DE19504606C2 - Optoelectronic device for detecting precipitation which is deposited on the outside of a transparent pane - Google Patents

Description

The present invention is based on a Preamble of the main claim designed to Er version of the degree of wetting of a transparent Disk with z. B. drop-shaped present low proposed device from optoelek tronic base works.

Such devices are designed to the reflected on the disc per unit of time Moisture quantitatively in a representative form grasp and depending on one of the disc assigned electrically operated system automatically influence.

By DE 32 03 091 A1, DE 33 14 770 C2 and EP 0 249 031 A2 are devices for optoelectrics tronic detection of existing on a disc Foreign substances become known, for example for Control a motorized windshield wiper system can be used by one blasting emit rays emitted into the transparent pane coupled in and after at least one reflection decoupled the outer surface of the disc pelt and ge to an assigned radiation receiver be directed. The rays can over at least one attached to the inner surface of the disc brought guided radiation body and into the pane be coupled in and out of the same. A sol For radiation protection reasons or Ensuring a perfect measurement together with the radiation transmitter and the radiation receiver ger be arranged in a housing, the same to be attached to the inner surface of the disc.

However, such a facility is not straightforward usable for panes where there are no agents are present, through which the disc in a given the degree of wetting is freed from precipitation, after which a new measuring cycle is then initiated.

In addition, DE 33 14 770 C2 is one of the features of the preamble of the main claim, also for optoelectronic detection of device provided on a disc of existing precipitation known.

The existing one from a phase-selective rectifier connected differential element and a downstream one, with a electrical device connected comparator stage is existing circuit part but only intended to be used once for a short time bring associated electrical device (wiper motor) and that is, when otherwise affecting the electrical device performing control stage was not in use for a long time and therefore on the same there are no defined relationships.

In addition, WO 87/05115 is one with natural or artificial Optoelectronic sensor device operating in ambient light has become known, in which there are two radiation detectors connected in series, their common connecting line a zero crossing amplifier circuit stage having two circuit branches and an associated, d. H. connected to the two circuit branches, with two Schmitt triggers provided signal processing level is assigned, via which a cooperating electrical device can be influenced by control stage. The two available there, e.g. B. each provided with a capacitor Circuit branches are not to be regarded as differentiators, but only serve and only to each of the two present in the two circuit branches Amplifier only let through depending on the cutoff frequency, rely on one by the related to both radiation detectors certain voltage reference Supply measurement signals and in such a way that the one amplifier of the Reference magnitude and positive contrasting changes in voltage others that differ negatively from the reference value Changes in tension intensified. By means of an inverting stage either inverting the positive or negative amplified measurement signals and the measurement signals of both circuit branches are then one each Schmitt trigger representing the comparator stage, which is then dependent of predetermined threshold values via an OR element an electrical device head for.

A transfer of the teaching on which this previously known subject is based on optoelectronic sensor device provided for precipitation detection does not offer itself at all and does not easily lead to that of Principle underlying the present invention.

This is further supported by the fact that such a system is passive and therefore not to record the degree of wetting of a pane with precipitation suitable is.

Finally, DE 29 48 521 A1 in turn has a natural or sensor device operating under artificial ambient light, at a radiation detector u. a. one of two connected in anti-parallel Comparators existing comparator stage is connected. The one from this generated signal pulses can be adjusted by a time step a signal dead time Length connected within which another signal is not counted to for tasks such as B. short-term vehicle counts every object only to assign exactly one count.

The object of the present invention is to achieve reasons, an optoelectronic device of the one gangs mentioned in such a way that without With the help of additional, the degree of wetting the disc changing agent a flawless Er version of the same and thus one depending there of standing influence of an assigned elec trically operated device is feasible.

According to the invention, the task is performed by specified part of the main claim Features resolved. Advantageous in such a case Structure is that one easily - even afterwards before increasing - assignment of the actual Sen sors to (already installed) transparent panes is guaranteed so that depending on occur influences related to precipitation ordered, electrically operated devices - such. B. retractable and extendable awnings by electric motor - are feasible.

Other particularly favorable configurations of the inventive subject are in the Unteran sayings and are based on one in the Drawing shown embodiment closer explained.

It shows

Fig. 1 assigned to an electrically operated device optoelectronic device with associated circuit components

Fig. 1a-1f the signal curves formed by certain circuit components.

As can be seen from Fig. 1, on the inside 1 b of a with its outside 1 a occurring low impact exposed transparent disc 1 a beam lenleitkörper 2 is held by suitable adhesive. The radiation guide 2 are on the one hand two radiation emitters 3 designed as light emitting diodes and on the other hand two radiation detectors 4 designed as photodiodes are assigned.

