DE3146495A1 - Starting protection circuit - Google Patents

Description

Black & Decker Inc. Case 4143

Start-up protection circuit;

The invention relates to a start-up safety circuit for power tools which can be locked in the switched-on position em pushbutton switch.

With power tools and especially hand-held power tools, such as drills, Hand-held circular saws etc., there is a serious safety problem due to the pushbutton switch common in these devices, which normally only switches the device on as long as the pinger pressure on the switch continues.

However, since continuous operation is often required, at since the constant finger pressure is tiring and undesirable, the pushbutton switches have a lock in the form of a additional pushbutton or slide with which the pushbutton switch can be locked in the on position.

If a user can now switch on a tool that is locked in the switched-on state by pulling out the power plug goes out of operation and the pushbutton switch remains locked out of convenience or forgetfulness, so The next time the device is plugged in by the same or another user, the motor will run completely surprisingly, and there is a considerable risk, especially since the tool when the engine is running as a result of the armature moment of inertia executes unpredictable movements. The same hazards can arise if in the event of a mains voltage failure, a device that is locked while it is switched on remains plugged in or also a tool that is not in operation is switched on and locked playfully or on purpose.

The invention is accordingly based on the object of a Start-up safety circuit for power tools to prevent the unintentional start-up of the tool locked push button. To solve the

The object of the invention is based on a start-up protection circuit of the type mentioned and is characterized by a circuit arrangement that is used in the simultaneous appearance of the mains voltage in front of and behind the pushbutton prevents the motor from starting.

Since the mains voltage only appears simultaneously in front of and behind the switch when the device is switched on, namely when the device is plugged in or when the mains voltage returns after a failure, this is activated Way prevents it from starting.

There are several options available for practical implementation, with relay circuits because of the relatively high effort and space requirements are generally not appropriate. In conjunction with a a circuit having a semiconductor switch for speed control or control of the power tool a development of the invention a bistable, by an input pulse in one of its two switching states tiltable circuit, whose supply voltage from the mains voltage to a located behind the pushbutton switch Point is derived and whose output voltage blocks the semiconductor switch in one switching state, as well as a pulse generator connected in front of the pushbutton switch, which generates an input pulse when the mains voltage appears for the bistable circuit supplies. If then the plug of the electric tool with the pushbutton switched on is plugged in, the operating voltage for the bistable circuit appears practically simultaneously with the input pulse, which then the bistable circuit can tilt, whereby the semiconductor switch is blocked. If, on the other hand, the power tool is switched off State is plugged in, the input pulse appears for the bistable circuit before its operating voltage and therefore does nothing. When you press the The bistable circuit remains accordingly in the pushbutton switch

Idle state so that the semiconductor switch operated normally can be, for example by means of a control circuit of a known type for a speed control or control ensures.

As pulse generators to deliver the input pulse Known circuits can be used for the bistable circuit, for example a monostable multi- ■ vibrator, which is triggered when a DC voltage generated from the AC mains voltage appears.

According to a further development of the invention, however, a particularly simple possibility is that the pulse generator has a capacitor that can be charged from the mains voltage via a diode, the increasing charging voltage of which represents the input pulse for the bistable circuit.

The bistable circuit can advantageously include an operational amplifier, the output of which has a Diode is fed back to its non-inverting input, the polarity of the input pulse so is chosen that the resulting output voltage of the operational amplifier conduct the feedback diode and thus the operational amplifier in this switching '

• ". State.

The invention is described below with reference to the drawings. Show it:

1 shows a block diagram for an embodiment of the invention;
FIG. 2 shows a time diagram for the circuit according to FIG. 1 with the pushbutton switch initially open; FIG. 3 shows a timing diagram for the circuit according to FIG

when the pushbutton switch is initially closed; 4 shows a more detailed circuit diagram for an embodiment of the invention.

In the circuit arrangement according to FIG. 1, the motor of an electric tool with its field windings 2 is in Series via a semiconductor switch in the form of a triac and a pushbutton switch that can be locked in the switched-on position 4 at the. Mains supply line 5. The triac 3 is controlled in a known manner by a motor control circuit 6, which optionally additionally from a tachometer generator (not shown) information regarding the Receives actual value of the speed and accordingly enables regulation. The operating voltage Vcc2 for the motor control circuit 6 is through a diode 7 with a downstream limiting resistor 8 and a smoothing capacitor obtained, it being possible for a voltage limiter (not shown) to be additionally provided. The diode 7 is on a circuit point 10 connected behind the push button switch 4, so that the supply voltage Vcc2 only appears after switch 4 has been closed.

