DE4008161C1 - Integrated circuitry projecting and controlling electrical appts. - has voltage limiter delivering pulse signal to counter if mains voltage is applied in-front of main switch - Google Patents

Abstract

A first voltage monitoring circuit (3) resets the counter upon raising of the voltage before the main switch after mains interference. A first AND gate (10) delivers reset pulses for the counter (2). A signal obtained in the control circuit (4), from the presence of the mains voltage behind the main switch at the output (Q) of the ocunter (2), indicates whether the counter (2) has reached its final position, thus connecting the AND gate. Reset pulses are supplied to the counter (2) so long as it has not reached its final position and simultaneously the mains voltage is available behind the main switch (1) and the electronic control circuit (3) only controls the appliance if the counter (2) has reached its final position. USE/ADVANTAGE - e.g. machine or oven. Prevents automatic starting up of appliance after power has been restored following mains failure, although mechanical switch is in 'on' position.

Description

The invention relates to an integrated circuit arrangement for the protection provided with control electronics electrical devices due to network interference (DE 36 21 141 C2).

For electrical devices such as electric ovens, saws or drilling machines, angle grinders with mechanical Lockable switches must take precautions that prevent the devices from automatically without user intervention, start functioning if the mains voltage is available again after a power failure stands. Without appropriate safety precautions because damage can be caused by unforeseen Do not avoid starting machines or ovens.

From DE 36 21 141 C2 is a start lock for electrical Devices known after mains voltage failure. Indeed requires the circuit arrangement specified there a specially trained device main switch that not only switches the supply voltage, but additionally is coupled to a potentiometer that the mechanical switch position in a resistance value changes. Now the circuit arrangement specified there supplied with voltage, it is first based on the Potentiometer setting checked whether the changes in Voltage state from actuation of the switch or caused by a network fault. A The disadvantage of this known circuit arrangement is that  this known circuit arrangement always a special trained power switch requires.

The invention has for its object a monolithic integrable safety circuit for control specify electrical equipment that avoids that a mains failure after mains voltage return without action the user's electrical device its function by itself, although the mechanical switch in the "on" position stands. This task is characterized by the characteristics solved in claim 1.

That means electrical Tools such as drills or saws after a mains voltage return do not start without user intervention can and that electric stoves after a Mains voltage recovery without user intervention just be able to heat. The circuit according to the invention should also require as few external components as possible, especially with conventional device main switches get along and a given security time enable without adjustment.

The invention is based on an embodiment explained.

Fig. 1 shows the operation of a motor M, for example, angle grinder or circular saw is used for operating an electric tool such. When operating an electrical tool, it may happen that the mains voltage fails and that in this state the main switch 1 , which is generally a mechanical switch and serves to operate the motor M in the exemplary embodiment, remains switched on. Without any special precautions, the motor M would automatically restart as a result of the switch 1 being switched on when the power failure is over and the power supply is available again. An automatic start of the motor after a power failure must be prevented under all circumstances, since considerable damage can occur if a circular saw or an angle grinder z. B. starts surprisingly.

In the circuit of FIG. 1, it is ensured that the motor M cannot start automatically when the mains voltage is available again after a mains failure, regardless of whether the main switch 1 is switched on or not. Rather, a prerequisite for starting the motor when the mains voltage is applied after a mains failure is that the closed switch 1 is first opened for a specific time and then closed again in the circuit of FIG. 1. In this way it is ensured in the circuit of FIG. 1 that the user determines when the motor M starts again after a power failure.

The counter 2 and the output signal at its output are of significant importance for the circuit of FIG. 1, since the control circuit 3 enables at a logic 0 at the output of the counter 2 , while the motor M cannot start at a logic 1 at the output , because the control circuit 3 is blocked. The prerequisite for a logical 0 to appear at the output is that counter 2 has run up to its final state (e.g. 31 ). If the counter 2 is not in its final state, a logical 1 appears at the output Q, which prevents the motor M from starting.

