DE2409889A1 - Control cct for washing machine motor - has main winding sub-divided to act as freq-multiplying inverter transformer - Google Patents

Abstract

The control circuit, for washing machine's single-phase asynchronous motor, has the motor's main winding divided into two identical sub-windings which act as transformer for the static inverter that frequency multiplies the motor's voltage. The static inverter is supplied with sinusoidal voltage pulses of the same polarity. The frequency-multiplied voltage is synchronised with the sinusoidal mains voltage's frequency. The auxillary phase winding is likewise divided into two sub-windings and connected in series with a capacitance consisting of two capacitors one of which serves as the static inverter's commutating capacitor.

Description

Control of a single-phase asynchronous motor, especially for washing machines The invention relates to an arrangement for multiplying the speed of a single phase Asynchronous motor with a main phase winding and an auxiliary phase winding with an operating capacitor, in particular for driving a washing machine.

There are two operating states for driving the washing drum of a washing machine required: the actual washing process, which takes place at low speed, the direction of rotation changes periodically, and the spin process, which for Ejecting the water from the laundry requires a relatively high speed power.

Washing machine motors therefore typically have two winding systems each with a different number of poles, with the high-pole winding for washing and the low-pole winding is used for spinning.

Up to now, the washing drum has preferably been driven with a single-phase drive Squirrel cage motor, in whose stator a 900 el. Against the main winding Shifted auxiliary winding with a series-connected operating capacitor is arranged for phase rotation; Main and auxiliary strands form a two-phase Winding.

This type of drive had proven itself over many years, However, it was no longer sufficient than to become more and more additional Demands for intermediate speeds for application, gentle spin, and higher speeds for the spin process (up to 1000 rpm). One has therefore tried this Requirements through speed-controllable direct current series motors or direct current shunt motors or to meet universal motors. However, such motors are relative expensive and also not maintenance-free. Their use in washing machines has increased therefore also unable to enforce.

Finally, a possible solution has become known in which a normal asynchronous motor with two winding systems (main phase and auxiliary phase winding) is used, which in addition to the mains frequency via a frequency converter works with half the network frequency. The two result from the two winding systems The resulting basic speeds at mains frequency are set by switching to the frequency converter each halved; this results in four different possible speeds. One of those engine is easy to manufacture, but must be used during operation with half the mains frequency with constant mechanical power, double that in each case Torque can be applied.

The present invention has now set itself the task of a To create drive for washing machines, which has the disadvantages of the above known Does not have drives.

This is achieved according to the invention in that the main phase winding is divided into two equal partial windings and an inverter for frequency multiplication the motor voltage is provided, its converter transformer from the partial windings is formed that the inverter with sinusoidal voltage pulses the same Polarity is fed, and that means for synchronizing the frequency-multiplied Voltage with the sinusoidal line frequency voltage are provided.

The advantage of this arrangement according to the invention is that you can, for example When the frequency is doubled, the number of poles ratio is half as large as the desired rotation ratio can choose, and then maintaining the normal washing motor sizing and construction double the spin speed with the required intermediate speeds with the same performance.

Another major advantage is the simple design a transformerless inverter and its control, which differ from the usual and known designs differs significantly.

For example, from DT-OS 1 610 045 the use of a Inverter with a DC link for continuous frequency change known for feeding an asynchronous motor. This converter works with changeable DC link voltage and requires considerable resources for proper operation to smooth the intermediate circuit current. In conjunction with the required extensive and complicated control electronics for the thyristors of the converter result a total price of the drive that is not justifiable for washing machines for household purposes is.

In a advantageous embodiment of the invention, one depends on the network frequency guided oscillator provided, which with integer multiples of the network frequency swings. According to the invention, the AC mains voltage is via a rectifier at the Reheschaltung of a resistor and a Zener diode and the supply voltage for the oscillator is removed from the zener diode.

The invention is explained in more detail below with reference to the drawing; In a schematic representation: FIG. 1 shows the inverter-fed asynchronous motor; figure 2 the electrical control circuit and FIG. 3 the respective voltage curve at discrete switching points.

