DE29903904U1 - Motion sensor controlled lamp device - Google Patents

Description

HlEBSCH PEEGE &JE.H.R

PATENT ATTORNEYS EUROPEAN PATENT AND TRADEMARK ATTORNEYS

Application for registration of a utility model

Our reference: SL228DE8 B/ke

(31) Priority Application Number: 29804089.1

(32) Priority Date:

09.03.98

(33) Priority Country:

Germany

(54) Title:

Motion sensor controlled Lighting device

(71) Applicant:

Stones! AG Allmeindstr. 10

8840 Einsiedeln Switzerland

(74) Representative / Agent:

Dipl.-Ing. Gerhard F. Hiebsch Dipl.-Ing. Dr. oec. Niels Behrmann M.B.A. (NY) Heinrich-Weber-Platz 1

78224 Singen

Oral agreements require written confirmation to be valid.

Parking in the building (entrance: Freiheitstraße)

LAKE CONSTANCE PATENT ⁸

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Motion sensor controlled lighting device

The invention relates to a motion sensor-controlled lighting device according to the preamble of claim 1. Such devices are known, for example, from DE 196 01 489 A1 of the applicant and are based on the principle of connecting common lighting devices -- incandescent lamps, energy-saving lamps or others -- to a motion detector in the most compact way possible in order to then be able to activate and deactivate the lighting device in a motion-controlled manner.

In the known prior art, the motion sensor was housed in a base housing that could preferably be inserted into a lamp socket, with this base housing then in turn offering a lamp socket for inserting the lamp.

Such technology is therefore particularly suitable for luminaires in which the lamp housing offers sufficient space for inserting or interposing the base housing.

However, particularly under compact lampshades or when there is only limited space above the lamp base, there may be circumstances that do not allow the insertion of this known base housing between the base and the lamp. This is particularly true if the base housing to be used exceeds a certain minimum size due to the necessary electronics or antenna.

The object of the present invention is therefore to improve a generic motion sensor-controlled lighting device in such a way that the overall arrangement becomes more compact and can in particular also be used in confined spaces.

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The object is achieved by the motion sensor-controlled lighting device with the features of claim 1. Advantageous further developments of the invention are described in the subclaims.

In an advantageous manner according to the invention, the carrier module uses the interior or intermediate space defined by the lamp and provides there in particular the sensor electronics with transmitting and/or receiving antenna; not only does this avoid the need for these additional modules to be integrated into the motion base itself, but this measure also separates the sensor electronics from the circuits already present in the mounting base (in particular a conventional electronic ballast (EVG) for the lamp), so that the motion sensor can be accommodated easily and in a space-saving manner, particularly from a radiation and thermal point of view, without the -- temperature-sensitive -- sensor electronics being disadvantageously heated by the lamp ballast electronics.

In connection with the present invention, the term interior and/or intermediate space is to be understood as any space located above the mounting base which is determined, defined or limited by sections of the lighting device, whereby such interior or intermediate spaces would otherwise remain unused. In particular in the case of tubular lighting devices -- elongated, curved or coiled lighting tubes -- the term interior or intermediate spaces according to the invention is to be understood as all spatial areas which lie within an imaginary shell placed around the lighting device.

In a further advantageous manner, the invention takes advantage of the penetration properties of microwaves by placing the transmitting or receiving antenna behind or between the lighting means in a space-saving manner.

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ensure that the emitted or received microwaves penetrate the lamp in the coverage area.

The invention is not limited to a specific shape or design of a lighting device.

It is particularly preferred to realize the lighting means as a gas discharge lighting means, wherein an associated discharge tube is arranged in front of or around the transmitting or receiving antenna in accordance with the invention, and wherein further preferably this transmitting or receiving antenna is formed on a flat substrate.

One possible suitable embodiment of the gas discharge lamp is the -- single or double -- spiral shape, in which the tube is wound spirally to achieve the most compact object possible with the maximum tube length and extends around the transmitting or receiving antenna. The lighting means is thus realized as a spirally wound or helical gas discharge tube that encompasses at least a portion of the transmitting and/or receiving antenna. It is also particularly advantageous if the lighting means is realized as a double spiral with a spiral structure running back and forth. In an advantageous manner according to the invention, the space available above the mounting base can thus be optimally utilized without this mounting base being unnecessarily and disadvantageously enlarged to accommodate the antenna.

According to the invention, the mounting base contains only the ballast electronics for the lamp (EVG) that are conventionally already present in such a base, and only within the scope of a possible further development could this base additionally contain the (compact) control or evaluation electronics for the motion sensor.

Alternatively, it is possible to mount these sensor electronic components on the flat carrier for the transmitter

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/receiving antenna, which then enables the complete realization of the motion sensor as a module and thus the easy retrofitting of existing sensor lights (e.g. by inserting the sensor carrier into the base between the light source).

A particularly suitable form of implementation for the microwave motion sensor is the broadband pulse radar sensor, which operates at a frequency in the range between about 2 and about 20 GHz and is particularly suitable for penetrating both the lamp and any surrounding lampshade.

