EP1820169A1

EP1820169A1 - Sensor light

Info

Publication number: EP1820169A1
Application number: EP05850220A
Authority: EP
Inventors: Heinrich Wolfgang Steinel; Martin Meggle; Christof Herbst; Thomas Möller
Original assignee: Steinel GmbH and Co KG
Current assignee: Steinel GmbH and Co KG
Priority date: 2004-12-01
Filing date: 2005-12-01
Publication date: 2007-08-22
Anticipated expiration: 2025-12-01
Also published as: DE202005021534U1; DE502005007018D1; WO2006058742A1; EP1667079A1; US8130099B2; EP1820169B1; DE502005005991D1; US20080204230A1; EP1667079B1; DE202004018647U1; DE202005021536U1

Abstract

The invention relates to a sensor light comprising a light unit which can be activated as a reaction to a sensor output signal of a movement sensor unit (16) which, preferably, works on an infrared basis, and which is provided on a carrier unit (10,12) enabling the sensor light to be mounted in an inner or outer area. The movement sensor unit is embodied in a modular manner and can be removed from the carrier unit when the latter is in a mounted state and has at least one manually activated actuating element (28) which can be activated when the movement sensor is removed.

Description

DESCRIPTION

SensorLight

The present invention relates to a sensor lamp according to the preamble of the main claim. Such devices are well known in the art, and are marketed in bulk, such as outdoor or garden lights controlled by an infrared motion sensor.

Principle of this used as a generic forming lights 5 is that a nearly arbitrarily aesthetically designed, a lighting device having lamp unit is attached to a support unit (base unit), which ensures the one hand, the electrical supply of the lighting unit, on the other hand, the mechanical attachment of the sensor D to a house wall or the like. Mounting position allows. In addition, in the case of such luminaires, there is a motion sensor system which, typically integrated into the carrier unit, offers a lens window for a movement sensor arranged behind it and sensitive to infrared radiation.

The associated sensor electronics integrated in the carrier unit then enable the sensor-controlled switching on and off of the lighting element in response to a detected movement, wherein additionally suitable ambient or operating parameters can be set or preselected, such as a level of ambient brightness in which the device is activated in the first place, a lighting period in the activated state (before the lighting unit is again automatically deactivated), or a detection area of the sensor system. These parameters are usually location or environmental condition, so that each mounted sensor light before proper commissioning must first be suitably adjusted.

However, a problem with the S sensor luminaires known from the prior art is that this parameter setting can only take place in the mounted state (that is to say on a building wall), so that access to the sensor luminaire or the carrier unit and / or the sensor unit frequently occurs provided adjustment is cumbersome in the handling; For example, the use of a ladder is required when the luminaires are suspended high. In addition, it is often difficult to adjust the brightness or twilight threshold for activation of the lamp properly, this is often done in the respective semi-darkness (each with the disadvantage that the adjustment elements are correspondingly difficult to see).

A further disadvantage of the devices known from the prior art is that, in particular at wide detection angles and the use of a mirror for interaction with an infrared motion sensor, the circumferential detection area is highly inhomogeneous; This is due to the fact that, with typically two sensor individual elements of a motion sensor, certain optical irradiation conditions result in that, depending on the circumferential position of a person moving relative to the sensor, its image is projected in different ways onto the sensor adjustment elements becomes.

However, since the motion detection signal is based on a difference of the individual signals output from the elements, there exist positions in the circumferential direction in which both sensor elements receive infrared images equally and thus no usable sensor difference signal is generated, hence the motion sensor has an in Environmental direction extremely inhomogeneous sensitivity and thus detection range shows. Object of the present invention is therefore to simplify first handling and adjustability generic type sensor lights in the assembled state. In addition, the range or sensitivity homogeneity of the 5 motion sensor of a sensor lamp should be improved in the circumferential direction.

The object is achieved by the sensor lamp with the features of the main claim; advantageous developments of the invention ID are described in the dependent claims.