A converter 11 is connected to the mains supply 5 in front of the switch 4 and converts the mains voltage to a further DC voltage Vcd wins. This triggers a monoflop (monostable multivibrator) 12, at the output of which is Q1 Single pulse of predetermined length of, for example, 1 ms occurs when the voltage Vcd appears for the first time. This pulse is at the clock input of a bistable circuit in the form of a flip-flop 13? that of the Voltage Vcc2 is fed. The inverting output Qp is connected to a reset input of the motor control circuit 6 connected.

The mode of operation of the circuit according to FIG. 1 will be explained with reference to the timing diagrams in FIGS will. If the plug of the power supply 5 is plugged in with the pushbutton switch 4 switched off, then appears at this point in time t ~ the one supplied by converter 11 Spannimg Vcd practically immediately (Fig. 2). The monoflop 12 is triggered and delivers a at output GL

Impulse, which up to time t. pending. However, this pulse has no effect on the flip-flop 13 because its operating voltage Vcc2 is not yet available, because the switch 4 is assumed to be open. Accordingly, there is no voltage at the two outputs Q ^ ^unci ^ _{2 of} the flip-flop 13. This corresponds to the logic state L (low voltage).

If later at any time t the pushbutton switch 4 is closed, the supply voltage Vcc2 appears practically simultaneously, and the motor control circuit 6 takes over the control or regulation of the motor 1 via the triac 3. Since the output from the monoflop 12 Pulse at output Q ,. has long since subsided, the flip-flop 13 can not switch, and its output Qp continuously supplies a voltage corresponding to the logic state H. The internal circuit of the motor control circuit β is designed so that when this voltage H is applied to the flip-flop output Qp, no blocking influence is exerted, the circuit 6 thus operates normally. '

If, on the other hand, as shown in FIG. 3, when the mains voltage appears on supply 5, pushbutton switch 4 is closed, then the two voltages Vcc1 and Vcc2 appear practically simultaneously and together with the pulse at monoflop output Q- at time t _Q .

Since flip-flop is at the operating voltage Vcc2 13, its output delivers Qp at the time t ^, the voltage H. The time t * occurring falling edge of the pulse at the output Q ^ of the monostable multivibrator 12 but flips the flip-flop 13 in its other switching state, and at the output 0 * 2 the voltage disappears, ie goes to L. In this state at the reset input, the motor control circuit 6 blocks the triac 3 so that the motor 1 cannot start.

In the circuit arrangement according to FIG. 4 is again the

Motor 1 of the power tool, for example a drill, with its field windings 2 via a triac and a pushbutton that can be locked in the switched-on position switch 4 connected to the mains voltage. The triac 3 is controlled in a known manner using the phase control method Via a diac 15 and a phase shifter formed with capacitors 16, 17 and ¥ iderstands 18, 19, 20 and a setting resistor 21 with a series resistor 22, which determines the ignition angle for the triac 3. It is assumed that the triac .23 one Optocoupler 24 is switched on, so conducts.

An operational amplifier 25 forms together with one Feedback diode 26 connected between its output 27 and its non-inverting input, a bistable circuit. The voltage divider resistors at the inputs of the operational amplifier 25 28 to 31 are dimensioned so that the output voltage .des operational amplifier 25 after the application of the Operating voltage has a positive value. The diode then blocks and has no influence. The operating voltage Vcc2 for the operational amplifier 25 is, as in the exemplary embodiment according to FIG. 1, from the mains voltage on Point 10 is derived behind the push button switch 4, with a Zener diode 32, the charging voltage of the capacitor 9 is limited to a desired value of 12 V, for example.

