DE3540680A1 - Passive infrared movement receiver - Google Patents

Abstract

The invention relates to a passive infrared movement receiver for switching lighting on and/or off, having an infrared detector (3) and a light-sensitive element (7), an analog/digital converter (6) being connected downstream of the infrared detector (3), possibly via one or more amplifier stages (4, 5), and the light-sensitive element (7) being connected via one or more evaluation stages, which together form a twilight switch arrangement (8) to the input (11) of an AND logic circuit (12), and the analog/digital converter (6) being connected to another input (14) of the AND logic circuit (12), and in the case of which a signal is emitted to the output (15) of the AND logic circuit (12) when a signal is present at both inputs (11, 14). In order to make the infrared movement receiver retriggerable, that is to say sensitive to a plurality of movements of a measurement object taking place at time intervals, an OR logic circuit (16) is connected downstream of the AND logic circuit (12), and a timing element (18) which controls the load switch (21) is connected downstream of the OR logic circuit (16). In this way, the load switch remains closed as long as the infrared detector (3) detects movements of a measurement object, for example a plurality of people entering the response area of the infrared detector (3) successively, even when the light-sensitive element (7) is "seeing" the previously reported "light". <IMAGE>

Description

The invention relates to a passive infrared motion receiver with an element focusing infrared radiation, in particular Fresnel lens, which emanates from a measurement object Infrared radiation is focused on an infrared detector that detects the Converts infrared radiation into electrical signals, and one alongside the focus of the focusing element arranged photosensitive Element for measuring the ambient brightness, which at a adjustable threshold for the ambient brightness emits a signal, one or more in series with the infrared detector Amplifier stages to amplify the weak, from the infrared detector incoming signals and to suppress interference (network or Radio interference) are switched and to the output of the last one An analog / digital converter is connected to the amplifier Size of the amplified signal of the infrared receiver with a adjustable threshold compares and emits a signal as soon as that Signal exceeds this threshold that the output of the analog / Digital converter to an input of an AND logic circuit and the output of the photosensitive element possibly over several Evaluation stages, which together form a twilight switch arrangement, connected to the other input of the AND logic circuit is that only at the output of the AND logic circuit Output signal is given when at the corresponding input for the infrared detector and the input for the light sensitive Element there is a signal.

DE-OS 32 25 264 is an infrared motion receiver become known of a room lighting depending on the Automatically switches on the presence of a person. For this is an Infrared detector in the focus of a focusing element available, which is the body radiation of one in the room Person receives. Furthermore, a light sensor for measuring the Room lighting available. In this device, the lighting should can only be switched on if the light sensor on the one hand insufficient room lighting and on the other hand the infrared Detector reports a moving person.  

Infrared detector and light sensor are therefore Link interconnected. In this known device however nothing to be inferred whether after switching on for the first time the lighting, d. H. the infrared detector has a moving one Person reported and the light sensor has an insufficient Room lighting displayed, further movements or people also with sufficient lighting can be detected, namely when the Light sensor measures the light that the device previously turned on Has.

The object of the invention is that described in the introduction Improve the functionality of infrared motion receivers, in particular to make it retriggerable.

The object is achieved according to the infrared motion receiver of the type identified at the beginning by the in the characteristic of the Main measures listed resolved. Further training of the Invention are described in the subclaims.

The advantage of the training according to the invention is that the Load switch remains closed as long as the infrared detector Detects movements even if the photosensitive element previously reported "light" "sees", i.e. H. if the infrared Movement receiver is located near the connected lamp.

According to claim 2 is prevented that disturbances when switching off the Load switch, for example switching sparks at the relay, no renewed Trigger the sensitive evaluation electronics. It takes place So for a certain period of time a "locking" of the motion receiver. This makes it possible to switch relatively large loads.

According to claim 3, the threshold for the infrared Set detector incoming signal in a simple way.