In accordance with the invention advantageously, it is thus possible that the sensor lamp can be mounted and operated in a proven and known manner, but for the purpose

15 the simplified handling and adjustment of the acquisition and operating parameters, the module-like motion sensor unit can be removed from the sensor light and then in this removed state the - simple and easy - setting the operating parameters

ΞD ter takes place.

It is particularly advantageous that, according to the preferred development of the invention, the removal of the motion sensor unit has a predetermined illumination state of the sensor.

ΞS sorleuchte, in particular a continuous light of the lamp unit, triggers, which in particular also so that a setting under poor ambient light conditions (such as when setting a twilight threshold) is simplified.

3D

The sensor housing accommodating the movement sensor unit is particularly suitably designed to be cylindrical and pluggable, with the at least one positioning element being more preferably concealed in the inserted state. Not only lets

In this way, the aesthetically pleasing realization of the sensor light as a whole is promoted, and as a result, the rotary regulators or switches typically used as actuating elements are advantageously protected against ambient influences. protected, without the need for separate measures. In addition, there is the possibility by this measure, the controls or the surrounding housing surface with visible labels, instructions S or the like. to provide, even without then always make the use of an external manual necessary to increase ease of use and reliability, while in the inserted state these labels are invisible and thus not adversely affect the aesthetic appearance of the overall arrangement D adage.

In addition, it is particularly suitable to equip the present invention with a motion sensor which has a wide detection range, i. H. greater than 180 ° and typically up to 360 °. This detection range is made suitable by a multi-facet mirror, which then interacts with the actual (infrared-sensitive) sensor, with the sensor housing forming a circumferential slot area through which infrared radiation can strike the mirror and then deflected appropriately to the sensor become.

According to training and to improve or extend the detection area 5 in a vertical plane, it is also provided to introduce a frontally arranged lens area in the sensor housing, so that, for example, movements in a region immediately under a suspended sensor light can be detected. D

According to a further preferred development of the invention, it is additionally provided that the above-mentioned and further setting parameters for the illumination and detection behavior of the sensor light - brightness threshold values, detection range, lighting duration, illuminance in the idle and activated states, etc. - are not set individually and separately but, for this purpose, predetermined, program-like stored parameter sets by pressing of the control element are easily selectable. These parameter sets are based on factory-set and stored typical environmental scenarios, so that the (initial) setting effort can be drastically reduced for the user performing the assembly and initial setting on the sensor lamp.

A particular variant of the invention consists in a further development, the purpose of the parameter backup

ID or the like provided data storage on the motion sensor unit, in particular in the removed state, an external contact making accessible by means of a suitable interface, such as in the way that (analogous to the known portable USB storage devices) the movement

IS sensor unit is provided with a suitable, preferably standardized interface and so by means of an external diagnostic unit (such as a suitably programmed PC) maintenance personnel can access the unit on site, set operating parameters and / or check

ErfassenD or even an operating and / or operating history of a device can record and check against the background, for example to distinguish technical errors from operating errors. Further possibilities of such an external interface with access to the data storage unit would also exist in a

E s ner updatability an operating system software for the motion sensor unit ( "Firmware Update"), especially if the further refinement of the invention ^"provided data storage unit, beyond simply storing operational parameters addition, wider than non-volatile program and data

3D tenbasis is understood for the motion sensor unit.

In accordance with a further preferred embodiment, the motion sensor unit for realizing the sensor system has four infrared-sensitive sensor elements which expand the known pair of sensor elements. As a result, the above-described problem of the inhomogeneous detection area in the circumferential direction is solved in an advantageous manner by greatly varying sensitivity behavior, because In accordance with the invention, the four sensor elements which are suitably connected in pairs or crosses are evaluated in the form of two mutually independent branches (with respective sensor electronics), so that even in the unfavorable case described above, the simultaneous application of both sensor elements of a pair of sensor elements to one identical IR image of the other branch outputs a detection detection signal useful for motion detection. By a logical OR combination of both ID branches a uniform, homogeneous detection signal is then guaranteed for each case of the environmental position at a wide detection angle.