In a further development that is advantageous according to the invention, it is also provided that the lighting device is provided with a brightness and/or time control unit that activates or deactivates the light source depending on the ambient light level, for example in the case of brightness control that is further preferably self-light compensated. This can be used, for example, to change the operation of the light in a bright daylight environment (despite motion detection). In addition or alternatively, the time control unit according to the further development ensures that the lighting device is operated in continuous operation, for example at predetermined evening hours, while otherwise lighting operation with a predetermined lighting duration is only triggered when required, namely as a result of detected movement of an object.

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Further advantages, features and details of the invention will become apparent from the following description of embodiments and from the drawings, which show in

Fig. 1: a schematic side view of the motion sensor-controlled lighting device according to the invention according to a first embodiment;

Fig. 2: a side view of the motion sensor controlled lighting device according to the invention according to a second preferred embodiment;

Fig. 3: a cross-sectional view along the section line III - III in Fig. 2;

Fig. 4: a cross-sectional view analogous to Fig. 3 along the section line IV - IV in Fig. 2;

Fig. 5: a schematic view of an elongated carrier element equipped with electronic components for the motion sensor unit with an antenna section at the end and

Fig. 6: a detailed view of section VI with the end antenna section of the carrier board according to Fig. 5.

The lamp shown schematically in Fig. 1 is modelled in its external form on devices that are commercially available and sold as so-called energy-saving lamps. A housing 12 provided with a screw base 10 for a standard light bulb socket provides space for the control or ballast electronics (not shown in detail).

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shows) of a gas discharge lamp 14, which can be operated in the usual way with transformed mains voltage.

In the context of the present invention, such a lamp is connected to a motion sensor in such a way that -- as schematically indicated by the flat carrier board 16 -- the transmitting and/or receiving antenna of a radar motion sensor is arranged behind or between the actual lighting means 14, and this radar motion sensor emits or receives electromagnetic waves during operation via the flat carrier element 16 as an antenna. These are usually in the range between about 2 and about 20 GHz and are thus able to easily penetrate not only the lighting tube 14 (or the illuminating gas contained therein), but also any cover or lampshade that can surround the arrangement shown in the assembled state.

More precisely, a microwave sensor is used to implement the motion sensor 16, which operates on a pulse basis and emits a broadband pulse transmission spectrum, approximately 500 MHz wide at a carrier frequency of 2 GHz. Using a predetermined time gate corresponding to a detection distance (formed from the forward and return times of a signal pulse from an object at the detection distance), a large number of reflected pulses are detected using an antenna arrangement formed on the carrier board 16, and the frequency of reception (integration) or the change in the frequency of reception is used to infer that the object to be detected is moving.

Such a pulse radar technology would also enable presence detection in such a way that, in contrast to the described motion detection, no reflected signals from a constant, time-dependent detection distance (corresponding to a bowl in the room) are received and evaluated, but rather this bowl-

shaped detection area is continuously and cyclically electronically traversed so that presence detection is possible (even without the object being detected having to move).

A radar sensor that works on a pulse basis and is used appropriately within the scope of the present invention can be operated in common frequency ranges -- 2 GHz, 5.7 GHz or higher -, ensures satisfactory penetration, in particular of the illuminant 14, through the emitted or reflected radar pulses and can be mounted in a particularly space-saving manner in the manner shown.

In particular, it is also provided that the light source is not curved as shown in Fig. 1, but spiral or single or double spiral and thus extends in the form of a spiral (comparable to the shape of an immersion heater) around the vertical antenna board 16. This arrangement in particular enables the space required to be optimized, since the interior enclosed by the spiral fluorescent tube is used here in an advantageous manner to accommodate the sensor antenna, and possibly even the sensor electronics, without additional space being required in the base housing (occupied by the electronic ballast). Preferably, a sensor module constructed in this way can also be plugged onto the housing 12, is supplied with operating voltage by the electronics contained therein and thus makes it possible to retrofit common energy-saving lamps with minimal effort.

The detection range of the motion sensor arrangement depends on the intended purpose and is realized by appropriate design of the antenna structure on the carrier 16; in particular, a circular detection range (radially symmetrical to the longitudinal axis due to the arrangement of Fig. 1) is also possible.

As an alternative to the shown design as a pulse radar sensor, the motion sensor can also be implemented as a

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A radar sensor that works according to the Doppler principle is conceivable. Here, the movement of an object in the sensor's detection range is detected as a frequency shift between the emitted signal and the reflected received signal, and this frequency shift (Doppler frequency) is evaluated to detect movement and speed.

Another alternative to the design shown is a pulse radar sensor that works according to the homodyne principle, and in which broadband transmission pulses define an effective detection range through their pulse shape and duration; simultaneously and without delay, such a transmission signal is then coupled into the motion sensor on the receiving side in order to control a non-linear mixer element. The resulting mixer signal is then evaluated for motion detection.

Such a sensor type is used in the embodiment shown in Figs. 2 to 6: A lighting device 20 corresponding to the design of a commercially available energy-saving lamp has a gas discharge lamp, which in turn consists of three elongated pairs of tubes 22 bent at the upper end, which, see the sectional view in Figs. 3 and 4, describe a triangular shape on the upper side of a base housing 24 and thus delimit an elongated, triangular clear intermediate or interior space.

