DE3418939A1 - Power controller for electrical loads - Google Patents

Abstract

In the case of a power controller for electrical loads, having a nominal-value transmitter which supplies a nominal voltage which is dependent on the desired power, a circuit is provided which supplies a mains-synchronous, intrinsically changing digital ramp signal as well as a voltage which is a function of the maximum value of the mains-synchronous ramp signal and is used as a reference variable for the nominal value transmitter. A further circuit converts the nominal voltage, which is supplied by the nominal value transmitter, and is part of the maximum value of the mains-synchronous ramp voltage, into a corresponding digital signal. A digital comparator compares the digital nominal signal corresponding to the nominal voltage with the mains-synchronous digital ramp signal and, when the two digital signals are equal, activates a circuit which supplies a triggering current for the power element for the case when the power component is not carrying any load current.

Description

Power control for electrical loads

For electrical tools such as B. Drills are power controls required that are suitable for the electrical tools required To be able to operate motors with an alternating voltage of different mains frequency. Because there are countries in which the mains frequency is 50 Hz, as well as countries in which a mains frequency of 60 Hz is available. For power controls to control of motors for electric tools is still a so-called basic calibration required, at which the minimum power is set.

The invention is based on the object of an integrable power control to be specified for electrical loads such as motors with no switching to different Mains frequencies is required and also the previously required Basic adjustment is not required. This task is performed in a power control for electrical Loads with a setpoint generator, which is dependent on the desired performance Provides target voltage, achieved according to the invention in that a circuit is provided which is a network-synchronous, changing digital ramp signal and a voltage which is a function of the maximum value of the network-synchronous ramp signal and which serves as a reference value for the setpoint generator that a circuit is provided is the setpoint voltage supplied by the setpoint generator, which is part of the maximum value the grid-synchronous ramp voltage is converted into a corresponding digital signal, and that a digital comparator is provided which corresponds to that of the nominal voltage compares the digital setpoint signal with the network-synchronous digital ramp signal and if the two digital signals are tied, a circuit is activated which is responsible for the In the event that the power component carries no load current, an ignition current for the Power device supplies.

For generating the network-synchronous, changing digital ramp signal and a voltage that is a function of the maximum value of the grid-synchronous ramp signal is, according to one embodiment of the invention, an oscillator that has a counter clocked up, a zero voltage detector that ensures that the ramp signal is synchronized with the grid provides, a buffer that stores the maximum value of the grid-synchronous ramp signal, as well as a digital / analog converter that converts the digital maximum value of the ramp signal converts it into a corresponding analog voltage.

To generate the ramp voltage that is used for comparison with the Setpoint voltage is used, according to one embodiment of the invention, a second counter clocked up and the output signal of the second counter through a second digital / analog converter converted into a corresponding analog signal, which in an analog comparator is compared with the nominal voltage.

To generate the ignition power for the power component, the Output signal of the digital comparator in which the one corresponding to the target voltage digital signal compared with the network-synchronous digital ramp signal is fed to a trigger / retrigger logic that uses a current detector to control the Queries power component for load current. If the two are tied, in the digital comparator compared with each other digital signals is a pulse width control and a Activated pulse output stage, which supplies the ignition current for the power component The invention is explained below using an exemplary embodiment.

The oscillator 1, the counter 2 and the voltage zero crossing detector 3 are used to generate a ramp voltage that corresponds to a network-synchronous ramp voltage digital ramp signal. The buffer 4 stores the maximum value of the digital ramp signal and the D / A converter 5 converts the maximum value of the digital ramp signal into a analog voltage that is available at point A and to the setpoint generator is placed, which is a potentiometer 6 in the exemplary embodiment.

The zero voltage detector 3 has the task of the counter 2 by resetting to zero at each zero crossing of the mains voltage with the mains voltage to synchronize This is done by a zero crossing pulse, which the voltage zero crossing detector 3 supplies when the mains voltage crosses zero. After the zero voltage pulse has expired the counter 2, which is a 6-bit counter in the exemplary embodiment, is from the oscillator 1, which in the exemplary embodiment is an integrated RC oscillator, clocked up, namely until the onset (beginning) of the next voltage zero crossing pulse. With the voltage zero crossing pulse, the Counter 2 reset. Shortly before counter 2 is reset, its counter reading is transferred to buffer 4 and, as already described, with the aid of the D / A converter 5 into a corresponding one Converted voltage that is available at point A.

The reference voltage available at point A, which is the maximum value of the grid-synchronous ramp signal is used as a reference value for the setpoint voltage.

The reference voltage present at point A is therefore sent to the setpoint generator applied, which is the potentiometer 6 in the exemplary embodiment. The one on the potentiometer 6 applied maximum value of the ramp voltage is corresponding to the slider position of the potentiometer.

The nominal voltage applied to the wiper of the potentiometer 6 corresponds generally the position of a combination device switch.

A comparison is made in the power control according to the invention a digital ramp signal with a digital setpoint signal, which the on The wiper of the potentiometer 6 corresponds to the set voltage applied.

This comparison takes place by means of the comparator 7.

Reaches the digital ramp signal, which is between two mains voltage zero crossings from a certain count (generally zero) to a maximum value runs up, the value of the setpoint signal, the ignition of the power component takes place, if this is not carrying any load current.