The spectrum of those used in this arrangement Rays are preferably in the infrared range.

On the input side, the radiation transmitters 3 are connected on the one hand to ground and, on the other hand, to the voltage supply U _B via a compensation element 17 and a control element 18 and a clock stage 19 . The clock stage 19 ensures that the beams are emitted from the radiation transmitter 3 in a clocked form, which means that interference caused by infrared components of the ambient light is eliminated. The compensation member 17 is provided to compensate for the temperature transition of the transmitter formed by the light emitting diodes. Advantageously, the control element 18 is also inserted into this connection, with which the aging effect of the light-emitting diodes in particular is compensated for. This control element 18 is connected with its measuring input to the output of a phase-selective rectifier 7 described later.

The two output side associated with the light conducting body 2, receiver as photodiodes formed beams 4 are on the one hand to the supply clamping voltage U _B and on the other hand in each case one filter stage 5 ', 5 "and 5 ^*, 5 ^** connected via an I / U converter. 6 the two filter stages always consist of egg nem one hand connected to ground and the other connected to the radiation receiver 4 resistor 5 ', 5 ^* and each one the one hand, also connected to the radiation detector 4, and on the other hand to the one input of the I / V converter 6 connected capacitor 5 ", 5 ^** . The output of the I / U converter 6, which is connected to ground at its input, is connected to an input of a phase-selective rectifier 7 , which is also influenced by the clock stage 19 via the associated connecting line.

It arises at the output of the rectifier 7 depending on the respective precipitation conditions, for. For example, the voltage curve U _G shown in FIG. ₁ a over time t, during which time t ₁ disc 1 is continuously subjected to drop-shaped precipitation (rain) in an increasing manner, and during period t ₂ a there is a constant relationship between a further exposure and a simultaneous drying of the pane by external influences, and finally there is an excess weight in relation to the drying over the further exposure during the time period t ₃ .

This output voltage U _{G of} the rectifier 7 is supplied via a signal processing stage 9 and a Fil terstufe 10 a, 10 b a differentiator 11 . Depending on the positive or negative gradient of the output voltage U _{G from} the rectifier 7, this provides a corresponding output signal U _D ( FIG. ₁ b), which corresponds to the duration t ₁ and t _{3 of} the respective change in the output voltage U _G from Rectifier 7 has corresponding signal components which are above a reference level B when the output voltage U _G rises negatively and below a reference level B when the gradient rises.

The upstream of the differentiator 11 signal processing stage 9 consists of one with its one input connected to the output of the rectifier 7 NEN operational amplifier, the other input via an adjustable, from the resistors 8 a, 8 b formed voltage divider on the one hand at the supply voltage U _B and on the other hand is connected to ground. At the output of the operational amplifier is formed from a resistor 10 'and a capacitor 10 "ge low-pass filter stage on the one hand ruled out, which is also connected to the input of the differentiating member 11 .

At the output of the differentiator 11 is now one of two antiparallel switched comparators 14 a, 14 b existing comparator stage 14 is connected, the two other inputs of the comparators each having one of the resistors 12 a, 12 b and 13 a, 13 b existing adjustable voltage dividers are connected to the supply voltage U _B and to ground.

At the output of the comparators 14 a, 14 b are due to the anti-parallel switching device shown in FIGS. 1c and 1d, an equal pulse height and one compared to the duration t ₁ and t _{3 of} the respective change in the output voltage U _{G of} the rectifier 7 due to the comparator thresholds U _S1 and U _S2 slightly reduced pulse length t ₁ or t ₃ , having voltage pulses U _Ka, U _Kb , which then lead to the voltage curve U _K shown in FIG. 1e at the output of the comparator stage 14 . At the output of the comparator stage 14 , a time stage 15 is connected, which preferably consists of a counter which detects the output signals of the comparator stage 14 and at least one retriggerable time switch. Based on this, the signal curve shown in FIG. 1f is achieved, namely by the time delay t _v (t _{v '} ) realized, ie over the time period t ^* , the signal U _Z is present at the output of the time stage 15, which of the downstream control stage 20 is fed. From this, preferably provided with power semiconductor switching elements, control stage 20 , the associated electrically operated device 21 is influenced accordingly. The duration of the operation of the control stage 20 and thus of the electrically operated device 21 is indicated by a function display element 22 preferably formed as a light-emitting diode.

In order to illustrate the optimal signal level of the above-be signed circuitry at the input of the differentiating member 11 is connected a Fensterkom parator 16, which is connected to a, the signal level gel indicated solubilizing, preferably consisting of a light emitting diode device 23rd

With such a construction of a circuit arrangement, it is advantageous to combine the circuit components 11 to 19 in a microcomputer 25 .

