DE2807224C2 - Electric direction indicator for automobiles - Google Patents

Description

The direction indicator has high stability and reliability regardless of changes in temperature and battery voltage and! provides a reduction in the response time of the flashing indicator lights after switching on.

The invention is explained in more detail below by means of exemplary embodiments based on the drawings. In the drawings,

Fig. 1 of a conventional electric direction indicator,

Fig. 2 is a circuit diagram of a direction indicator which can be regarded as a preliminary stage of the direction indicator according to the invention, to explain the principle of the direction indicator according to the present invention,

Fig. 3 a circuit diagram of a warning system also provided,

Fig. 4 is a timing diagram for the direction indicator shown in Fig. 2,

Fig. 5 and 7 are circuit diagrams for direction indicators according to the present invention and

Fig. 6 is a timing diagram for the embodiment of the direction indicator according to the present invention shown in Fig. 5.

Fig. 2 shows a direction indicator using a quartz oscillator. Fig. 3 shows a warning device for indicating water quantity, oil quantity and temperature for an automobile. Reference numeral 1 denotes a DC power source, 2 is an ignition switch, 3 is an oscillator for a quartz clock used for automobiles, 4 are direction indicator lamps, 5 are pilot lamps, 6 is a direction change indicator switch for operating the indicator lamps 4, 7 is a synchronized switch which operates in synchronism with the direction indicator switch 6, and 8 is an amplifier circuit which includes resistors, an inverter, a NAND gate, a relay and a diode for amplifying the signal from the quartz oscillator 3.

The circuit described above works as follows:

By operating the direction indicator switch 6 for turning the automobile right or left, the synchronized switch 7 is switched on so that the direction indicator lamps 4 for turning the automobile and the control lamps 5 for controlling the indicator lamps 4 can be operated.

The indicator lamp 5 remains in the OFF state when a filament of one of the direction indicator lamps 4 is broken or disconnected because a relay of the amplifier circuit 8 stops its alternating ON-OFF switching because the current flowing through the filaments of the direction change indicator lamps 4 is reduced. In this way, the breakage or disconnection of the filament of a direction indicator lamp 4 is indicated by the indicator lamp 5 not lighting up.

In Fig. 3, a warning lamp 9 is shown for warning the amount of liquid, temperature and pressure when the values reach predetermined set values, respectively. Reference numeral 10 denotes a sensor which is closed when the amount of liquid such as water reaches a predetermined value. By closing the sensor 10, the pulse signal generated by the quartz oscillator 3 actuates the warning lamp 9 through the amplifier circuit 8. In Fig. 2, reference numeral 81 denotes a relay, 82 is a protective diode, 83 and 84 are resistors, 85 is an inverter, 86 is a NAND gate and 87 is a capacitor.

The operation of the direction indicator using the quartz oscillator 3 will now be described with reference to Fig. 4, which is a timing chart. A time period At elapses from the time fo when the direction indicator switch 6 is operated for turning right or left of the automobile.

Δω is maintained until the time fi when the direction indicator lamp 4 starts operating, and this time period Δt corresponds to half a cycle of the output frequency of the quartz oscillator 3. In this embodiment shown in Fig. 2, one cycle of the output signal of the quartz oscillator 3 is about 700 msec and the delay time Δω is about 350 msec. If the delay time or response time is long, the indication indicating the turning of the automobile will be delayed thereby, which may sometimes lead to dangerous situations.

The operation of the direction indicator shown in Fig. 2 will now be described in more detail with reference to Fig. 4. The waveform of the output frequency from the quartz oscillator 3 is a

Pulse signal having two levels 1 and 0 Usually, the quartz oscillator 3 oscillates to provide the pulse signal. When the direction indicator switch 6 is kept in its neutral position, the output of the inverter 85 is at the low level "0" and the output of the NAND gate 86 is at a high level "1". On the other hand, when the direction indicator switch 6 is operated for the automobile to turn right or left, the output of the inverter 85 is brought to the high level 1 and the NAND gate 86 produces a pulse signal having two levels 1 and 0 in accordance with the pulse from the quartz oscillator 3. This operates the relay 81 to thereby operate the direction indicator lamp 4 in accordance with the pulse signal.