The advantage of claim 4 is that for the optical and optoelectronic part of the motion receiver a common Bracket and adjustment of the lens and the infrared detector can be done so that on the one hand when inserting the Fresnel lens and the circuit board on the other hand the correct distance  automatically produced between Fresnel lens and infrared detector becomes. The fact that on the circuit board that contains the infrared Detector carries, also the downstream of the infrared detector Amplifier stages are arranged, the very weak electrical signals from the infrared detector via a short line be fed to the amplifier so that on the connecting line disturbances are reduced.

According to claim 5, a pre-assembled unit of the optical, optoelectronic and electrotechnical assemblies manufactured.

Below is an embodiment of the drawing Invention described in more detail. Show it:

Fig. 1 is a schematic representation of the circuitry of the receiver according to the invention movement,

Fig. 2 is an exploded view of the mechanical structure of the motion receiver.

The circuit arrangement according to FIG. 1 of the drawing consists of the infrared detector ( 3 ), a bandpass filter ( 4 ) connected downstream of the infrared detector ( 3 ) and an amplifier ( 5 ) connected downstream of the bandpass filter, which is connected to a window comparator ( 6 ) .

The infrared detector ( 3 ) absorbs the heat radiation from bodies and converts them into electrical signals, which are amplified by the bandpass filter ( 4 ) and disturbances that do not result from moving bodies, e.g. B. line hum voltages or radio interference can be suppressed. The interference-suppressed useful signal is further amplified by the amplifier ( 5 ). With the help of the window comparator ( 6 ) the level of the amplified useful signal is compared with a fixed threshold and a signal is emitted if the useful signal exceeds this threshold.

The light-sensitive element ( 7 ) is arranged parallel to the infrared detector ( 3 ) and forms a twilight switch ( 8 ) with an adjustable response threshold ( 9 ), which emits a signal at an adjustable ambient brightness, by means of further downstream, known assemblies. The twilight switch ( 8 ) is continuously adjustable from approx. 7-1000 lx and can also be switched off with the same adjuster ( 9 ), so that the infrared detector ( 3 ) can also be used alone, e.g. B. in daylight can be used.

The output ( 10 ) of the photosensitive element ( 7 ), which can be a photodiode or a phototransistor, is connected to the first input ( 11 ) of an AND gate circuit ( 12 ) and the output ( 13 ) of the window comparator ( 6 ) is connected to the second input ( 14 ) and AND logic circuit ( 12 ). The AND logic circuit ( 12 ) only emits a signal at its output ( 15 ) when the ambient brightness set with the adjuster ( 9 ) has been reached and movement has been detected by the infrared detector ( 3 ). This will be discussed in more detail below.

The following circuit arrangement consists of the OR logic circuit ( 16 ), a further AND logic circuit ( 17 ), a first timer ( 18 ) with adjuster ( 19 ), a second timer ( 20 ) and the load switch ( 21 ), in which it is a relay. The interconnection of the individual modules is as follows: The OR logic circuit ( 16 ) has an input ( 22 ) to the output ( 13 ) of the window comparator ( 6 ), and a second input ( 23 ) to the output ( 15 ) of the AND Linking circuit ( 12 ) and connected with a third input ( 24 ) to the node ( 25 ), to which the output of the timer ( 18 ), the input of the timer ( 20 ) and the input ( 26 ) of the load switch ( 21 ) are connected. The unspecified output of the OR logic circuit ( 16 ) is connected to an input ( 27 ) of the AND logic circuit ( 17 ) and its second input ( 28 ) to the output ( 29 ) of the timing element ( 20 ). The output of the AND logic circuit ( 17 ) is connected to the input of the timer ( 18 ).

The OR logic circuit ( 16 ) controlled via the output of the timer ( 18 ) and the input ( 24 ) depending on the switching state of the load switch ( 21 ) ensures that further movements can be detected by the infrared detector ( 3 ), even if the twilight switch ( 8 ) "sees" the light that was switched on by the load switch ( 21 ). Due to the retriggerability with the aid of the OR logic circuit ( 16 ) and the timer ( 18 ), the load switch ( 21 ) is kept closed as long as the infrared detector ( 3 ) detects "movements" in its response range.

