with the circuit board 36 or by a screw mechanism.

However, it is also possible, for example, for the optics 33 to be displaced in relation to the housing, in particular to the housing lower part 31, and also for the printed circuit board 36 fastened in the housing, in particular in the housing bottom part 31, and thus for the detection electronics 35.

For example, the optical system 33 may be arranged in a housing upper part 32, and the housing upper part 32 may be adjusted by a rotating mechanism such that a displacement of the optical system 33 in relation to the housing lower part 31 and also in the Ge¬ housing bottom 31 attached circuit board 36 and thus the detection electronics 35 takes place. An example of such an arrangement is shown in FIG.

On the lower housing part 31 may be arranged with the optics 33, for example, a two-position adjustment positions of the housing top 32. For example, in a shift of 180 ° there may be a mark 'LOW' for the adjustment of a relatively small distance arrangement between optic 33 and circuit board 36, which setting may be chosen for a low ceiling height.

Furthermore, a mark 'HIGH' for the adjustment of a relatively large distance arrangement between optics 33 and circuit board 36 may be present, this setting can be selected for a high ceiling height. The upper housing part 32 can be arranged in a rotational manner in a thread on the housing lower part 31 and thus be adjusted by a 180 ° rotation such that a displacement of the distance from the optical system 33 to the printed circuit board 36 and thus the detection electronics 35 takes place. There may be two fixing points, into which the upper housing part 32 can engage in each case in the stop of the 180 ° rotation, so that a fixing of the upper housing part 32 in the two adjustment positions is made possible.

The optics 33 may be formed as a Fresnel lens.

The detection range B can be adjusted mechanically. The detection range B can be adjusted electronically.

The mechanical adjustment of the detection area B can be controlled via an electronic drive. The mechanical change can be made via a motor-driven mechanism.

The adjustment of the detection range B can be done for example by parameterization by means of a programming device via setting switch or a bus system.

The sensor A may additionally contain a brightness sensor as a detection unit.

The sensor A can be connected to the bus line 21 as a control device 13, for example, or connected directly to a control device 1 via a sensor interface.

Thus, a lighting system BA can be constructed with at least one light source, wherein by means of control commands, the brightness of the light source is controlled by at least one Be¬triebsgerät 1, 1 ', 1 ".. depending on a sensor A according to the invention.

The brightness of the lighting means can be changed by switching on and switching off individual operating devices (1, 1 ', 1 ").

The brightness of the lighting means can also be changed by dimming individual operating devices (1, 1 ', 1 ").

Thus, a lighting system BA can be made possible with at least one luminous means, wherein the luminous means by at least one operating device 1, 1 ', 1 " Depending on commands of a central control unit 12 or of a control unit 13, 14 are controlled, and at least one control unit 11, 13 is designed as a sensor A according to the invention.

The operating devices 1, 1 ', 1 ", 1, x, 1'y can communicate according to the DALI standard.

Thus, lighting system BA is provided with at least one light source, wherein the operating devices 1, 1 ', 1 ", 1'x, 1'y can be placed in an addressing mode and in each case in the operating device 1, V, 1", 1, x, 1, y stored preset address L can read.

The central control unit 12 can interrogate the possible addresses ADR and check whether more than one operating device 1, 1 ', 1 ", 1" x, 1 "sends a response for a specific address.

Claims (10)

Claims 1. Sensor (A) for detecting movement for a lighting system (BA), wherein the sensor (A) monitors a certain detection range (B) and in particular the brightness of the lighting system (BA) can be controlled depending on the sensor (A), comprising a housing (31, 32), a detection electronics (35) arranged in the housing (31, 32) and an optic (33), characterized in that the sensor is designed such that a distance from the optics (33) to the Erfas¬sungselektronik (35) can be changed to allow an adaptation of the detection range (B) to the mounting height (h1, h2). Second sensor (A) for a lighting system (BA), according to claim 1, characterized in that the change of the distance is effected by a mechanical adjustment. 3. sensor (A) for a lighting system (BA) according to claim 1 or 2, characterized in that the change of the distance is effected by an electronic adjustment. 4. Sensor (A) for a lighting system (BA) according to claim 1, 2 or 3, characterized in that the optical system (33) is designed as a Fresnel lens. 5. Sensor for a lighting system (BA), according to claim 2, characterized in that the mechanical change takes place via a screw mechanism. 6. sensor (A) for a lighting system (BA) according to claim 5, characterized in that the mechanical change takes place via a motor-driven mechanism. 7. sensor (A) for a lighting system (BA) according to one of claims 1 to 10, characterized in that the detection area (B) according to the mounting height (h1 or h2) can be adjusted during the commissioning by a control unit. 8. sensor (A) for a lighting system (BA) according to one of claims 1 to 11, characterized in that the sensor (A) additionally includes a brightness sensor. 9. sensor (A) for a lighting system (BA) according to one of claims 1 to 8, characterized in that the detection electronics (35) includes a passive infrared sensor. 10. Lighting system (BA) with at least one luminous means, wherein the brightness of the luminous means is controlled by at least one operating device (1, 1 ', 1 ") depending on a sensor (A) according to one of the preceding claims. For this 6 sheets of drawings