The second counter is used to generate the digital setpoint signal 8 (in the exemplary embodiment an up / down counter), the count of which is from the D / A converter 9 into one corresponding voltage is converted. The one at the exit of the wide D / A converter 9 existing voltage is by means of the second comparator 10 compared with the nominal voltage on the wiper of the potentiometer 16. The counter 8 runs up until the voltage present at the output of the D / A converter is the same is the nominal voltage applied to the comparator 10. The counter running up 8 is controlled by the comparator 10 and a step size control 11. Is the The nominal voltage applied to the comparator 10 is greater than that which is also applied to the comparator 10 applied voltage generated by the D / A converter 9, so the comparator 10 outputs the SchriçtsNeitensteuerung 11 freely, which with z. B. from the acidic zero crossing detector 3 obtained, for example pulses appearing at intervals of 10 msec, the up / down counter 8 clocks higher. The counter 8 is clocked higher until the D / A converter 9 delivered voltage reaches the target voltage. Are those applied to the comparator 10 If voltages are the same, the comparator 10 switches the step size control 11 off If the voltage supplied by the D / A converter is equal to the nominal voltage, then corresponds to the count of the counter 8 of the target voltage. This setpoint counter reading, the corresponds to the nominal voltage, is stored in the up / down counter 8. With binary Counters 2 and 8 are tied (counter 2 supplies the digital Ramp signal) the digital comparator 7 supplies a control signal to a trigger / retrigger logic 12, which in turn shows the state of the power component (triac) with respect to a Queries the load current flow. If the query, which takes place via the current detector 13, shows that the power component no longer carries a load current in the moment when the counter reading of the counter n equals the target counter reading of the counter 8 reached, the pulse width control 14 is activated, which in turn controls the ignition current activated for the power component delivering pulse output stage 15.

The clock counter 16 has the task of dividing the zero crossing pulse into two to break down successive partial signals in order to ensure reliable can that the maximum information of the counter 2 is transferred to the buffer 5 first can be and only then the counter 2 to its initial value (usually Zero) is reset.

A suitable voltage zero crossing detector is, for example described in German patent specification 25 53 764. The buffer exists in the exemplary embodiment from 6 D flip-flops. By means of an acceptance command, the at the data inputs of the D flip-flops pending counter states of the counter connected upstream of the buffer transferred to the memory of the buffer.

For example, a programmable one is used as the step size control Divider used. In the simplest case, the trigger / retri.gger logic consists of one Clock flip-flop with set and reset. As a pulse width control, for example a monostable flip-flop can be used.

Through the power control according to the invention, the phase angle controlled (phase control), in which the electrical power component switches the electrical load to the power supply network. Because as is well known is the amount of electrical power delivered to the electrical load, from the phase angle the mains voltage at which the power component is controlled. The phase angle at which the control of the power component occurs, in the present case is a function of the wiper position of the potentiometer or the position of a combination device switch such. B. the push button switch a drill that controls the potentiometer's wiper.

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Claims (16)

Claims power control for electrical loads with a Setpoint generator that supplies a setpoint voltage that is dependent on the required output, characterized in that a circuit is provided which has a network synchronous, changing digital ramp signal and a voltage that provides a function is the maximum value of the grid-synchronous ramp signal and is used as a reference value for the setpoint generator is used that a circuit is provided that the setpoint generator Target voltage supplied, which is part of the maximum value of the grid-synchronous ramp voltage is converted into a corresponding digital signal, and that a digital comparator is provided that the target voltage corresponding digital target signal with the compares the network-synchronous digital ramp signal and if the two are tied digital signals activated a circuit in the event that the power component carries no load current, supplies an ignition current for the power component. 2) power control according to claim 1, characterized in that an oscillator and a counter are provided, the counter from the oscillator during the period from one voltage zero crossing to the next voltage zero crossing is clocked up. 3) power control according to claim 1 or 2, characterized in that that a voltage zero-crossing detector is provided, the clocking up of the Counter ends when the next voltage zero crossing is reached. 4) power control according to one of claims 1 to 3, characterized in that that a buffer is provided which stores the maximum value of the digital ramp signal. 5) power control according to one of claims 1 to 4, characterized in that that a digital / analog converter is provided that the maximum value of the digital Converts the ramp signal into an analog voltage. 6) power control according to one of claims 1 to 5, characterized in that that a setpoint generator is provided, the reference variable from the digital / analog converter generated maximum ramp voltage is supplied. 7) power control according to claim 6, characterized in that a potentiometer is provided as a setpoint generator. 8) power control according to one of claims 1 to 7, characterized in that that a second digital signal is used to generate the digital signal corresponding to the nominal voltage Counter is provided. 9) power control according to claim 8, characterized in that the second counter is an up / down counter. 10) power control according to one of claims 1 to 9, characterized in that that the second counter is followed by a digital / analog converter that has the digital Converts the signal of the second counter into a corresponding analog signal. 11) power control according to one of claims 1 to 10, characterized characterized in that an analog comparator is provided which the output signal of the digital / analog converter connected downstream of the second counter with the setpoint voltage compares. 12) power control according to one of claims 1 to 11, characterized characterized in that a step size control is provided from the analog Comparator is enabled when the target voltage is greater than the output voltage of the digital / analog converter connected downstream of the second counter, and that of the analog Comparator is switched off when the two voltages are equal. 13) power control according to one of claims 1 to 12, characterized characterized in that the voltage zero-crossing detector pulses for clocking up of the second counter delivers. 14) power control according to one of claims 1 to 13, characterized characterized in that a trigger / retrigger logic is provided that the state queries the power component with regard to load current flow via a current detector. 15) power control according to one of claims 1 to 14, characterized characterized in that a pulse width control is provided that the trigger / retrigger logic is downstream. 16) power control according to one of claims 1 to 15, characterized characterized in that a pulse output stage is provided, which is the pulse width control is downstream.