NL8104917A - DEVICE FOR CONTROLLING A DC MOTOR. - Google Patents

Description

Ί * - 1 -

Device for controlling a DC motor.

Known are devices for controlling a DC motor powered by an alternating current source connected to a two-phase rectifier, which devices include a semiconductor element with adjustable conductivity connected in series between the rectifier and the motor, as well as means for feeding of the semiconductor element with control pulses synchronous with the frequency of the source, the duration of which is determined depending on the desired average voltage for feeding the motor.

In these known devices, control is generally accomplished by influencing the conductivity angle, with the ignition of the semiconductor element occurring at any point 15 of the period, while quenching occurs during the zero crossings of the supply current.

These known devices have the drawback that high-frequency components are introduced into the current, which give rise to considerable high-frequency disturbances.

In order to reduce these disturbances, it has also been proposed to make a triac or a thyristor conductive during an alternating current period, so that current generation and retention occur during the zero crossings. To control the average voltage to the desired value, the conductivity of the semiconductor element is controlled only for certain semiconditions.

Such known devices have the drawback that they do not allow fine adjustment, since this adjustment necessarily takes place in successive jumps. In addition, the motor supply is pulsed at a relatively low frequency, causing unwanted shocks to the motor and the mechanical members entrained thereby.

The object of the invention is to provide a device in which the above-mentioned drawbacks are eliminated.

8104917 * · "- 2 -

According to the invention, this object is achieved in that the control device is designed to supply pulses, the beginning of which coincides with the zero crossing of the voltage of the source and whose duration is less than that of half a period.

The invention will be explained in more detail below with reference to the drawing, which shows by way of example a favorable embodiment of the control device for a DC motor according to the invention. Herein shows; Fig. 1 is a block diagram of the entire control device for a DC motor according to the invention, and Fig. 2 shows the electrical circuit diagram of the control circuit used herein.

As Fig. 1 shows, a motor M is powered from an alternating current source 1 through a control circuit 2. This control circuit is controlled by a control circuit 3.

The control circuit 3 receives various signals, namely a synchronizing signal S1, a signal S2 for measuring the current flowing through the motor M, a signal S3 indicating the true speed of the motor, which signal is output by a measured value transmitter 4, carried by the motor Mf and a signal S4, which indicates the prescribed speed, which signal is supplied by a circuit 5. Furthermore, the control circuit 3 supplies a control signal S5 for regulating the power supply of the motor and a signal 30 S6 for switching on or switching off the power supply of the motor M.

As shown in Fig. 1 at the top of the drawn time diagram, the signal S5 consists of a series of block shape pulses, the starting points of which always coincide with the starting points of half a period.

The start of the pulses S5 is initiated by the synchronizing signal S1, which can be derived in known manner from the alternating current source 1. The pulse duration t1 of the pulses S5 determines the average supply voltage of the motor. Since the control circuit contains a two-phase rectifier, 8104917 μ-i - 3 - with a mains supply of 50 Hz, the pulse frequency of the pulses S5 will be 100 Hz.

The control circuit 3 will not be described in more detail and detail, since it can be implemented in various known ways, in particular by means of a microprocessor. In any case, it must be adapted to the behavior of the signals supplied to it and which it must supply. The measured value transmitter 4 can be designed to supply an electrical signal, the frequency of which is representative of the speed of the motor. The measuring transducer can also output a voltage proportional to the speed of the motor.

The control circuit 3 serves to influence the supply voltage 15 in such a way that the motor M obtains a speed corresponding to the reference speed prescribed by the circuit 5. In the circuit 3, the difference between the input signals S3 and S4 is determined and an increase in the pulse duration of the pulses S5 is controlled such that the instantaneous speed of the motor is less than the reference speed prescribed by the circuit 5 and vice versa. This pulse duration accretion can be proportional to the difference between the signals S3 and S4 in order to obtain a fine adjustment close to the desired speed. The pulse duration of the pulses S5 is also determined by taking into account the current of the current passing through the motor M, for which current the signal S2 is a measure.

When this current exceeds a predetermined value 30, the pulse duration t ^ will be shortened proportionally to the excessive increase of the average current. If the value of the signal S2 exceeds this value for a predetermined period of time, the control circuit 3 will completely suppress the signal S5.

The signal S6 is a safety signal.

It is necessary for the motor to run that the signals S5 and S6 are both present. The signal S6 appears when the signal S4 exceeds a predetermined value, indicating that the motor must be running 40. This signal S4 is present during all 8104917-4 half periods (see the drawn time schedule in Fig. 1) until this signal S4 falls below the predetermined value, in which case it is no longer present at all.

