DE1945083C3 - Device for reversing the direction of rotation of a single-phase capacitor motor - Google Patents

Description

In a device for reversing the direction of rotation of a single-phase capacitor motor, there is a sudden changeover not possible during the run, as the speed in the first direction is considerably reduced must be before the switchover, d. H. the restart can take place after interchanging the phases. this often leads to difficulties because in different devices, e.g. B. washing machines and dishwashers, a switchover with a currentless break is not desired or not possible at all. So it already had one Device known (DT-AS 1149 796), in which the two windings of the motor on one side via a Capacitor with each other and each with a supply line with a temperature-dependent switching device are connected. With this device there is a sufficient break for the The motor coasts down before it is switched on again in the opposite direction, but there are two Heating windings, two bimetal strips and additional switches: · necessary.

The invention is based on such a device for reversing the direction of rotation of a single-phase capacitor motor, Its two windings on one side with each other via a capacitor and each via a supply line are connected to a temperature-dependent switching device.

The invention sets itself the task of a device the aforementioned type to simplify significantly and achieved this in that the switching device only has a single temperature-dependent component which, when the first lead is live, has an in of the non-current-carrying second supply line lying switch opens, which opens after switching over the Direction of rotation, d. H. first supply line de-energized and second supply line connected to voltage, delayed closes again. . · ■,

The invention is based on two exemplary embodiments Hand of the drawings explained below. The Fig. and 2 each shows the circuit of Reversing device in connection with the motor.

In Fig. 1 the current flows from the conductor R via the changeover switch 1 and its contact 2 through the thermal relay 3 to the main winding 4 of the motor 5 and through this back to the conductor MP. A two-current flows through the capacitor 6 and phase-shifted the auxiliary winding 7 and also flows from this back to the conductor MP. The motor runs in the first direction of rotation.

Inside the thermal relay 3 is in the supply line 8 to the main winding 4, a heating winding 9 is connected. This surrounds a bimetal strip 10, which in turn is in the lead 11 to the auxiliary winding 7 is connected. A contact 12 is seated at the free end of the bimetal strip 10 an intermediate switch inserted into the line 11 13. The heating of the bimetal becomes the Contact 12 lifted and switch 13 opened.

If switch 1 is switched to contact! 4, then, since the switch 13 is still open, the motor is initially de-energized and runs out. There too Heating coil 9 is de-energized, the bimetallic strip 10 cools, and the switch 13 then closes, so that now the current through the line 11 on the one hand by the Auxiliary winding 7 and a branch current on the other hand through the capacitor 6 out of phase through the Main winding 4 can flow. The motor now runs in the other direction of rotation.

The opening time of the intermediate switch 13 is matched to the engine characteristics that the engine after switching over of switch 1 can run down in the opposite direction of rotation until restarting.

A modified embodiment is shown in FIG. Here the thermal relay is connected between a double-pole changeover switch 15 and the conductor R. In the relay 16, both a bimetallic strip 17 and a heating winding 18 are connected in the supply line 8, in series and in such a way that the heating winding in turn surrounds the bimetal. An intermediate switch 19 is inserted into the supply line 11, its liftable contact 20 being seated on a resilient intermediate piece 21 of the supply line. This intermediate piece 21 is connected to the bimetal strip 17 via a toggle spring 22.

If the contact 23 is closed in the changeover switch 15, the current flows from the conductor R via the bimetallic strip 17 through the heating winding 18 to the main winding 4 of the motor 5 and via the capacitor 6, out of phase, to the auxiliary winding 7; the motor runs again in one direction of rotation. The heating coil 18 heats the bimetallic strip 17 and this deflects downward in the plane of the drawing. As a result, the spring 11 tilts and thereby takes the intermediate piece 21 with the contact 20 upwards in the plane of the drawing. The switch 19 is open.

As far as the arrangement agrees in its mode of operation with that according to FIG. 1 match. Additionally is here however, an auxiliary circuit 24 is provided which bridges the heating winding 18 when the bimetal strip 17 excessively dislodges due to excessive heating. In this case, an auxiliary switch 25 closes so that the Current in line 8 through the bimetal strip and the auxiliary circuit 24 to the exclusion of the Heater 18 flows to the engine. This has the advantage that excessive heating of the heating coil is avoided as it can cool down during its bridging. At the same time then the cools Bimetal strips also a little off; the auxiliary switch 25 opens again and the winding 18 is again heated. The play between switching the auxiliary switch 25 on and off is coordinated so that the movement of the bimetallic strip remains only slightly and the s toggle spring 22 does not affect, so that the intermediate switch 19 remains open in this direction of rotation while the engine is running.

After switching the switch 15 and closing the contact 26, the motor is de-energized again, and ίο only after the bimetal 17 has cooled down and closed of switch 19, the current flows through line 11, so that the motor can start in the opposite direction of rotation.

1 sheet of drawings

Claims (4)

Patent claims: 1. Device for reversing the direction of rotation of a single-phase capacitor motor, its two windings on one side via a condenser with each other and each via a supply line with a temperature-dependent one Switching device are connected, characterized in that the switching device (3,16) only a single temperature-dependent one Has component (10, 17), which when conducting first supply line a switch (13, 19) located in the non-current-carrying second supply line opens, which opens after switching the direction of rotation, d. H. first supply line de-energized and second supply line connected to voltage, delayed closes again 2. Device according to claim 1, characterized in that between the motor (5) and changeover switch (1) in the supply line (8) to the main winding (4) a heating winding (9) is connected and this one into the The supply line (11) to the auxiliary winding (7) surrounds the switched bimetallic strip (10) which has a contact (12) an intermediate switch (13) in the supply line (11) for Auxiliary winding carries. 3. Device according to claim 1, characterized in that in the supply line (8) to the main winding (4) a bimetallic strip (17) and one connected in series with this, surrounding the bimetallic strip Heating coil (18) are connected and the bimetal strip has a contact (20) of an intermediate switch (19) in the feed line (11) to the auxiliary winding (7) affected. 4. Device according to claim 3, characterized by one in a known manner from Bimetallic strip (17) which can be switched on via an auxiliary switch (25) in the event of excessive deflection, the heating coil (18) bridging auxiliary circuit (24). 40