With the help of the timer ( 18 ), the duty cycle of the load switch ( 21 ) can be determined after the last movement in the monitoring area has been detected. It can be adjusted using the adjuster ( 9 ), for example from 12 sec to 12 min.

Through the AND logic circuit ( 17 ) in conjunction with the timer ( 20 ) is a "lock" of the load switch ( 21 ) for a certain time, for. B. for 2 seconds, so that malfunctions that may occur when the load switch ( 21 ) is switched off (switching sparks at the relay) do not trigger the sensitive evaluation electronics again. With the help of the voltage supply circuit ( 30, 31 ) the supply voltage for the infrared motion receiver is generated from the mains voltage.

Fig. 2 shows the mechanical structure of the infrared motion receiver. The infrared motion receiver designed as a surface-mounted device consists of the lower housing part ( 32 ), the upper housing part ( 33 ), a first circuit board ( 34 ) with the modules ( 12, 16, 17, 18, 20, 21 and 30 ) and not shown Terminals. The circuit board ( 34 ) is connected via the line ( 35 ) to the second circuit board ( 36 ) which carries the modules ( 3, 4, 5, 6, 8 and 31 ).

The infrared motion receiver also contains a Fresnel lens system ( 37 ) in the form of a flexible film, for. B. made of polyethylene, and a focusing frame ( 38 ) made of insulating material for holding the Fresnel lens film ( 37 ) and the circuit board ( 36 ).

The circuit board ( 34 ) is connected to the focusing frame ( 38 ). For mounting and connection, the frame has molded feet ( 40 ) with which it is supported on the circuit board ( 34 ) and fastened with screws. The holes ( 41 ) provided in the board ( 34 ) are used for this.

A total of three feet ( 40 ) are provided, of which only two are visible due to the perspective in FIG. 2.

At the front of the frame opening there is a radius-shaped receptacle ( 42 ) into which the Fresnel lens film ( 37 ) is inserted from the rear. The film lays against the inner walls of the radius and engages with the non-curved longitudinal sides behind locking projections, which are not described in any more detail. As a result, the film is pressed into the curvature under tension and lies flush at every point in the receptacle, so that the focal points of all the individual lenses of the lens system coincide in a common focal point.

As can be seen from FIG. 2, the Fresnel lens film ( 37 ) has three lens planes, of which the upper five, the middle four and the lower three have individual lenses. This results in twelve response zones, which are fan-shaped at different horizontal and vertical angles, so that, for example, a person can enter a response zone, as a result of which the change in the infrared radiation intensity caused by the movement within the response zone for switching on and / or off the Lighting is evaluated.

The front of the upper housing part ( 33 ) is inclined to the vertical. Correspondingly, the Fresnel lens film ( 37 ) is adapted to the inclination in that the receptacle ( 42 ) is also designed to be inclined. Parallel to the Fresnel lens film ( 37 ), the circuit carrier board ( 36 ) with the infrared detector ( 3 ) is inserted into the rear frame opening of the focusing frame ( 38 ) and held by latching elements (not shown in more detail).

The circuit board ( 34 ), the focusing frame ( 38 ) with the Fresnel lens film ( 37 ) and the circuit board ( 36 ), as already described above, form a structural unit that is loosely inserted into the lower housing part ( 32 ).

The protective film ( 39 ) made of dimensionally stable, infrared and translucent material has a trough-like shape with a circumferential sealing edge ( 43 ). It is inserted with the sealing edge into the upper housing part ( 33 ) and is supported with the edge on a circumferential sealing edge ( 44 ) in the parting plane of the housing. In addition, a soft elastic seal, not shown, can be inserted between the sealing edge and the sealing edge. The protective film ( 39 ) is shaped so that the receptacle ( 42 ) of the focusing frame ( 38 ) fits flush into the trough. Furthermore, the inside of the upper part ( 33 ) is shaped such that the back of the protective film ( 39 ) fits tightly against the inner contour of the upper part ( 33 ), with the smallest possible gap between the window ( 45 ) and the back.