While the base housing 24 has, in an otherwise known manner, a ballast electronics (not shown in the figures) for operating the light tubes 22, the sensor electronics including the transmitting and receiving antenna are contained on a flat carrier board 26, which is designed in terms of its length and width dimensions so that it can be inserted into the elongated triangular space 28. Contact with the lighting or control electronics contained in the base housing 24 and a power supply provided here is made via floor-

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side connection contacts 3 0 on the narrow side of the carrier board 26 .

At the other end, it has an antenna designed as a dielectric resonator 32 which, see the section according to Fig. 6, has a cylindrical shape with a diameter of approx. 8 mm and a height h of approx. 4 mm.

In the embodiment shown, the carrier board 26 is surrounded by an elongated, metallic shielding element 34, from which the resonator 32 protrudes only at the end. As shown in Fig. 2, the resonator section also extends above the tube pairs 22, with a cover cap 36 being provided here.

In addition, Fig. 2 shows laterally accessible control elements in the form of suitable actuators on the carrier board 26, which can be actuated by a distance between two adjacent tube pairs 22 and serve to adjust a switching threshold for the ambient brightness (the - actually compensated - brightness sensor is not shown in detail in the figures), a detection range of the motion sensor and a minimum lighting duration after switching on if no further movement is detected.

In an otherwise known manner, this device is inserted into standard lamp screw sockets and -- including the motion sensor and brightness control electronics -- is supplied with operating voltage via these.

As an additional development (not shown in the figures), it is possible to provide the device according to the invention with a time control in such a way that -- depending on the time of day -- different operating modes of the lighting device are possible: At previously determined times, for example, the lighting device is operated in continuous operation without motion detection being necessary; at other times

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The lamp activation is triggered by the motion sensor, which is implemented by means of the carrier board and the end-side resonator antenna 3 2 in the present embodiment.

According to a further development, it is also possible to supplement the lighting arrangement according to the invention with a twilight or brightness sensor unit, which makes activation or deactivation of the lighting device dependent on the current ambient light level and/or which additionally carries out an ambient light-dependent brightness setting of the lighting device. In this way, activation of the lighting device by movement can be prevented, for example, if a very bright ambient light level would make it unnecessary to switch on the lighting device.

Claims (10)

1. Motion sensor-controlled lighting device with a light source ( 14 ; 22 ), in particular a gas discharge lamp, held on a fastening base ( 12 ; 20 ) and with its outer walls delimiting a clear interior and/or intermediate space ( 28 ) outside the fastening base, and a motion sensor ( 26 ; 32 ) set up to activate or deactivate the light source in response to a detected movement, characterized in that the motion sensor is a microwave sensor formed on a carrier module ( 26 ) with a transmitting and/or receiving antenna ( 16 ; 32 ) and associated sensor electronics, which is provided on the fastening base ( 12 ; 24 ) in such a way that the carrier module ( 26 ) is received with at least a partial area in the interior and/or intermediate space ( 28 ). 2. Lighting device according to claim 1, characterized in that the lighting means has a curved gas discharge tube ( 14 ; 22 ) which extends upwards from the fastening base ( 12 ; 24 ) which can be inserted into a lamp holder ( 10 ), wherein the carrier module ( 26 ) is realized by means of a plate-shaped, flat substrate. 3. Lighting device according to claim 1 or 2, characterized in that the lighting means has a plurality of elongated tube sections running parallel to one another, which form the interior and/or intermediate space for an elongated carrier module ( 26 ). 4. Lighting device according to one of claims 1 to 3, characterized in that the carrier module is provided on the fastening base in such a way that at least a partial area of the movement detection area of the transmitting and/or receiving antenna, preferably implemented as a resonator ( 32 ), is directed through the lighting means ( 14 ; 22 ) onto an object to be detected. 5. Lighting device according to one of claims 1 to 4, characterized in that the fastening base ( 12 ; 24 ) has a ballast electronics for the lighting means and contact means for the carrier module. 6. Lighting device according to one of claims 1 to 5, characterized in that the motion sensor is designed as a broadband pulse radar sensor which detects movement or presence on the basis of broadband radar pulses reflected from an object within a predetermined time gate. 7. Lighting device according to one of claims 1 to 6, characterized by a device for detecting the ambient brightness, this device acting on the lighting means such that activation or deactivation depends on a current level of ambient brightness. 8. Lighting device according to claim 7, characterized by means for compensating the light of the lamp itself, in particular a unit for shifting a response threshold of the activation or deactivation by an amount of light generated by the lamp itself. 9. Lighting device according to one of claims 1 to 8, characterized by a time control unit which is designed to switch the lighting device between a continuous lighting mode and a motion-controlled lighting mode with a preferably preselectable minimum lighting duration depending on the time of day. 10. Lighting device according to one of claims 1 to 9, characterized in that the motion sensor is designed as a plug-in module and can be removably attached to the fastening base.