Summary of MOTORES (parte 1): MOVIMIENTO GIRATORIO. COLECTOR

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00:00:00 - 00:05:00

The video discusses the motion of a rotary motor, specifically the collector. It shows how the rotor's rotation is simplified as a conductor in a spiral. The motor is represented in a selected image by the current entering through the upper inspirator and leaving through the lower inspirator marked with a red cross. The video explains how the machine's motion is constant because the conductor's direction is always reversed in the neutral zone.

  • 00:00:00 This video discusses the motion of a rotary motor, specifically the collector. Once the shield is removed from the gearbox, the stator can be identified with the coils of excitation. Inside this, the induced current is created by the collector in the right-hand side. The rotor's rotation is simplified as a conductor in a spiral. The poles of excitation of the motor are electric fields, which produce a magnetic field in which the rotor is located. When the conductor in a spiral is connected to the collector and two screens with the continuous voltage generator rotates, the circuit's travel is marked by a red line. The arrows indicate the direction of the current. The motor is represented in a selected image by the current entering through the upper inspirator and leaving through the lower inspirator marked with a red cross. The field of excitation is now symbolized by green field lines crossing the conductor in a circular path. The field of the conductor in the upper part of the inspirator is oriented to the force towards the left. Opposite to the direction of the current, in the lower part of the inspirator the field is oriented towards the force towards the right. The total magnetic field resulting from the current in the conductor is created by the field lines intersect
  • 00:05:00 This video shows a rotating machine called a motor that is oriented towards the right. The forces that act on the rotor cause it to rotate. The rotor's conductor provides the rotational force that brings it to a stop. When the forces are in equilibrium, the zone of neutral exists. The process is repeated, but if the conductor's zone of neutrality changes direction, the direction of the current in the rotor also changes. The forces and current in the rotor continue to rotate in a circular fashion, because the direction of the current always reverses in the neutral zone. The machine's motion is constant because the conductor's direction is always reversed in the neutral zone.

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