A further favorable development of the invention is also that the mirror element interacting with the sensor (or the individual sensor elements) and used to realize the large detection angle is itself adjustable or adjustable, so that in a simple and elegant way an adjustment of the detection range (for example, by tilting or pivoting of individual or all facets or segments of the mirror) can take place.

The result is thus surprisingly simple and elegant way a sensor lamp, which combines significantly improved detection characteristics with simplified production and simplified installation and adjustment. Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawings; these show in S

Fig. 1: A view of a sensor lamp according to a first embodiment of the present invention;

G Fig. 2, Fig. 3: the partial views of the lower portion of

Carrier unit of the sensor lamp according to FIG. 1 with inserted, module-like motion sensor unit (FIG. 2) as well as exploded, the detached 5 state;

Fig. 4: a variant of the carrier unit opposite

Fig. 2 as a second embodiment;

FIG. 5, FIG. 6: perspective views of the module-like motion sensor unit with different areas of the sensor housing; FIG.

Fig. 7 is a sectional view of the sensor housing of S Fig. 5, 6 with internal mirror unit, sensors and associated electronics and

8 shows a sensitivity / range D detection diagram of the detection characteristics of the sensor lamp equipped with the motion sensor system of FIGS. 5-7 in comparison with known dual-element sensors. 5 The sensor lamp shown in Fig. 1 has a arm 10 and a wall portion 12 having carrier unit made of a plastic material, wherein at the end of the arm in an otherwise known manner, a bulb socket and S a holder for a (not shown), the bulb socket and thus the Lamp enclosing lampshade is provided. At the other end, in the lower region of the arm of the carrier unit, a movement ID sensor unit 16, which can be plugged in by means of a cylindrical sensor housing 14, is detachably provided.

Figures 2 and 3 illustrate the relative relationship between the carrier unit of the sensor lamp and the sensor housing; Fig. 2 shows the sensor housing in the inserted

IS state, wherein an annular lens portion 18 in the inserted state protrudes from the housing realized by the carrier unit, while the remaining housing portion is hidden in the lamp body. The exploded view of FIG. 3 illustrates the withdrawn

ΞD nen condition.

With reference to FIGS. 5 to 7, the basic structure of the sensor unit 16 will be explained. The cylindrical housing 14 made of a plastic material has at one end an electric

SS nikmodul 20, which, exposed to the top, u. a. In addition to other electronic components an infrared sensor 22 (again consisting of an arrangement of four pairs and cross-connected IR Einzelelsen- sensors) carries. In the housing the sensor 22 is opposite

3D, a cone-shaped facet mirror 24 is provided which lies in the housing 14 at the height of the laterally encircling lens region 18 and can be acted upon by this with incident radiation, which then deflected by the facets of the mirror unit 24 on the sensor 22

35 becomes. In addition, as shown in FIGS. 5 and 7, the sensor housing has an additional round lens area 26 at the end, through which incident radiation passes directly through a free middle area of the mirror 24 can fall through to the sensor 22. On the bottom side (ie the electronic module 20 adjacent), the housing 14 from the outside accessible control elements in the form of rotary controls 28, and a molded into the housing material and S corresponding plug contacts having plug 30 for electrical connection provided in the support unit of the lamp further units, among others for power supply and control of the lighting unit.

In use, the luminaire shown in FIG. 1 is first mounted, for example in the position shown, on a wall or the like, the illuminant is screwed in and the lampshade is put on. After the electrical connection has been made, it is then possible, in the manner shown in FIG. 3, to remove the movement sensor unit 16 and, in this withdrawn state, to make the desired settings by actuating the adjusting elements 28. By suitably configuring the electronics present in the carrier unit, at this time (i.e., D removing the module), the lighting unit is set in a steady state. After reinserting (FIG. 2), the sensor light for the motion detection operation is then ready for operation in the set manner.

