DE621467C - Device for controlling single-phase induction motors with auxiliary phase winding and starting capacitor - Google Patents

Description

Device for controlling single-phase induction motors with auxiliary phase winding and starting capacitor In single-phase induction motors, it is desirable to increase the capacitance to reduce the capacitor connected upstream of the auxiliary phase winding after start-up, so that it is not overloaded by the high capacitive current. To this The purpose is either to switch off the start-up capacitor after start-up or if one permanently switched on operating capacitor and one only at start-up switched on additional capacitor selects this alone. So in both cases a capacitor can be switched off, which is often automatically by means of a function by the speed, the current or the voltage of controlled switching devices happens. For single-phase induction motors with main and disconnectable auxiliary phase winding it is also known to increase the starting torque by means of an in the circuit of the starting winding switched on temperature-dependent resistor to regulate automatically in order to Connection of the motor to networks with different voltages always has the same starting torque to achieve. In addition to the temperature-dependent resistance, there is also a switching device here used, through which the auxiliary phase winding is switched off after start-up: This switching device is undesirable for single-phase induction motors of lower power, because this increases the acquisition costs and reduces operational reliability especially if the engine is used, for example, to drive household machines and the like, is not operated by experts. There are also automatic starting devices for single-phase induction motors without switching devices provided with contacts known, in which the control is achieved only by means of a choke coil, the one that changes depending on the strength of the current in the main phase magnetic circuit owns. This choke coil has a displaceable against spring force Armature and is therefore also cumbersome and expensive, making it for single-phase induction motors lower performance is not considered.

According to the invention, the automatic control of the single-phase induction motor with auxiliary winding and capacitor, eliminating the need for a switching device allows the temperature-dependent resistors in the circuit with the Capacitor connected auxiliary phase winding are switched on so that they are under the capacitive effect of the capacitor according to the flow of the auxiliary phase current reduce starting. Using a resistor with a positive Temperature coefficients, e.g. B. made of tungsten, this resistor becomes the capacitor upstream. This circuit is shown as an exemplary embodiment in the drawing. The main winding 12 of the single-phase induction motor is connected to the single-phase network i i connected. A capacitor 14 is connected in series with the auxiliary phase winding 13, which remains permanently switched on as an operating capacitor. Parallel to this lies an auxiliary capacitor 15 in series with a resistor, which is only used during start-up 16 with positive temperature coefficient. When cold, this has resistance a low ohmic value, so that the auxiliary capacitor 15 has the normal starting current can accommodate. The resistor 16 now heats up under the influence of the starting current gradually, as a result of which its ohmic value increases and the one flowing through the auxiliary capacitor 15 Current is reduced accordingly. This gives the auxiliary phase winding 13 thus a gradually decreasing capacitive current, so that overloads be avoided.

You can also use a resistor with a negative temperature coefficient, e.g. B. Manganese dioxide, uranium dioxide o. The like. Use, which is then connected in parallel to the capacitor 14. When cold, this resistor has a high ohmic value, so that the entire starting current flows through the capacitor. Take zunehmender- with heating of the ohmic value of the resistor from t is gradually bridged whereby the capacitor and its current decreases accordingly.

By used according to the invention, depending on the Temperature changing resistances will have the capacitive effect of the capacitor reduced during motor start-up without the need for any switching device is, so compared to the known starting devices with centrifugal switches or other switching devices achieved a very significant simplification that of is of great practical importance because the capacitor motors are mainly used for Smaller capacities are built and used to drive household machines, etc. which do not require proper operation and maintenance of the motors can be.

The resistors can be separated from the capacitor and attached to the control panel or another suitable location, as this, both those with a positive as well as those with a negative temperature coefficient, many times over are housed in a vessel filled with neutral gas so that they can be used in the do not oxidize or decompose at high temperatures. You can have these resistances Appropriately use as signal lamps at the same time. This is particularly recommended for Use of a resistor made of tungsten because it has a high temperature very high ear value and therefore only has a very low power consumption.

Claims (4)

PATENT CLAIMS: i. Device for controlling single-phase induction motors with auxiliary phases winding and starting capacitor, characterized in that the capacitive effect of the starting capacitor (15) due to temperature-dependent resistors (16) is automatically reduced under the influence of the auxiliary phase current. 2. Establishment according to claim i, characterized in that a resistor with a positive temperature coefficient zient iiz series is connected to the capacitor. - 3. Device according to claim i, characterized in that a resistor with a negative temperature coefficient is connected in parallel to the capacitor. 4. Device according to claim i, characterized characterized in that the resistor is used as a signal lamp to indicate the switch-on state of the motor .is.