To derive the input pulse for the operational amplifier 25, which is fed to the investing input is generated, a directly connected to the mains voltage diode 33 with limiting resistor 34 one of the voltage Vcc1 in Fig. 1 corresponding DC voltage, the one Capacitor 55 limited to one by a zener diode 36 Voltage charges. The positive flank of the rising. Voltage in capacitor 35 passes over a coupling capacitor 37 and a limiting resistor

3H6495

stood 38 at the inverting input of the operational amplifier 25. Parallel to the capacitor 35 is a discharge resistor 39t which ensures defined initial conditions,

If the pushbutton switch appears when the mains voltage appears is open, has the positive edge transmitted to the inverting input of the operational amplifier 25 Voltage across the capacitor 35 has no effect because the operating voltage Vcc2 of the operational amplifier 25 is still does not exist. When the pushbutton switch 4 is operated later, the short one is then via the coupling capacitor transmitted pulse when charging the capacitor 35 long since decayed, so that the output 27 of the operational amplifier 25 goes unaffected to positive voltage.

This voltage feeds a light-emitting diode 40 in the optocoupler 24. whereby the triac 23 is conductive and the phase control of the triac 3 is effective.

If, on the other hand, the pushbutton switch 4 is closed when the plug is plugged in or when the mains voltage returns when the plug is plugged in, the operating voltage Vcc2 of the operational amplifier 25 occurs practically simultaneously with the positive pulse at the inverting input. The voltage at the output 27 of the operational amplifier then runs in the negative direction up to approximately the common reference voltage and is therefore negative compared to the voltage at the non-inverting input determined by the voltage divider with the resistors 28 and 30. The then conductive feedback diode 26 holds the operational amplifier 25 in this state. Since the light-emitting diode 40 is not energized, the triac 23 remains switched off and the motor 1 cannot start because the triac 3 blocks the main circuit. To switch on the motor 1, it is necessary to first unlock the pushbutton switch 4 and bring it into the open position. Then the operating voltage Vcc2 for the operational

amplifier 25, which when the pushbutton switch is switched on again 4 then goes into the normal operating state with a positive output voltage.

-M.

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Claims (5)

B LU M BAG H * WESEH .. B £ ^: BÖj | jNJ KRAMER ZWJRNER - HOFFMANN PATENT LAWYERS IN MUNICH AND WIESBADEN Patenlconsult Radeckestraßo 43 8000 Munich 60 Telelon (089) 883603/883604 Telex 05-212313 Telegrams Palentconsull Patenlconsult Sonnenberger Straße 43 6200 Wiesbaden Telephone (06121) 562943/561998 Telex 04-186237 Telegrams Patentconsull Black & Decker Inc. Case 4143 Newark, Del. 19771, USA Claims Start-up safety circuit for power tools in the on position lockable pushbutton switch characterized by a circuit arrangement which, when appearing at the same time the mains voltage in front of and behind the pushbutton switch (4) prevents the motor (1) from starting. 2. Start-up fuse circuit according to claim 1 with a semiconductor switch (3) on v / ei send circuit (β; 15-22) for speed control or regulation, characterized by a bistable circuit (13 _{5 that can be tilted by an input pulse into one of its two switching states} 25), whose supply voltage (Vcc2) is derived from the mains voltage at a point (10) located behind the pushbutton switch (4) and whose output voltage (Q ₂ ) blocks the semiconductor switch (3) in one switching state, and by one in front of the Pulse generator (11, 12j 33-35) connected to the pushbutton switch (4), which supplies an input pulse for the bistable circuit when the mains voltage appears. Munich: R. Kramer , Ap \ .- lng. · W. Weser Dipl.-Phys. Dr. rer. nat. · E, Hoffmann Dipl .-! Ng. Wiesbaden: PG Blumbach Dipl.-Ing. · P. Borgen Prof. Dr. jur. Dipl.-Ing., Pat.-Ass., Pat.-Anw. until 1979 · G. Zwirner Dipl .- [ng. Dipl.-W.-Ing. 3. Start-up fuse circuit according to claim 2, characterized in that the pulse generator has a capacitor which can be charged from the mains voltage via a diode (33) (35), the rising charge voltage of which represents the input pulse for the bistable circuit (25). 4. Start-up protection circuit according to claim 2 or 3, characterized in that the bistable circuit contains an operational amplifier (25) whose output (27) via a diode (26) to its non-inverting input is fed back, and that the polarity of the input pulse is chosen so that the setting Output voltage of the operational amplifier (25) the feedback diode (26) conducts and thus holds the operational amplifier in this switching state » 5. Starting fuse circuit according to one of the claims 2 to 4, characterized in that the bistable circuit (25) controls the semiconductor switch (3) via an optocoupler (24) controls.