Since the motor M must not start after the mains voltage has returned after a mains failure even if the switch 1 is closed, the circuit part 4 (control circuit), which is supplied by a point 5 of the supply line 6 , which is located behind the main switch 1 , ensure that counter 2 does not reach its end value. This is achieved in that the circuit part 4 delivers reset pulses to the counter 2 for so long and thus always sets the counter to "0" until the main switch 1 is opened by the user. The circuit part 4 can only supply reset pulses for the counter 2 as long as the main switch 1 is closed, since the circuit part 4 is only supplied with current when the switch 1 is closed. The function of the circuit part 4 will be discussed later.

The circuit part 7 (protective circuit) has the counter 2 already mentioned, a voltage limiting circuit 8 , a voltage monitoring circuit 9 , an AND gate 10 and an OR gate 11 . The voltage limiting circuit 8 ensures that the voltage at point 12 is limited to a value that is suitable for the integrated circuit part 7 as an operating voltage. The limiting circuit 8 also supplies the clock signal for the counter 2 . The counter 2 is reset to "0" at the first start-up of the voltage at point 12 , specifically by the voltage monitoring circuit 9 , via the OR gate 11 , which has both reset pulses from the voltage monitoring circuit 9 and reset pulses from the control circuit 4 forwards to the counter 2 as long as a reset signal until the voltage z. B. has reached half the limit voltage. A single reset pulse is sufficient in each case to reset counter 2 to zero, regardless of the respective counter reading.

The reset pulses for the counter 2, coming from the control circuit 4 and are generated in this from the clock generator 13, pass via the AND gate 14 in the circuit section 4 to the AND gate 10 in the circuit part 7 when the Spannuns monitoring circuit 15 is a " 1 "reaches the AND gate 14 . The reset pulses of the clock generator 13 are only forwarded from the AND gate 10 to the OR gate 11 when a potential is present at the AND gate 10 which corresponds to the logic 1 on the inhibit line 16 . For this purpose, one input of the AND gate 10 is connected to the inhibit line 16 . If switching on is to be enabled, there must be a logic 0 at the output of counter 2 and thus on the inhibit line and at one input of AND gate 10 , which prevents reset pulses from clock generator 13 from reaching counter 2 since counter 2 must not be reset when the engine is running.

If, via the AND gate 10 and the OR gate 11, reset pulses from the control circuit 4 occur at a time before the counter 2 has counted up to its final value, the inhibit line 16 prevents the control circuit 4 from the motor M starts.

However, if the control circuit 4 is supplied via the resistor 17 and the diode 18 only when the counter 2 is already in its end position (eg 31 ), the inverted output of the counter 2 becomes logic "0". As already mentioned, this prevents, via the AND gate 10 , that the counter 2 is reset by reset pulses from the AND gate 14 . Because the inhibit line 16 has a logic 0, the control circuit 4 can start the motor M.

The voltage monitoring circuit 15 of the control circuit 4 ensures that the reset pulses can only be switched through to the protective circuit 7 when the operating voltage of the control circuit 4 has reached its minimum value (eg 8 V). In this case, the voltage monitoring circuit 15 supplies a corresponding release potential for the reset pulses to the one input of the AND gate 14 .

The protective circuit 7 is supplied via the resistor 19 and the diode 20 during the positive half-wave of the mains voltage supply current. The capacitor 21 ensures that the protective circuit 7 can partially maintain the voltage during the negative half-wave of the mains voltage. The capacitor 22 has the same function for supplying the control circuit 4 .

