DE2630866C2 - Circuit arrangement for short-circuit braking of asynchronous squirrel-cage motors - Google Patents

Description

3

from a bridge rectifier 11 and an opto-18 reset and thus the NAND-Giietl 23 gokoppler 12 existing fast switch. A triac 13 blocks. Closing the contacts 8, 9 again and is in series with the bridge rectifier 11 and in parallel 10 sets the memory 18 through the delay element to the stator winding 3 As long as the motor in 16 and the input 22 is prepared All other operation and the switching contacts 8, 9 and 10 closed 5 is repeated as described above. The bridge rectifier 11 is connected as a result of the switching path of the switch, since the short circuit previously established for the switching contact 10 checks whether the circuit arrangement described above controls whether the secondary does not emit any voltage. At the output 14 of the opto-main contacts are open and thus the short-circuit coupler 12 is therefore a low signal. If the switching connection is prevented when the triac is fired, but clocks 8, 9 and 10 are open, the bridge receives the circuitry according to the connector rectifier 11 on the one hand via the supply line 6 and the exemplary embodiment described on the other hand via a voltage zero point 15 as well as improvement of the braking speed is from the Diadie stator winding 3 voltage. This appears on the gram in Figure 3. In the slide output 14 of the optocoupler 12 high signal It is the grams are the in percent of the nominal speed n ₀ from the logi- 15 depressed speeds η shown on the right in the figure after the start of the Zeitschen switching, from such a signal form only point O braking onset over the time r then briefly generate ignition pulses when the wear. The curve 1 furthest to the right be-high signal after interruption of the switching contacts 8, 9 applies to the case of the motor coasting down unbraked in time t and 10 at point 14. The middle 3 and the left curve

A high or low signal 20 2 pending at point 14 shows the course of the speed be. ' The application is reversed by an inverting timer 16, short-circuit braking. When the Ymken curve was recorded on its edge falling from high to low, the value for influencing the braking speed was delayed and given to one input 17 of a magnet-feeding resistor 27 to its optimal value. An inversion element 19 is also adjusted, while this curve is delayed when the middle switched second inverting timing element 20 is recorded; a value was set that corresponds to the longest braking time that can be achieved with the gene only the short-circuit braking edge rising from low to high when the signal is 14. At the moment the Span- ish corresponds

reversal at its inputs 17 and 21 is the

Magnetic memory set. At its output 22 there are 3 sheets of drawings

appears to be high as soon as the input is 17 towards 30

input 21 becomes positive. The output 22 of the magnetic memory is connected to the input of a first NAND gate 23, to its second input 24 the signal present at 14 is passed on unchanged. The output 25 of the NAND gate only falls then from high to low if input 24 is activated immediately after the motor has been switched off with the memory set Receives high signal. The magnetic memory 18 falls off as soon as the savings at its input after the through the timer 20 conditional delay time is reversed. At that moment also appears at the exit 25 of the NAND gate 23 again high signal.

The high signal, which is normally present at point 25, is only activated during the short period between switching off the engine and falling off of the set memory is converted into a low signal. This brief square-wave pulse is generated The ignition pulses are used to do this at one input 29 of a second. NAND gate 31 that of a periodic square-wave pulse generated, for example, at 2.5 kHz clock generator 30. These only appear at the output 32 of the NAND element 31 if at the input 28 briefly High signa! The generated in this way appears only immediately after the engine has been switched off at output 32, ignition pulses are transmitted via an ignition device 33 forwarded to ignition contact 34 of triac 13

The ones at points 14,17,21,22,24,25,28,29 and 32 adjacent signal sequences are shown in the diagram in the figure 2 shown.

