DE2832556A1 - Monitoring circuit for incandescent lamps in motor vehicles - has signal store connected to voltage divider also connected to lamp - Google Patents

Abstract

The motor vehicle lamps are connected by a switch to a voltage, and the connection between the switch and the lamp is connected through a resettable signal store to the control input of a signal pickup. The signal memory (14) is connected to a voltage divider (21) supplied with a stabilised d. c. voltage. It has three resistors (22-24) connected in series. The junction between the resistors (22, 23) is connected to the monitored lamp (12) and through a timing element (25) to the setting input (S) of the resettable memory unit (14).

Description

State of the art

In such a known circuit arrangement DE-OS 26 whether 1st takes place the monitoring of the consumer by the voltage drop on a measuring resistor in the supply of consumers.

This has the disadvantage that the lamp voltage due to the voltage drop at the measuring resistor is reduced that an additional threshold switch for evaluation of the voltage drop at the measuring resistor is required and that the monitoring only can take place when consumers are switched on, because only then current in the measuring resistor flows.

The object of the invention is to find a consumer monitoring system, which are simple in construction, reliable in function and even when the consumer is switched off is effective.

Advantages of the Invention The circuit arrangement according to the invention with the characterizing features of the main claim has the advantage that the defect of the consumer to be monitored immediately, i.e. regardless of whether he is on or off is turned off, is displayed. This circuit arrangement is therefore preferably suitable for monitoring the brake light lamp of a motorcycle.

The measures listed in the subclaims are advantageous Further development and improvement of the features specified in the main claim are possible. It is particularly advantageous if the timer, which is the set input of the memory is connected upstream, is designed as a series RC, the resistance of which is connected to the voltage divider and its capacitor to ground and its connection to the set input of the memory connected. In this case, the resistance of the timer is used at the same time as Protective resistor for the set input of the memory. About that In addition, it is advisable to also use the reset input of the memory via a protective resistor to be connected to the voltage divider.

Exemplary embodiments of the invention are one of the drawings and explained in more detail in the following description. It shows Fig. 1 shows the basic structure of the circuit arrangement according to the invention for monitoring an electrical consumer, Fig. 2 the circuit of a monitoring device for a circuit arrangement according to FIG. 1, and FIG. 3, the coupling of several to monitoring consumer to the circuit according to FIG. 2.

Description of the exemplary embodiments The circuit structure according to the invention according to Fig. 1 is used to monitor the brake light lamp, the brake switch and the signal lamp for a motorcycle. It is via the plus line 10 and the ground line 11 connected to a DC voltage, for example from a not shown Accumulator battery of the motorcycle is discharged. A brake light bulb 12 is over a brake switch 13 is connected to the two supply lines 10 and 11. The circuit arrangement is also provided with a flip-flop memory 14 which Connected via a line 15 to the stabilized DC voltage of a Zener diode 16 is. The Zener diode 16 is connected to a resistor 17 connected in series with it the supply voltage of the lines 10 and 11. The output of the memory 14 is located at the control input of a signal generator, which consists of a control transistor 18, a protective resistor 19 and a signal lamp 20, which in turn is connected to the supply voltage is.

The resettable memory 14 is on the input side at one with the stabilized DC voltage connected to line 15 to be supplied voltage divider 21, which has three resistors 22, 23 and 24 in series. The connection between the first resistor 22 and the second resistor 23 is on the one hand at point C. to the brake light lamp 12 to be monitored and, on the other hand, via a timer 25 connected to the set input S of the memory 14. The connection between the second resistor 23 and the third resistor 24 is connected to the reset input R. of the memory 14 connected. The resistance value of the first resistor 22 of the voltage divider 21 is greater than that of the second resistor 23 at 150 kl with 100 kil. This in turn is greater than the resistance value of the third resistor 24 with 82 k The mode of operation of this circuit arrangement is explained in more detail below explained. When the ignition switch is switched on, positive voltage is applied to the line 10 and consequently a stabilized DC voltage of 6.2 V on line 15. As a result, an L signal occurs at the output of the memory 14, through which the control transistor 18 is switched through. The signal lamp 20 now lights up.