If the main switch 1 is opened after the mains voltage has been re-inserted after a mains failure, the circuit part 4 receives no voltage since the part of the supply line 6 behind the switch 1 is no longer connected to the mains. As a result, the clock generator 13 can no longer deliver reset pulses and cannot reset the counter 2 to zero. In contrast to circuit part 4 , circuit part 7 receives a voltage even when switch 1 is open. The voltage monitor 9 provides a reset via the OR gate 11 to the counter 2 until the ramp-up voltage at the point 12 has reached the minimum value for the operation of the circuit part 7 . With each positive half-wave of the mains voltage, a clock pulse is emitted from the voltage limiter circuit 8 to the counter 2 , so that when using a counter with a final state of 32 z. B. 32 positive half-waves are required until the counter 2 has counted up to its final state. Since a logical 0 appears on the inhibit line 16 only when the final state of the counter 2 is reached, which is a prerequisite for starting the motor M, the switch 1 must be kept open for at least 32 positive half-waves (= 640 msec) after opening before it closes again. If the switch 1 is kept open for less than 32 positive half-waves, the circuit evaluates this as a "fault" and the motor M is not started even after the switch 1 is closed.

As the circuit of FIG. 1 shows, the circuit part 4 is fed by negative half-waves of the mains voltage and the circuit part 7 by positive half-waves of the mains voltage. This is achieved in that the diode 20 and the diode 18 have opposite directions. The supply of negative half-waves is necessary in the circuit part 4 because the triac 23 must advantageously be ignited with negative ignition pulses. If the circuit part 4 is supplied negatively, the circuit part 7 must be supplied positively, namely when both circuit parts ( 4, 7 ) are integrated together and, as is generally the case, the circuit parts are implemented in bipolar technology. Because if the circuit part 7 is positively supplied as in the embodiment of FIG. 1 with a negative supply of the circuit part 4 , it is prevented in the simplest way that the supply of the circuit part 7 simultaneously also the circuit part 4 and thus the actual control electronics, which are integrated in the same semiconductor body is included. In this way it is ensured that the protective electronics (circuit part 7 ) can be supplied in an energy-saving manner via a high-resistance resistor 19 (eg 470 KOhm / 50 mW), while the actual control circuit (circuit part 4 ) can be supplied via a relatively low-resistance resistor 17 (e.g. 12 KOhm / 3 Watt) must be supplied.

Because of the low power required by the circuit section 7 in contrast to the circuit section 4 , the circuit section 7 can be operated in stand-by mode (plug 26 inserted) with the switch 1 open.

The circuit according to the invention is not only suitable for electrical tools such as drills, angle grinders or electric circular saws, but very generally for electrical devices, which also include, for example, electric ovens, stoves or pumps, etc. The circuit according to the invention only requires an additional pin connection ( 12 ) for the circuit part 7 . The point 25 is the reference point (ground) of the circuit.

FIG. 2 shows an example of the circuit part 8 of FIG. 1 with a voltage limitation and a clock generator which supplies the clock signal for the counter 2 of FIG. 1. The voltage limiter consists of FIG. 2 of a Zener diode 27 and the clock generation is as shown in FIG. 2 of a transistor 28 and a resistor 29 which is connected at its one end with the zener diode 27 and to the base of the transistor 28. The other end of resistor 29 is connected to the emitter of transistor 28 .

Fig. 3 shows an example of a voltage-monitoring circuit (9, 15). The voltage monitoring circuit of FIG. 3 consists of a transistor 30 and a resistor 31. One end of the resistor 31 is connected to the base of the transistor 30 , while the other end of the resistor 31 is connected to the emitter of the transistor 30 .

The supply of the voltage monitoring circuit of Fig. 3 through a connected as a current mirror transistor 32 and a resistor 33, wherein the one end of the resistor 33 to the base of the transistor 30 of the voltage monitor circuit and the other end of the resistor 33 to the base of transistor 32 is connected. The base of transistor 32 is also connected to a collector K 1 of transistor 32 , while the second collector K 2 of T 32 is connected to collector T 30 .