When the direction indicator switch 6 is closed at the time when the quartz oscillator 3 generates the signal of the high level 1, the output signal of the NAND gate 86 is simultaneously brought from the high level 1 to the low level 0 and the relay 81 is also switched to the ON state to thereby operate the direction indicator lamp 4.

If the direction indicator switch 6 is closed at the time that the crystal oscillator 3 produces the low value 0 signal, the output of the NAND gate 86 is maintained at a high level 1 until the output of the crystal oscillator 3 becomes high value 1. Therefore, the maximum possible time between the time that the switch 6 is operated and the time that the relay 81 or the lamp receives power is approximately one-half cycle of the output frequency of the crystal oscillator 3.

Referring now to Fig. 5, there is shown an improved embodiment of the direction indicator for an automobile. Reference numeral 881 denotes an amplifier composed of an inverter, and 882 denote frequency dividers composed of JK flip-flop circuits. The same reference numerals as those shown in Fig. 2 denote the same parts or circuits. The operation of the direction indicator shown in Fig. 5 will now be described. When the direction indicator switch 6 is in a neutral position,

the output signal of the inverter 85 has a low value 0 and the output signal of the NAND gate 86 is stable at the high value 1. Furthermore, the output signals of the frequency dividers 881 and 882 each have the low value 0. the output signal of the amplifier 88 is at the high level 1 and the relay 81 receives no current.

On the other hand, when the direction indicator switch 6 is operated, the output signal of the inverter 85 is switched to the high level 1, and the NAND gate 86 generates pulse signals having two levels 1 and 0. When the output signal from the NAND gate 86 changes from the high level 1 to the low level 0, the output signal from the divider 88t also changes from 1 to 0, and the output signal from the divider 882 also changes from 0 to 1. Then, the output signal from the amplifier 88 changes from 1 to 0, thereby operating the relay 81. In contrast, when the output signal of the NAND gate 86 changes from 0 to 1, then the relay 81 is brought into the OFF state, and the relay 81 is started with intermittent operation (i.e., ON-OFF switching) to thereby switch the direction indicator lamps 4 intermittently. In this embodiment, two frequency dividers are provided so that the output frequency of the amplifier circuit 88 is about one quarter of the output frequency of the quartz oscillator 3, resulting in the frequency of the ON-OFF switching relay 81 being about one quarter of the output frequency of the quartz oscillator 3. Fig. 6 shows a timing chart for the operation of the direction indicator embodiment shown in Fig. 5. The direction indicator switch 6 is closed at time r ₀ and the direction indicator lamp 4 is switched at time t 1 . The time period Δt' is the delay time, ie the starting time of the direction indicator lamps 4, and the delay time Δt' is one quarter of the delay time Δt in the previously described embodiment, and it follows that the response time of the direction indicator lamp can be reduced if desired.

In this way, the time from the operation of the direction indicator switch 6 to the switching of the direction indicator lamp 4 can be reduced by providing two frequency dividers 881 and 882 .

Fig. 7 shows an embodiment of the direction indicator in which five frequency dividers 881, 882, 883, 884 and 885 are provided. Each of the dividers consists of JK flip-flop circuits and the output frequency of the quartz oscillator 3 is divided by the five frequency dividers to 1/32. This noticeably reduces the delay time. The operation of the direction indicator in the embodiment with the circuit shown in Fig. 7 is the same as the operation of the direction indicator according to Fig. 5.

Thus, the delay time or response time can be suitably adjusted according to the number of frequency dividers.