The asynchronous motor 1 in FIG. 1 has two offset from one another by 900 el Phase windings on, the main and the auxiliary winding. The main phase winding consists of two identical partial windings 2-3 and 4-5, which are completely identical and also have the same spatial arrangement in the engine. The auxiliary phase consists of the winding 6-7. For this purpose, an operating capacitor 8 is connected in series. The two partial windings 2-3, 4-5 form the converter transformer of the inverter The inverter is in the mid-point circuit with a commutation capacitor 9 and two thyristors 10, 11 constructed as control valves; the five-phase winding 6-7, along with the run capacitor, is in parallel with the main phase windings 2-3 and 4-5 switched. When operating with frequency multiplication, i.e. with inclusion of the inverter, the sinusoidal signal applied to the input terminals 12, 13 arrives AC voltage via a rectifier arrangement built in a Graetz bridge circuit with the diodes 14 to 17 as a pulsating DC voltage to the inverter.

When operating with mains frequency, the operating voltage is applied directly the motor terminals, which are labeled 18 and 19. The control signals for the two thyristors 10, 11 of the inverter are in a flip-flop with generated by a control oscillator. The sinusoidal mains voltage (Figure 3a) for supply the According to FIG. 2, control is at terminals 12 and 13. The supply takes place via the rectifier valves 20, 21, 23, the resistor 24, the capacitor 27 and the Zener diode 28. The reference potential 29 of the control circuit is the same as that of the inverter in Figure 1. The one at terminals 12 and 13 applied mains voltage is via the rectifier valves 20, 21 to the series circuit of the resistor 24 and the zener diode 28 placed. The supply voltage for the control oscillator is taken from the zener diode 28.

The control oscillator consists of a unijunction transistor 30, the resistors 31, 32, 33 and the capacitor 34. The frequency of the control pulses is set with resistor 31 and capacitor 34; in the example tilts the oscillator twice during a mains voltage half-cycle (frequency doubling; Figure 3b). The occurring at the resistor 33 LI-Sr) output pulses / control a from the transistors 35, 36, the capacitors 37, 38 and the resistors 39, 40, 41, 42, 43 and 44 in a known manner constructed flip-flop circuit. The tipping impulses at the output of the flip-flop circuit are shown in Figure 3d.

By means of these toggle pulses, two switching stages are set up in the same way controlled, which trigger the thyristors 10 and 11 of the inverter. Such Switching stage consists of a transistor 45 or 46, each with an RC element, which is formed from a resistor 47 or 48 and a capacitor 49 or 50 is. The supply of these switching stages takes place via the rectifier valves 20, 21 and 22 and resistors 25 and 26. The pulses of the flip-flop circuit are taken from the collectors of transistors 35 and 36 and each over the resistors 51 and 52 led to the transistors 45 and 46, respectively.

The transistors 45 and 46 then also alternately toggle accordingly in their respective managerial resp.

non-conductive state. During the non-conductive state of the Transistors 45 and 46 become capacitors 49 and 50 via resistors 25 and 26 charged. When the voltages on capacitors 9 and 50 increase the breakdown voltages of the trigger diodes 53 and 54 exceed, these will conductive and the voltage on capacitors 49 and 50 ignites the thyristors. During the conductive state of the transistors 45 and 46, the capacitors discharge 49 and 50 via the resistors 47 and 48 and the collector-emitter paths of the Transistors. The thyristors cannot be ignited (FIG. 3e). at sinusoidal alternating voltage curve (Figure 3a) then results in a curve of Inverter voltage according to Figure 3f. It is now assumed that the thyristor 10 is in its conductive state as a result of the pulses via the trigger diode 53; the thyristor 11 is accordingly in its non-conductive state. Then a current driven by the rectifier bridge 14 to 17 flows in the winding part 2-3, i.e. the winding part 2-3 has full operating voltage.