FIG. 2 shows the electrical circuit diagram of the control circuit 2 of the motor M. This motor receives a rectified voltage from a rectifier bridge 10, which is connected to an alternating voltage network via its switch 8 and contacts 7 and 7 via a switch 8. Furthermore, the AC power supply to this rectifier bridge 10 is controlled by a triac 16, which is connected in series with the rectifier bridge in the power supply chain and controlled by a photodiac 17, without an external power supply. The supply slide 17 is controlled by the signal 15 S6, which comes from the control circuit 3 of FIG. 1.

The signal S6 must therefore be present before the motor M can be powered.

A series circuit 20 is connected to the output terminals on the DC side of the rectifier bridge 10, which, in addition to the motor M, also contains a semiconductor element 11 and a resistor R3. This resistor R3 serves to measure the current flowing through the motor M. Namely, the voltage drop caused by this current across resistor R3 is applied across a photodiode 13, which then emits the light signal S2.

The semiconductor element 11 is a transductance element with low internal resistance in the conducting state, as is known, for example, under the designation Hexfet IRF 830. The control electrode 9 of the element 11 is controlled by the signal S5, which is sent by the control circuit 3 1 is output as an optical signal. When this optical control signal S5 energizes the phototransistor 12, this will lead to a voltage drop across the resistor R2, which voltage is transferred via a diode D to the electrode 9. Between this electrode 9 and the negative terminal of the rectifier 10 is a parallel circuit which consists of a capacitor 14 with a field effect transistor 15 parallel to it.

40 The field effect transistor 15 is known 8104917

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- 5 - switched for transmitting a constant current within a certain voltage range. Thus, when the optical signal S5 makes the phototransistor 15 conductive, the transistor 14 will be charged and the semiconductor element 15 will become conductive. At the end of the optical pulse train, the capacitor 14, which is separated from the resistor R2 by a diode D, will discharge with a constant current in the element 15.

The voltage at the terminals of capacitor 14 decreases linearly and will lead to progressive current reduction of the motor through element 19 during the half period considered. Thus, interrupting the current flowing through the motor is accomplished progressively, thereby avoiding the transmission of radio-electrical disturbances. Thus, an interference suppression fliter can be dispensed with.

A Zener diode 18 is connected across the element 11 to protect against any overvoltages. It is noted that the coupling between the control circuit 3 and the control circuit 2 is ensured by optical signals, thereby achieving low voltage galvanic isolation between the control circuit 3 and the high voltage elements of the control circuit 2.

In an interesting variant, the diode D

and the transistor 15 can be omitted so that at the end of the optical signal S5, the capacitor 14 discharges exponentially across the resistor R2.

The exponential reduction in the supply current of the motor M is also beneficial in view of the absence of high frequency disturbances.

- conclusions - 8104917

Claims (10)

1. Control device for a DC motor, fed from an AC source, which is connected to a biphasic rectifier, the device comprising a semiconductor element with controlled conductivity, connected in series between the rectifier and the motor, as well as means for supplying to the semiconductor element of control pulses synchronous with the frequency of the source, the pulses of which the duration is determined depending on the desired average voltage for supplying the motor, characterized in that pulses are applied in this device, the beginning of which coincides with the zero crossing of the voltage of the source and of which the pulse duration is less than the duration of half a period. 2. A device according to claim 1, characterized in that the semiconductor element is a transductance element with low internal resistance in the conduction state. 3. Device according to claim 1 or 2, characterized in that it comprises means for supplying pulses, which are generally block-shaped and from which the trailing edge decreases progressively. Device according to claim 3, characterized in that it comprises a control circuit -25 which supplies square pulses and is provided with at least one input for a signal which determines the desired average voltage for the motor, the square pulses from the control circuit are applied to the control circuit, which includes means for providing such a slope of the trailing edge of the pulse that this pulse exhibits a progressive decrease. 5. Device according to claim 4, characterized in that said means provide a progressive decrease which is substantially linear. 8104917 - 7 - Device according to claim 4, characterized in that said means provide a progressive decrease which has an exponential course. 7. Device as claimed in claim 4, characterized in that the control circuit comprises means for generating optical control pulses which act on a phototransistor of the control circuit, which phototransistor controls the semiconductor element. 8. Device as claimed in claim 4, characterized in that it is provided, for safety reasons, with an electronic switching element connected in series in the rectifier supply line, consisting of a triac, which is controlled without external supply by a photo-diode, which switching element 15 is controlled to interrupt the rectifier power supply when the input of the control circuit corresponds to an average voltage which is less than a certain voltage threshold. 9. Device as claimed in claim 4, characterized in that the control circuit comprises a resistor connected in series with the semiconductor element, at the connection contacts of which the voltage is measured by means of a photodiode. Device according to claim 4, 7, 8 or 9, 25, characterized in that the high voltage control circuit for the motor is galvanically separated from the low voltage control circuit, the coupling between these two chains being effected by optical signals, which are transmitted by means of fiber optics. 8104917