DE3031093A1 - Brightness control potentiometer for vehicle dashboard - has resistance assembly with photoelectric component in differential stage, parallel to resistor - Google Patents

Abstract

The potentiometer or rheostat is intended for brightness control of the illumination of instruments in motor vehicles, aircraft, ships etc. The control assembly has a housing containing an electronic frequency generator and an electronic differential stage with a resistance assembly, the latter comprising a variable resistor for digital control of the connected load (illumination). Thus the load is switched in a relatively high switching sequence or frequency. The resistance assembly (RIV) contains a photo-electric component (F), in parallel to a resistor (R5') with which it is connected to earth (110). Pref. the resistor is of control type. Alternately it may be of a fixed type. The frequency generator and the differential state may consist of two series-connected Schmitt triggers, or of an integrated circuit and two NAND-Schmitt triggers.

Description

Potentiometer or rheostat for brightness control or

Regulation in particular of the instrument lighting in motor vehicles, Airplanes, ships and the like according to patent ... (patent application r 30 14 193.6-33) The invention relates to a potentiometer or a rheostat according to patent ... (patent application P 30 14 193.6-33) and has become a further improvement of such a device set as a goal.

So far, for the brightness control of the instrument lighting in motor vehicles usually a manually adjustable potentiometer Rotary or sliding resistance is used, in which, however, a relatively high power dissipation which is given off as heat. This is particularly disadvantageous when vehicles equipped with such a potentiometer or rheostat high outside temperatures are operated in midsummer weather and longer Uninterrupted solar radiation can also occur in the temperate latitudes can. Due to the high heat emission can adjacent materials and other circuit parts, e.g.

other electronic components that are particularly sensitive to heat, are impaired in their function.

With the main patent (patent application P 30 14 193s6-331 was therefore proposed an electronic potentiometer with a much lower power loss to create that with an electronic frequency generator and an electronic Differentiation stage with a resistor arrangement with variable resistance for digital control of the connected load is designed in such a way that the connected -Load in a relatively high switching sequence or frequency continuously switched on and off will.

With this electronic potentiometer, the brightness of the instrument lighting can only be changed by hand. This can be particularly difficult when the brightness of the instrument lighting is proportionate in bright ambient light is set strongly and the vehicle suddenly moves into an area with little ambient light drives into an underpass or tunnel, for example, where speed restrictions are also frequent which must be carefully observed by the driver. It is then a additional stress when the driver first darkens the instrument lighting must adjust to the instruments even under the deteriorated ambient light conditions to be able to read glare-free.

The invention is based on the object, the potentiometer or the To further improve rheostats according to the main patent that the brightness control or regulation takes place automatically depending on the ambient light.

This task finds its solution with a potentiometer or rheostat according to the preamble of claim 1 according to the invention essentially in that the resistor arrangement in the electronic differentiating stage having photoelectronic component which is connected in parallel to a Wierstands component is and is with this at the Uasse connection.

Any component can be used as a photoelectronic component that has a sufficient reaction speed, like a photodiode, a phototransistor, a photoresistor or the like, and the resistor component connected in parallel can either be a fixed resistor or a rheostat, which is mainly depends on whether the brightness control or

Regulation by the photoelectronic component alone or in addition should still be done by manual intervention on the resistance component, e.g. to adjust the basic brightness of the instrument lighting to the different Adjust ambient light conditions in the different seasons.

The maximum duty cycle (ED) of the connected as an external load Instrument lighting or the like can according to a further feature of the invention can be improved by the fact that the control input of the second Schmitt trigger to the frame dividing point of the resistor arrangement functioning as a voltage divider is connected according to the features of claim 4, so that the between the output of the first Schmitt trigger and the voltage dividing point of the resistor Takes over a protective function for the output of the first Schmitt trigger.

The advantages achieved by the invention are in addition to the simple ones automatic regulation of the connected external load in that the duty cycle (ED) for the external load within wide limits, from e.g. 5% ED (duty cycle) to 100% ED, via the resistor arrangement in the differentiating stage with a photoelectronic component with negligible low power dissipation can be determined very precisely.

A low duty cycle of e.g. 5% ED of the external load means in the case of incandescent lamps as consumers, that the incandescent lamps only have a low brightness output, and a long duty cycle of e.g. 100% ED means accordingly a high brightness of the incandescent lamps, as these are constantly current-carrying.

It also allows the possibility of parallel to the photoelectronic Provide a fixed resistor to the brightness of the connected component Making instrument lighting dependent only on ambient light, a significant cost saving, because the entire mechanics, otherwise for a manual adjustment of the potentiometer or rheostats is required, can be omitted.