It should be noted that the synchronized switch 7 in Figs. 2 and 7 is necessary for the following reasons: If it is to be detected by the direction indicator switch 6 via the line L· , whether the direction indicator switch 6 is in the neutral position or in the closed position without another connection being provided for the detection, difficulties arise. This is because when the direction indicator switch 6 is closed, a pulse signal with high and low level values is present on the line L ₀ , and therefore the synchronized switch 7 must necessarily be provided synchronously with the direction indicator switch 6. It can, however, also be replaced by switching elements with equivalent function, such as by memory circuits in a suitable switching arrangement.

4 sheets of drawings

Claims (1)

1 2 Patent claim quenz. Although in this known direction indicator ger already gained advantages resulting from the Electric direction indicator for automobiles, to provide high accuracy and reliability of the operating pedal connected to the oscillator of a quartz clock, and at least one amplifier circuit to amplify the output signal from the oscillator and frequency divider circuits to step down the frequency of the oscillator, as well as display lamps for changing direction and a switch, to change the time period of the flashing of the indicator lamps. In addition, the flashing of the indicator lamps should be as without delay as possible after actuation, characterized in that the amplifiers (8) of the switch via which the indicator lamps are switched by the driver of the automobile use a certain number of series-connected frequency dividers (881,882,883, ...) for dividing the output frequency from the oscillator (3) which is connected to the oscillator (3) via an NAND gate circuit (86) and feeds a reduced frequency to a relay (81) via an inverter amplifier (88) which is in the circuit of the indicator lamps, and is lower than would be desirable to achieve a delay time,
dene input of the NAND gate circuit (86) with From DE-AS 22 02 770 it is now already known, the output of a second inverter amplifier is connected to a central clock generator, one of which corresponds to the prescribed flashing frequency of the direction change indicator lamp in such a way that when the switch 25 is actuated, while another is a higher frequency, preferably with which errors in the flashing lamps can be displayed conspicuously. Frequency multiplier or frequency divider circuits are provided in this circuit, and the central clock generator Description 30 can also be used for other vehicle devices. If the direction change indicators are not working correctly, they are connected to another circuit with a different frequency so that they flash noticeably differently. The relatively complex circuit with frequency dividers therefore only serves to improve the display. Reducing the frequency of the oscillator and displaying The object of the invention is to provide an electrical rectifier The aim of the invention is to provide a direction indicator for automobiles in which a commercially available central clock is used in a simple circuit arrangement by which the direction changes can be indicated. In conventional electrical direction indicators, as used for automobiles to indicate the delay time between switching on the direction indicator lamps and the onset of flashing, an indicator device P. as shown in Fig. 1 indicates whether the power can be switched on. electrical load resistances L which are usually Lam- This task is performed in a direction indicator of the are working correctly or not. The display device P is operated by a self-excited oscillation generator S like an automatic flashing light switch. For such an automatic flashing light switch in such a system a periodic cycle for switching the flashing lights ON and OFF must be set and the periodic cycle can be influenced in an undesirable way by external conditions such as changes in the ambient temperature and the battery voltage of the automobile and the frequency can be changed by external conditions such as changes in the ambient temperature and the battery voltage of the automobile. 55 inverter amplifier whose input is connected to For this reason, direction indicators for cars have been developed which are connected to a frequency-stabilized oscillator which, as a central NAND gate circuit, emits an oscillation signal to the frequency divider corresponding to the output frequency of the Os clock generator. DE-OS 21 62 985 60 states that the frequency divider is connected to the switch for the indicator lamps in such a way that when the switch is operated, the Os clock generator is also used for other devices in the car. a circuit arrangement for operating clock-controlled The direction indicator according to the present invention Display devices in motor vehicles, where a central clock is provided, the output signal of which can be amplified if necessary via amplifier devices due to its compact circuit design. The oscillator of the quartz clock is used effectively for the direction indicator, so that setting the periodic cycle of the ON-OFF circuit for the flashing of the direction indicator lamps is unnecessary. A commercially available clock with a commercially available clock frequency is used.