This signals that the memory 14 is in order. Since the Resistors 23 and 24 of the voltage divider 21 through the brake light lamp 12 practical bridged.

there are no L signals at the set input S or at the reset input R. on.

The brake switch 13 is then actuated briefly.

As a result, the supply voltage of line 10 passes through the brake switch 13 and via the connection point C to the resistors 23 and 24 of the voltage divider 21.

The dimensioning of these two resistors now leads to the reset input R of the memory 14 a Voltage shown as an L signal is evaluated and consequently deletes the L signal at its output. The control transistor 18 locks and the signal lamp 20 goes out. A corresponding L signal at set input S of memory 14 delayed; the L signal at the reset input R therefore takes precedence. The extinction of the control lamp -20 indicates that the brake switch 13 works.

If the brake light 12 fails at any point in time, then so this is indicated immediately by the monitoring circuit. In this case it will be the resistors 23 and 24 of the voltage divider 21 are no longer intact Brake light lamp 12 bridged. By dimensioning the resistors of the voltage divider 21 is now achieved that at the set input S of the memory 14 by the timer 25 delayed L signal occurs, whereas the voltage at reset input R does not more is sufficient to be evaluated as an L signal. The output of memory 14 consequently emits an L signal and switches the control transistor 18 to the current-conducting state State.

The signal lamp 20 now lights up and shows the defect in the brake light lamp -12 immediately and regardless of whether the brake switch 13 is actuated or not.

Such a monitoring circuit can be combined in one device the circuit of which is shown in FIG.

The circuit elements taken over from Fig. 1 are here with the same Provided with reference numbers. Such a device can be installed at points A, B and C in the Circuit arrangement according to FIG. 1 can be connected. The timing element 25 from Fig. 1 here consists of a series RC whose resistor 25a is connected to the voltage divider 21 and its capacitor 25b are connected to the set input S of the memory 14 is. The reset input R of the memory 14 is here via a Protective resistance 26 connected to the voltage divider 21.

There is an inverter stage in each case in the set and reset inputs of the memory 14 27 and 28 inserted, the input of which is connected to the output via a diode 29 and 3C, respectively the other inverter stage 27 or 28 is connected. The memory 14 also includes two NAND gates 31 and 32, the outputs of which are each connected to an input of the other NAND gate are connected, while the output Q of a NAND gate 31 via a resistor 33 is connected to the base of the control transistor 18, is located the output of the other NAND gate 32 through a capacitor 34 to ground.

This capacitor 34 ensures that when you apply the voltage first the one input of the NAND gate 31 to ground. lies and so that the output Q of the memory 14 receives an L signal. The control of the brake switch 13 from Fig. 1 takes place in the manner described for FIG. 1, by the brake switch 13 is actuated after the voltage has been applied. Then lies at point C of the circuit the full tension. The voltage drop occurring across resistor 24 occurs via the protective resistor 26 to the reset input R and switches the output of the Inverter stage 28 to zero. This 0 signal arrives at the input via diode 30 of the inverter stage 27. The capacitor 25b of the timing element can now not charge, since the current flowing through the resistor 25a through the diode 30 against Mass is derived. The NAND gate 32, the first input of which is the L signal from Output of gate 31 and its second input now receives an O signal, emits an L signal at its output, through which the capacitor 34 is charged will. This also receives the input of the NAND gate 31 from both the output of the Gate 32 and from the output of the inverter stage 27 each have an L signal. The exit of the NAND gate 31 becomes consequently switched to an O signal, by which the control transistor 18 is blocked. If the brake switch 13 is now again open, the signal memory 14 at the output Q does not change its switching state. Set and reset inputs carry O signals and the outputs of inverter stage 27 and 28 carry L signals, which are applied to an input of NAND gates 31 and 32, respectively reach.