Preferred embodiments of the invention are shown in the drawing shown schematically. 1 shows a logic circuit diagram for an electronic Potentiometer with automatic brightness control by a photo-electronic Component and FIG. 2 shows a connection diagram using a photoelectronic Component in connection with an integrated circuit with two NAND Schmitt triggers for automatic brightness control.

The electronic potentiometer with automatic brightness control by a photoelectronic component Fi, the one Photodiode, a photoresistor, a phototransistor or the like, consists of five Assemblies between a supply line 101 and one or more ground connections 110 or

110 ', 11011, 110111, for example to the direct current on-board network of a Vehicle with an operating voltage of 12 volts or, if necessary, up to 24 Volts are connected: 1) A voltage stabilization stage I, which is used to exclude voltage fluctuations that occur in the vehicle's electrical system; 2) an interference voltage suppression stage II; 3) a frequency generator III for generating the switching sequences or frequency of the potentiometer; 4) a differentiation level IV to change the duty cycle, 5) an amplifier stage V with two transistors for current amplification.

The logic circuit of the electronic potentiometer is shown in Fig. 1 is structured as follows: The voltage stabilization stage I exists from a resistor R1 and a Zener diode Z1 connected in series with it, the in a line 102 between the supply line 101 from the vehicle electrical system and the ground terminal 110 lie. From the output of the voltage stabilization stand @@@ R1 and the Zener diode Z1 leads a Leituna 103 to the frequency generator III and the differentiating stage IV. Between the line 103 and the ground terminal 110 is located in a line 104 a capacitor C1 with its positive pole, that of the suppression of interference voltages is used. In addition, to line 103 via lines 105, 106 two logic inputs E1, E2, El ', E2' of two Schmitt triggers S1, S2 connected.

The first Schmitt trigger S1 has a high-resistance control input H, which is connected to the positive pole of capacitor C2 is. Of the The negative pole of the capacitor C2 is connected to the ground connection 110 via a line 105 '. In addition, the input H is connected to the output A of the first via a resistor R2 Schmitt trigger S1 connected. Another resistor is parallel to the resistor R2 Resistor R3 with a diode D1 in series, the diode D1 with its cathode is also at the output A of the first Schmitt trigger S1.

In the connecting line 120 between the output A of the first Schmitt trigger S1, which at the same time the output of the frequency generator III ..i.ldet, and the high impedance Input H 'of the second Schmitt trigger S2 is a capacitor C3 in series with the resistor R4, the positive pole of the capacitor C3 at the output A of the first Schmitt Trlggers and the negative pole of the capacitor C3 with one Side of resistor R4 is connected. The second side of the resistor R4 lies at the control input H 'of the second Schmitt trigger. The electrical connection between the resistor R4 and the high-resistance control input H 'simultaneously represents the voltage divider point 121 of a resistor arrangement R IV functioning as a voltage divider, which consists of the resistor R4, connected in series with a photoelectronic component F1, which in turn is connected in parallel to a further resistor R5 ', consists.

The resistor arrangement R IV in the electronic differentiating stage IV consists of a photo-electronic component F1 and one connected in parallel to it Resistance component R5 ', which in the exemplary embodiment of FIG. 1 as a Resel resistor is shown, but also as a fixed resistor as shown in Fig. 2, formed can be.

The photoelectronic component connected in parallel with the resistor R5 ' F1 is on one side via a line 106 'to the ground terminal 110, while the other side of the resistor array R IV to the voltage divider point 121 is connected.

The output A 'of the second Schmitt trigger S2 leads via a resistor R6 to the base of a first npn transistor T1, the collector of which has a resistor R7 and a line 107 is connected to the lead 101, while the emitter of the npn transistor T1 is connected to the ground terminal 110 via a line 107 '.

A line 108 also leads from the collector of transistor T1 a resistor R8 on the base of a second pnp transistor T2, which is called a Darlington transistor consists of two pnp transistors connected in cascade, which are arranged in a common housing. The Darlington transistor T2 is connected with its emitter via a line 109 directly to the lead 101, during the Collector of the second transistor T2 to the supply line 109 'for the external load 111 is connected, which in the exemplary embodiment shown consists of a number of parallel-connected incandescent lamps 112, 113, 114, each separately a ground connection 110 ', 110 ", 110"'.

The electronic potentiometer described above works like follows: The possibility of transferring voltage fluctuations from the vehicle electrical system via the line 101 or 102 to the electronic potentiometer is through the Voltage stabilization of the resistor R1 and the Zener diode Z1 in the line 103 excluded.

The stabilized voltage arrives at the frequency generator via line 103 III and the differentiation stage IV, with interference voltages with high Frequency can be suppressed by the arranged in the line 104 capacitor C1.

