TH20646B - "The machine starts to spin the electronic motor" - Google Patents

Abstract

Electronic motor starters for use in single phase induction motors where the hysteresis amplitude can be adjusted in the 75 Volt range provided for control of special response properties. Positive reverse of the NAND gate and the stability of the input signal. This invention makes use of the induced voltage across the motor's starting winding to initiate the motor rotation and stabilize the motor operation.

Claims (8)

1. The machine starts to spin the electronic motor. For use with single-phase induction motors. Whose starting winding consists of: Triacs with the first end connected to the motor power source. The second end is attached to the coil starts turning and the gate end. The rectifier path (7) includes the first diode (D2) attached to the first end of the triac and the first electrolytic capacitor (C4) for arranging the power source. The gate (8) power path, with the first and second distributed resister (R7) and (R8) connected to the rectifier path. Zener diode (ZD) and the first filter capacitor (C2), each connected in parallel with the second distribution resistor (R8), to supply the voltage that powers the gate path. Capture the voltage signal (9) across the winding, starting to rotate. Which has a second diode (D1), a third and fourth distribution resistor (R1 and R2), and a second filter capacitor (C1). To the adjustable hysteresis resistor (R3) attached to the third distribution resistor coupling (R1 and R3), the first and second NAND gate, M1 and M2, and the resistor. Feedback (R4), the swing path (11) connected between the first and second NAND gates. (M1 and M2), including the third and fourth NAND gates (M3 and M4) the first resistor (R5) and the second electrolytic capacitor (C3) and Trajectory to ignite (TRIGGER MEANS) (12), which consists of a second resistor (R6) attached to an output of the fourth NAND gate (M4) transistor (TR), with the base end attached to the second resistor (R6). The emitter end is connected to earth. And the end of the collector and the arrester coil (PC) is connected between the transistor emitter end (TR), the rectifier path (7) and the gate end of the triac. The collector coil (PC) initially excites the triac to begin electric rotation until a voltage is applied across it. Reaches a predetermined value and thereafter reduces triac excitation to separate the starting winding from the motor circuit allowing the motor to operate normally. 2.Electronic motor starter for use with single phase induction motors whose starting coils are composed of Triac, which has the first tip attached to the motor power source. The second end is connected to the winding and gate end. The rectifier path connected to the first end of the triac for arranging the power source. Path connected to the rectifier path To supply the voltage that powers the gate, the voltage sensing pathway senses the voltage across the winding, starting to rotate. The voltage sensing path has an output. The hysteresis amplitude modulation path consists of a hysteresis rectifier. Connected to the coupling is coupled to the output of the aforementioned voltage signal detection path The first and second gates are connected in series. And the feedback resistor is connected between the output of the second gate And the input of the first such gate The swing path consists of a third and fourth gates connected in series. The input of the third gate Will be connected to the connection between the first and the second gate A path connected to the output of the fourth gate. For igniting the gate of the Triac. The jump at the trigger path will begin to induce the triac to the coil to begin electric rotation until the induced voltage across the sensed coil by the aforementioned voltage signal sensing path reaches the value specified by Predetermined and after that the trajectory minimizes triac excitation to separate the starting winding from the motor circuit. By allowing the motor to operate normally 3. The machine starts to spin the electronic motor as stated in claim 2 where each such gate is a NAND gate. 4. The machine starts rotating the electronic motor as stated in claim 2 where each such gate is a Schmitt NOT gate. 5. The machine starts to spin the electronic motor as described in claim 2, where the trajectory will consist of a detector coil attached to the tip of the triac. 6. The machine starts to spin the electronic motor as described in claim 5, where the trajectory consists of a transistor with a base end connected to the output of the fourth gate. Said with the resistor, the emitter end is connected to the ground wire And the end of the collector is connected to the second coil of the said coil 7.Electronic motor starters as described in claim 5, where the trajectory also consists of a resistor. And the electrolytic capacitor connected in series to the primary winding of the arrestor coil straddles that second end. And at the end of the said gate of the aforementioned Triac 8.Electronic motor starts as specified in claim 2 where the trajectory ignites. It also consists of a diode bridge with a first end coupled with a first resistor to the aforementioned Triac end. And the second end is connected to the said end of the aforementioned Triac The photocopper's light-receiving transistor is connected in series with the second resistor across the third and fourth ends of the diode bridge. The photocopper's light emitting diodes are connected to the said fourth gate output. And thyristors connected in parallel with the transistor Straddles the third and fourth ends of the diode bridge. The thyristor has a gate end connected to the collector end of the photoresistor.