5 illustrates the advantages in the detection range achieved by the configuration of the sensor 22 with four sensors connected in pairs in each case: Whereas the measurement curves provided with the reference symbols 36 and 38 illustrate an angularly limited or strongly inhomogeneous detection range, as he described in FIGS As a result of a typical, common two-element sensor, the measuring curve 40 shows the homogeneous profile measured with the sensors of the present invention when using four individual IR sensors each pairwise and redundantly evaluated. 5

While the present embodiments have focused on infrared motion sensors, the invention is not limited thereto; so is the particular inventive idea of the modular motion sensor unit and its removability with all related developments and advantages equally suitable to be realized with other motion sensor principles S, such as an ultrasonic sensor or a high-frequency sensor. Just about a microwave acting, more preferably pulsed (Doppler) motion sensor is then extremely well suited to be a technically equivalent in other areas even superior alternative to D infrared sensors; For example, such an embodiment of the invention would allow the possibility of the sensor - such as by far sinking or the like. Measure in the carrier unit - to make almost invisible, because the (plastic) housing walls penetrating micro 5 waves would not need a separate sensor opening or separate, visible from the outside lens.

Claims

1. Sensor light with

S a lamp unit activatable in response to a sensor output signal of a motion sensor unit (16) which preferably acts on an infrared basis and which is provided on a carrier unit (10, 12) for mounting the sensor lamp in the interior or exterior area

ID is, characterized in that the motion sensor unit is formed like a module and with mounted carrier unit detachable from this and at least one manually operable

15 actuating element (28) which can be actuated in the removed state of the motion sensor unit.

2. Sensor light according to claim 1, characterized gekennzeich- 2D net, that the motion sensor unit (16) has a sensor housing (14) which is designed for pluggable cooperation with the carrier unit and a mechanical and an electrical connection between the motion sensor unit and of the

TrägS carrier unit in an inserted state of the sensor housing manufactures.

3. Sensor housing according to claim 2, characterized in that the sensor housing at one end a Linsenbe-

3G rich (18, 26) which protrudes in the inserted state of the sensor housing from the carrier unit, and the other end, the adjusting element (28) is provided, which is hidden in the inserted state.

35

4. Sensor light according to claim 2 or 3, characterized in that the sensor housing (14) is cylindrical and at one end the circumferential and slot-shaped lens area (18)

S points.

5. Sensor light according to claim 4, characterized in that the sensor housing frontally a the detection range of the motion sensor unit erwei-

ID ternden additional lens area (26).

6. Sensor light according to one of claims 1 to 5, characterized in that the sensor light is designed so that in response to a decrease in the

IS motion sensor unit of the mounted and ready to use carrier unit, the light unit in a predetermined activation state, in particular continuous light, is activated.

ED

7. Sensor light according to one of claims 1 to 6, characterized in that at least one predetermined, program-like predetermined control parameter set for a lighting operation of the sensor lamp and / or detection conditions of the loading by the actuating element

Weg5 motion sensor unit can be set or selected.

8. Sensor light according to one of claims 1 to 7, characterized in that the motion sensor unit comprises a four infrared-sensitive sensor

Having 3D elements having sensor (22), wherein the sensor elements are assigned separately in pairs each having a signal electronics branch and are evaluated so that a detection signal of the branches activation of the light unit

35 causes.

9. Sensor light according to claim 8, characterized in that the sensor (22) provided in a sensor housing (14) of the motion sensor unit, a

A plurality of faceted mirrors (24) is assigned.

10. Sensor light according to one of claims 1 to 9, characterized in that the motion sensor unit has a detection angle of 360 °.

ID

11. Sensor light according to one of claims 1 to 10, characterized in that the motion sensor unit comprises means for adjusting a detection range, in particular by varying the position

IS a cooperating with a sensor of the motion sensor unit mirror unit.

12. Sensor light according to one of claims 1 to 11, characterized in that the movement

SensorD sensor unit has a memory unit configured for storing operating parameters and an interface assigned to it, which in the detached state accessing the operating parameters, in particular by means of a to the interface

SS Ie connectable data processing device allowed.