The frequency generator III, which consists of the high-resistance Schmitt trigger S1 and the RC combination of capacitor C2 and resistor R2 is generated the frequency necessary to control the external load 111. About those in the generator circuit lying components, i.e. across the resistor R3 and the diode D1, is a specific one Actual ratio of the frequency generator III achievable.

The differentiation stage X IV causes a differentiation of the positive Edge of the generator signal. The form of differentiation is from the electrical Values of the resistance component R5 ', the exposure level of the photoelectronic Component F1 and the capacitance of the capacitor C3 is determined. The electric one Value from the parallel connection of the resistor component R5 ', which is either as Variable resistor or can be designed as a fixed resistor, and the photoelectronic Component F1 is therefore decisive for the brightness of the connected incandescent lamps. The combination of the photoelectronic component F1 with a variable resistor there are three functions to be assigned: 1. The rheostat R5 'becomes purely manual Control of the connected light bulbs used.

2. The rheostat R5 'is used to determine the basic brightness of incandescent lamps used.

3. The photoelectronic component F1 regulates depending on the Ambient light, based on the basic brightness determined by the rheostat R5 ', the duty cycle (ED) of the connected incandescent lamps towards 100% ED or vice versa from 100% ED to 5% ED as the lowest value.

The Schmitt trigger S2 connected downstream of the differentiation stage IV its high-impedance input H 'reyenerates and inverts the differentiated signal of the frequency generator III.

The signal created in the Schmitt trigger S2 is transmitted via the basic series resistor R6 in the transistor T1 with its load resistor R7 inverted current-amplifying.

Finally, the transistor T controls with its collector via the Base series resistor R8 the pnp transistor T2 used as a power output stage. The power output stage or the transistor T2 switches the externally connected load 111.

Instead of the two Schmitt triggers S1, S2 shown in FIG. 1, the Potentiometer circuit according to FIG. 2 also has an integrated circuit JCi have two NAND Schmitt triggers ST1, ST2 each with three inputs El, E2, H or El ', E2', H 'and one output A, A' each. The integrated circuit JC1 carries the terminal designations 1 to 14 and is connected via two additional lines 7 ', 14 ', which are connected to the terminals 7 and 14, via the line 103 with operating voltage provided. One such integrated circuit is made by Texas Instrument. listed under the type designation SN 49 713.

In this second exemplary embodiment, the resistor arrangement is R IV with the photoelectronic component F1 and a resistance component R5 '', which is shown here as a fixed resistor, through the line 106 'on the one hand the ground connection 110, on the other hand with the voltage divider point 121 and the control input H 'of the NAND Schmitt trigger ST2 connected.

The resistor R4, as in the first embodiment of Fig. 1 as a protective resistor for the output A of the first Schmitt trigger acts is between the capacitor C3 at its negative pole and the voltage divider point 121 connected.

Otherwise, the same parts in FIG. 2 as in FIG. 1 are the same Provided reference numerals, and the mode of operation of this second embodiment is exactly as described with reference to the first embodiment.

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Claims (4)

Claims Potentiometer or rheostat for brightness control respectively. Control of an external electrical load, especially the instrument lighting in motor vehicles, airplanes, ships and the like, with one in a housing arranged electronic frequency generator and an electronic differentiating stage with a resistor arrangement with variable resistance for digital control the connected load such that the connected load in a relatively high Switching sequence or frequency is continuously switched on and off, according to patent ... (patent application P 30 14 193.6-33), characterized in that the resistor arrangement (R IV) in the electronic differentiation stage (IV) a photoelectronic component (F1) which is connected in parallel to a resistance component (R5 'or R5' ') is and is connected to this at the ground connection (110). 2. Potentiometer according to claim 1, characterized by that the Resistance component (R5 ') is a variable resistor. 3. Potentiometer according to claim 1, characterized in that the Resistance component (R5 ") is a fixed resistor. 4. Potentiometer according to one of claims 1 to 3, in which the frequency generator and the differentiating stage from two Schmitt triggers connected in series or off consists of an integrated circuit with two NAND-Schmitt triggers, characterized in that that the control input (H ') of the second Schmitt trigger (S2, ST2) at the connection (121) of a voltage divider, which consists of the resistor (R4), the photoelectronic Component (F1) and the resistance component (R5 'or R5' '), and that the with its positive pole via the line (120) at the Au59Ing (A) of the first Schmitt trigger (S1, ST1) lying I <ondtasator (C3) with its negative pole to the input of the voltage divider is connected so that the resistor (R4i has a protective function for the output (A) of the first Schmitt trigger (S1, ST1).