On the circuit board ( 34 ) there are actuators ( 9, 19 ) on the long sides for setting the switch-on threshold of the twilight switch and the switch-on time. The actuators ( 9, 19 ) engage with their actuating means ( 46 ) in guide bores ( 47 ) of brackets ( 48 ) molded onto the feet ( 40 ). The consoles ( 48 ) can be designed on the sides facing the upper housing part ( 33 ) as scale carriers which have a lux scale or a time scale.

Claims (5)

1. Passive infrared motion receiver with an infrared radiation focusing element, in particular Fresnel lens, which focuses the infrared radiation emanating from a measurement object on an infrared detector, which converts the infrared radiation into electrical signals, and one next to the Focus of the focusing element arranged light-sensitive element for measuring the ambient brightness, which emits a signal at an adjustable threshold for the ambient brightness, one or more amplifier stages in series with the infrared detector for amplifying the weak signals coming from the infrared detector and for suppressing them of interference (network or radio interference) and an analog / digital converter is connected to the output of the last amplifier, which compares the size of the amplified signal of the infrared receiver with an adjustable threshold and emits a signal as soon as the signal exceeds this threshold , that the output of the analog / digital converter is connected to an input of an AND logic circuit and the output of the light-sensitive element, possibly via several evaluation stages, which together form a twilight switch arrangement, to the other input of the AND logic circuit, that at the output of the AND logic Linking circuit is only an output signal when a signal is present at the corresponding input for the infrared detector and the input for the light-sensitive element, characterized in that the AND gate circuit ( 12 ) is an OR gate circuit ( 16 ) and the OR Logic circuit ( 16 ) is followed by a timer ( 18 ), the output of which is connected to a load switch ( 21 ), that the output ( 15 ) of the AND logic circuit ( 12 ) is connected to an input ( 23 ) of the OR logic circuit ( 16 ) , the output ( 13 ) of the analog / digital converter ( 6 ) to another input ( 22 ) of the OR link tion circuit ( 16 ) and the output of the timer ( 18 ) is connected to a further input ( 24 ) of the OR logic circuit ( 16 ). 2.) Passive infrared motion receiver according to claim 1, characterized in that between the OR logic circuit ( 16 ) and the timing element ( 18 ) a further AND logic circuit ( 17 ) is connected, which has an input with the output of the OR- Linking circuit ( 16 ) and connected to the output at the input of the timing element ( 18 ), that the output of the timing element ( 18 ) is connected to the input of a second timing element ( 20 ), the output ( 29 ) of which is connected to the second input ( 28 ) the AND logic circuit ( 17 ) is connected. 3.) Passive infrared motion receiver according to claim 1 or 2, characterized in that the analog / digital converter ( 6 ) is designed as a window comparator. 4.) Passive infrared motion receiver with an element that focuses the infrared radiation, in particular a Fresnel lens system, consisting of a radius-shaped curved film which is arranged such that the focal points of all Fresnel lenses coincide in a common focal point, in which the infrared -Detector is arranged according to one of claims 1 to 3, characterized in that the infrared detector ( 3 ), the amplifier group ( 4, 5 ), optionally the analog / digital converter ( 6 ) and the light-sensitive element ( 8 ) a common circuit carrier board ( 36 ) are arranged and the circuit carrier board ( 36 ) is inserted in a focusing frame ( 38 ) carrying the Fresnel lens film ( 37 ) and defining the curvature of the film so that the infrared detector ( 3 ) is at the focal point of the Fresnel -Lenses lies. 5.) Passive infrared motion receiver according to claim 4, characterized in that the focusing frame ( 38 ) with feet ( 40 ) on one of the AND logic circuit ( 12 ), the OR logic circuit ( 16 ), the timing elements ( 18, 20 ) , The voltage supply ( 30, 31 ) and the load switch ( 21 ) receiving circuit board ( 34 ) is attached.