However, since the winding part 4-5, as already described above, the same structure and also the same spatial arrangement in Motor like the winding part 2-3 has, as a result of the transformer action this arrangement also induces the same voltage in the winding part 4-5. To the Motor terminals 18, 19 therefore have twice the operating voltage in inverter operation with double frequency. This also applies in reverse, if the thyristor 11 in its conductive, the thyristor 10 in its non-conductive Condition is located; it is then the same voltage from the winding part 4-5 in the Winding part 2-3 induced. When operating with mains frequency, the operating voltage connected directly to the motor terminals 18, 19. The relationship between tension and The frequency at the motor terminals and thus at the motor always remains the same, so that the magnetic flux in the motor to be controlled also remains the same, and so does the motor so that it is fully utilized without any additional auxiliary measures required.

d Can an operation of the motor in case of field / weakening be accepted it can be done without difficulty by adjusting the settings accordingly of the unijunction oscillator 31, 34 to increase the inverter frequency. However can only be integer multiples due to the synchronous running with the mains frequency be used.

It is within the scope of the invention, the operating capacitor from two Capacitors to form approximately the same capacity.

Since during operation with double the frequency only half Operating capacitance is required, one of these capacitors can be used as an operating capacitor while the other is used as a commutation capacitor for the inverter can be used.

It is also possible to provide a battery of operating capacitors. The individual capacitors are according to the possible variations of the Operating frequency switched on or off.

This control is preferred for the low-pole winding system Associated with skidding.

Another advantage is the multi-pole winding for washing over it also to be carried out pole-changing.

With such a measure it is possible in addition to the normal washing speed the engine at a further speed, as required for gentle washing, for example will operate.

List of the reference numerals 1 asynchronous motor 2-3, 4-5 partial winding 6-7 auxiliary winding 8 operating capacitor 9 commutation capacitor 10, 11 thyristor 12, 13 terminal 14, 15, 16, 17 diode 18, 19 motor terminal 20, 21, 22, 23 rectifier valve 24, 25, 26 resistor 27 capacitor 28 zener diode 29 Reference potential 30 unijunction transistor 31, 32, 33 resistor 34 capacitor 35, 36 transistor 37, 38 capacitor 39, 40, 41, 42, 43, 44 resistor 45, 46 transistor 47, 48 resistor 49, 50 capacitor 51, 52 resistor 53, 54 trigger diode 6 claims 3 sheets drawings

Claims (6)

Arrangement for multiplying the speed of a single-phase Asynchronous motor with a main phase winding and an auxiliary phase winding with an operating capacitor, in particular for driving a washing machine, d a d u r c h e k e n n n n e i c h n e t that the main phase winding in two equal Part windings (2-3, 4-5) is divided and an inverter for frequency multiplication the motor voltage is provided, its converter transformer from the partial windings is formed that the inverter with sinusoidal voltage pulses the same Polarity is fed and that means for synchronizing the frequency-multiplied Voltage with the sinusoidal, line-frequency voltage are provided. 2.) Arrangement according to claim 1, characterized in that one of the mains frequency-guided oscillator is provided, which with integer multiples the network frequency oscillates. 3.) Arrangement according to claim 2, characterized in that the AC mains voltage Via a rectifier on the series connection of a resistor and a Zener diode and the supply voltage for the oscillator at the Zener diode has been removed. 4.) Arrangement according to at least one of the preceding claims, characterized in that the auxiliary phase winding (6-7) is connected in series Operating capacitor (8) formed from two capacitors, each with half the capacity is and during operation with doubled frequency of one capacitor as Commutation capacitor of the inverter is used. 5.) Arrangement according to at least one of claims 1 to 4, characterized characterized in that a battery of operating capacitors is provided, whose individual condenser. Can be switched on or off according to the operating frequency are trained. 6.) Asynchronous motor for washing machines in particular with two winding systems different number of poles, characterized in that the low-pole winding system is fed via an arrangement according to claims 1 to 5 and the multi-pole Winding system is designed to be pole-changing.