Claims (13)

1. Optoelectronic device for detecting precipitation deposited on the outside of a transparent pane, wherein on the inside of the pane there is a radiation guide body cooperating with at least one radiation transmitter and at least one radiation receiver, the beams emitted by the radiation transmitter in clocked form after at least one the outside of the pane, depending on the reflection occurring on the same amount of precipitation, is fed to the radiation receiver, the output of which is connected to a circuit arrangement which comprises an I / U converter which amplifies the alternating component of the output signal of the radiation receiver and a clocked component of the output signal of the I / U converter has narrow-band filtering and directing phase-selective rectifier, which is followed by a differentiator, the output of which is connected to an input of a comparator stage which is connected to a di e change in the amount of precipitation reacting electrical device is connected, characterized in that the differentiating element ( 11 ) delivers a corresponding output signal (U _D ) depending on the positive or negative gradient of the output voltage (U _G ) of the rectifier ( 7 ), which the duration (t ₁ , t ₃ ) of the respective change in the output voltage of the rectifier ( 7 ) has corresponding signal components which are above a reference level (B) in the event of a negative rise in the output voltage and below a reference level (B) in that the comparator stage ( 14 ) is off the output signal (U _D ) of the differentiating element ( 11 ) forms positive signal pulses (U _Ka , U _Kb ) with the same pulse height, the respective pulse length (t _{1 '} , t _3' ) of the associated duration (t ₁ , t ₃ ) of each underlying signal components of the output signal of the differentiator ( 11 ) corresponds approximately and that the two anti parallel comparators ( 14 a, 14 b) existing comparator stage ( 14 ) is connected to the input of a time stage ( 15 ) evaluating the signal pulses of the comparator stage with a time delay (tv), the output of which is assigned to the electrical device ( 21 ) at the input , the same is connected as a function of the control stage ( 20 ) influencing the evaluated signal pulses. 2. Optoelectronic device according to claim 1, characterized in that the time stage (15) consists of a counting the signal pulses (U _Ka , U _Kb ) of the comparator stage ( 14 ) and at least one retriggerable timer. 3. Optoelectronic device according to claim 1 or 2, characterized in that the two comparators ( 14 a, 14 b) of the comparator stage ( 14 ) each with one of its two inputs, one on the one hand at the supply voltage (U _B ) and on the other hand to ground adjustable voltage dividers ( 12 a, 12 b and 13 a, 13 b) are connected. 4. Optoelectronic device according to one of claims 1 to 3, characterized in that a low-pass filter stage ( 10 ', 10 ") is inserted between the output of the phase-selective rectifier ( 7 ) and the input of the differentiator ( 11 ). 5. Optoelectronic device according to one of claims 1 to 4, characterized in that between the output of the phase-selective rectifier ( 7 ) and the input of the differentiator ( 11 ) a signal processing stage ( 9 ) is inserted, which consists of an operational amplifier, one of which Input is connected to the output of the phase-selective rectifier ( 7 ) and its other input is connected to a voltage divider ( 8 a, 8 b) on the one hand at the supply voltage (U _B ) and on the other hand at ground. 6. Optoelectronic device according to one of claims 1 to 5, characterized in that the beam transmitter ( 3 ) consisting of a radiation-emitting light-emitting diode is assigned a compensation element ( 17 ) compensating for the temperature response of the light-emitting diode. 7. Optoelectronic device according to claim 6, characterized in that the compensation element ( 17 ) between the radiation transmitter ( 3 ) and the upstream clock stage ( 19 ) is inserted. 8. Optoelectronic device according to one of claims 1 to 7, characterized in that the radiation transmitter ( 3 ) consisting of a radiation-emitting light-emitting diode is assigned a control element ( 18 ) which compensates in particular for the aging effect of the light-emitting diode. 9. An optoelectronic device according to claim 8, characterized in that the control member (18) interposed between the compensation member (17) of the clock circuit (19) and is connected to the output of the phase-selective rectifier (7). 10. Optoelectronic device is connected to one of claims 1 to 9, characterized in that at the input of the differentiating member (11) is a window comparator (16) is connected, with an optimal signal level of the circuit configuration indicated solubilizing component (23). 11. Optoelectronic device according to claim 10, characterized in that the component ( 23 ) consists of a light emitting diode. 12. Optoelectronic device according to one of claims 1 to 11, characterized in that the control stage ( 20 ) of the electrical device ( 21 ) is assigned a function display element ( 22 ) designed as a light-emitting diode. 13. Optoelectronic device according to one of claims 1 to 12, characterized in that some of the circuit components ( 11 to 19 ) provided for evaluating and processing the supplied physical quantities are integrated in a microcomputer ( 25 ).