Claims (13)

1. Integrated circuit arrangement for securing electronic devices provided with control electronics ( 3 ) after network faults, characterized in that
that the presence of the mains voltage is detected before and after a main switch ( 1 ),
that a voltage limiting circuit ( 8 ) is provided, which supplies a clock signal for a counter ( 2 ) when the mains voltage is applied in front of the main switch ( 1 ),
that a first voltage monitoring circuit ( 9 ) is provided which resets the counter ( 2 ) when the voltage is first raised before the main switch ( 1 ) after the mains fault,
that a first AND gate ( 10 ) is provided, the output of which provides reset pulses for the counter ( 2 ), and which has a signal obtained in the control circuit ( 4 ) from the presence of the mains voltage behind the main switch ( 1 ) with the output (Q ) of the counter ( 2 ), which indicates whether the counter ( 2 ) has reached its end position, so AND-linked that reset pulses are supplied to the counter ( 2 ) as long as it has not reached its end state and at the same time the mains voltage behind the main switch ( 1 ) is present,
and that the control electronics ( 3 ) only control the device when the counter ( 2 ) has reached its end position. 2. Circuit arrangement according to claim 1, characterized in that the voltage limiting circuit ( 8 ) via a resistor ( 19 ) and a diode ( 20 ) half-waves of the supply voltage are supplied in that a capacitor ( 21 ) is provided which the voltage Limiting circuit ( 8 ) supplied voltage also partially maintained during the half-waves of the supply voltage blocked by the diode ( 20 ). 3. Circuit arrangement according to claim 1 or 2, characterized in that the capacitor ( 21 ) is connected between the diode ( 20 ) and that supply line with which the resistor ( 19 ) is not connected. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that a counting clock is given to the counter ( 2 ) during each supplied half-wave of the supply voltage when the voltage at the voltage limiting circuit ( 8 ) has reached that value to which the voltage should be limited. 5. Circuit according to one of claims 1 to 4, characterized in that a second voltage monitoring circuit ( 15 ) is provided which receives half-waves of the supply voltage via a second resistor ( 17 ) and a second diode ( 18 ) and which has the release potential for provides a second AND gate ( 14 ). 6. Circuit according to one of claims 1 to 5, characterized in that the second supply lead with the second resistor ( 17 ) and the second diode ( 18 ) is behind the main switch ( 1 ). 7. Circuit according to one of claims 1 to 6, characterized in that a second capacitor ( 22 ) is provided which is connected between the second diode ( 18 ) and that supply line with which the second resistor ( 17 ) is not connected. 8. Circuit according to one of claims 1 to 7, characterized in that a clock generator ( 13 ) is provided which supplies reset pulses via the second AND gate ( 14 ) to the counter when at one input of the second AND gate ( 14 ) a release potential is present and if the counter ( 2 ) has not reached its end position. 9. Circuit according to one of claims 1 to 8, characterized in that the first AND gate ( 10 ), the reset pulses of the clock generator via the second AND gate ( 14 ) are supplied, and that the one input of the first AND gate ( 10 ) is connected to the output (Q) of the counter ( 2 ). 10. Circuit according to one of claims 1 to 9, characterized in that an OR gate ( 11 ) is provided, one input reset pulses of the first voltage monitoring circuit ( 9 ) and the other input reset pulses of the clock generator ( 13 ) are supplied and the output of which transmits the reset pulses to the counter ( 2 ). 11. Circuit according to one of claims 1 to 10, characterized characterized in that the one supply feed positive half-waves of the supply voltage and the other Supply supply negative half-waves of the supply voltage feeds. 12. Circuit according to claim 11, characterized in that the first supply lead positive half waves the supply voltage and the second supply lead negative half-waves of the supply voltage delivers. 13. Circuit according to one of claims 1 to 12, characterized in that the first resistor ( 19 ) is chosen such that it has a high impedance, that of the voltage limiting circuit ( 8 ), the first voltage monitoring circuit ( 9 ) and the counter 2 Circuit part consumes very little power.