When contacts 8, 9 and 10 are opened, the optocoupler as well as the NAND gate 23 are switched over without delay and the ignition point is only from the setting on the timer (approx. 2 msec). The time period according to FIG. 2, in rVm the triac 13 ignition pulse gets is limited by the timer 20 by the magnetic memory after the delay time has elapsed

Claims (2)

Patent claims: 1. Circuit arrangement for short-circuit braking of asynchronous squirrel-cage motors with mechanical Switch contacts to be operated in the power supply lines of the three-phase Stator windings with a semiconductor switch as a short-circuit switch and a timing element for the temporal Limitation of the braking current, characterized by a fast one connected in parallel to one of the switching contacts on the input side Switch from a bridge rectifier with a downstream optocoupler, one with the fast one Switches in series and a triac connected in parallel to one of the stator windings as a short-circuit switch, one formed by superimposing the three phases of the supply voltage, with an input of the fast switch connected voltage zero, a first NAND-Güed (23), whose 2ö one input contact (24) directly and the other input contact (22) via an inverting one Delay element (16 to 20) as a time element for the braking time with the output of the high-speed switch is connected, as well as a second NAND element (31), the input side via a second delay element with the output of the first NAND element (23) and the output of a clock generator (30) and on the output side is connected to the ignition contact of the triac (34) via an ignition device (33) 2. Circuit arrangement veh claim 1, characterized in that the inverting delay element consists of a magnetic memory (18) with a first inverting timing element (16) at one input contact and with an inversion element (19) and a downstream second inverting timing element (20) at the other input contact 40 The invention relates to a circuit arrangement for short-circuit braking of asynchronous squirrel-cage motors with mechanically operated switching contacts in the clamping part supply lines of the three-phase stator windings with a semiconductor switch as a short-circuit switch and a timer for time limitation of the braking current. From DE-OS 19 10 448 an electronic short-circuit switch for three-phase asynchronous motors is known. After the operating voltage has been switched off, the rotor core is supplied with direct current from outside created using the remanence magnetic poles that when passing through z. B. a Semiconductors short-circuited part of the stator winding in this generate an induction current as a result of which the kinetic energy of the rotor is eliminated by converting it into electrical energy or heat. Of the Braking current can be adjusted by an adjustable time relay or corresponding electronic arrangements after a short time Time to be switched off. Especially with motors with low winding resistance and smaller external ones The flywheel must be short-circuiting the phases immediately after switching off the operating voltage, otherwise the braking effect - due to the rapidly decaying residual magnetism of the rotor - will not more is sufficient to bring the rotor to a standstill. How the Kuiv. Circuit breaker should be controlled is However, not to be found in this laid-open specification. From DE-OS 24 05 092 is still an electronic Control circuit for starting and stopping a single-phase capacitor motor is known the via a transformer and a full wave rectifier is connected For braking, a brake switch is provided to generate a control voltage, which determines the duration of the braking current surge Zeitgüed generated for the braking time The object of the present invention is to provide rapid and reliable control of the short-circuit switch to provide an avoidance of power supply connections guaranteed The circuit arrangement according to the invention to achieve this object is characterized by a on the input side to one of the switching contacts connected in parallel to a fast switch from a bridge rectifier with downstream optocoupler, one with the fast switch in series and one of the stator windings Triac connected in parallel as a short-circuit switch, one by superimposing the three phases The voltage zero point formed by the supply voltage and connected to an input of the high-speed switch, a first NAND element, one input contact of which is directly and the other input contact via an inverting delay element as Timing element for the braking time is connected to the output of the high-speed switch, as well as a second NAND element, the input side via a second delay element with the output of the first NAND element as well as the output of a clock generator and on the output side via an ignition device with the ignition contact of the triac is connected. With the aid of the circuit arrangement according to the invention, it is possible to remove the triac immediately after it has been disconnected to ignite the stator winding quickly and safely from the supply voltage. The function of the logical Circuit elements are to trigger the triac with certainty in all other operating states impede. Because the output of the first NAND element is connected to a further adjustable timing element the braking speed can also be influenced. The inverting delay element can consist of a magnetic memory with a first inverting timing element at an input contact as well as with an inversion element and a downstream inverting timing element exist at the other input contact. A square wave signal appearing at the output of the fast switch is inverted by this delay element and both at its rising and at its falling edge delayed. The delay times for the both edges can be selected independently of each other. This slight delay is as evident from that The exemplary embodiment below becomes clear for a functional generation of the ignition pulses absolutely necessary. The invention is then based on an exemplary embodiment shown schematically in FIG are explained in more detail. Three-phase stator windings 1, 2 and 3 are supplied with voltage via leads 4, 5 and 6. the Stator windings can be operated via a contactor 7 with three associated switching contacts that can be operated together 8, 9 and 10 must be disconnected from the power supply. There is a parallel to the switch contact 10