As soon as an interruption occurs at the brake light lamp 12 and the The bridging of the resistors 23 and 24 of the voltage divider 21 is thus canceled the capacitor 25b can be charged via the resistor 25a and at the set input S of the memory 14 generate an L signal. Here is the voltage drop at the bottom Resistance 24 of the voltage divider 21 so low that the response voltage for the Reset input R of memory 14 is not reached. The inverter stage 27 switches .Now um, and one input of the NAND gate 31 receives a 0 signal. At the exit Q now occurs an L signal, through which the control transistor 18 in the current-conducting State is controlled and consequently the signal lamp 20 the failure of the brake light lamp 12 signals. In addition, this L-Signal is stored via the NAND gate 32, in which both inputs of the NAND gate now carry L signals and the output as well the associated second input of the NAND gate 31 is switched to zero.

This state of the memory 14 also changes after replacement the defective brake light bulb 12 initially nothing. Only when the brake switch is actuated 13, the memory 14 is again erased in the manner described above and the Signal lamp 20 switched off.

Fig. 3 shows a circuit for monitoring several parallel connected Consumers 12a and 12b by a monitoring circuit according to FIG. 2. It is a diode 35 and 36 is connected upstream of each of the consumers 12a and 12b to be monitored.

The connection between the consumers 12a and 12b and the respectively upstream diode 35 or 36 is via a resistor 37 and 38 with the Terminal C of the voltage divider 21 according to FIGS. 1 and 2 is connected. Through the diodes 35 and 36 prevents the failure of one of the two consumers on the two resistors 36 and 37 of equal size connected in parallel continue to have current flows. Rather, the current at connection C of the circuit in the event of failure of a consumer only flow through one of the resistors 36, 37 and therefore only half as large be.

This increases the voltage at point C to such an extent that the set input S receives an L signal via the timer 25 and consequently the memory in the above-described Way to trigger the signal switches.

When monitoring more than two consumers, the circuit can can be supplemented accordingly by further resistors and diodes. The voltage divider 21 is to be dimensioned so that in point C of the circuit in the event of failure of a consumer the voltage is increased so far that the memory 14 at the set input S receives an L signal.

Claims (6)

Claims S circuit arrangement for monitoring electrical consumers, in particular of incandescent lamps on motor vehicles, whereby the consumer has a Switch to voltage is to be applied and between the switch and the consumer lying connection via a resettable signal memory at the control input a signal transmitter is connected, characterized in that the signal memory (14) on a voltage divider to be supplied with a stabilized DC voltage (21) - is connected, which has three resistors (22, 23, 24) in series, wherein the connection between the first and second resistor (22, 23) on the one hand to the consumer to be monitored (12) and on the other hand via a timer (25) is connected to the set input (S) of the memory (14). and that the connection between the second and the third resistor (23, 24) of the voltage divider (21) is connected to the reset input (R) of the memory (14). 2. Circuit arrangement according to claim 1, characterized in that in the voltage divider (21) the resistance value of the first resistor (22) is greater than that of the second resistor (23) and this greater than that of the third resistor (24) is. 3. Circuit arrangement according to claim 2, characterized in that the timing element (25) is a series RC, the resistor (25a) of which is connected to the voltage divider (21) and its capacitor (25b) to ground and its connection to the set input (S) of the memory (14) is connected. 4. Circuit arrangement according to claim 3, characterized in that one inverter stage each in the set and reset inputs (S, R) of the memory (14) (27, 28), whose input each via a diode (29, 30) to the output of the connected to the other inverter stage. 5. Circuit arrangement according to one of the preceding claims characterized in that the reset input (R) of the memory (14) via a protective resistor (26) is connected to the voltage divider (21). 6. Circuit arrangement according to one of the preceding claims, characterized characterized in that each of the consumers to be monitored (12a, 12b) has a diode (35, 36) is connected upstream and the connection between consumers (12a, 12b) and diode (35, 36) each via a resistor (36, 37) with the voltage divider (21) is connected.