RU2013113861A - STAND FOR RESEARCH OF RESONANCE ELECTRIC POWER TRANSMISSION SYSTEM - Google Patents

Abstract

A stand for researching a resonant system for transmitting electric energy, comprising an increased frequency alternating current source, a transmitting transformer connected by an electric conductor to a receiving transformer and a load, sensors and measuring instruments, characterized in that the increased and tunable frequency alternating current source through a first switch and an electric store capacitors connected to the low-voltage winding of the transmitting high-frequency resonant transformer, which form an electric circuit of a power source for supplying electric energy of alternating current of increased frequency to a high-voltage electric circuit containing a high-voltage single-layer cylindrical winding of a transmitting high-frequency resonant transformer, the upper high-voltage output of which is connected by a wire of a power transmission line to the upper high-voltage output of a high-voltage single-layer cylindrical winding of a receiving high-frequency resonant transformer, both high voltage monolith Cylindrical coil windings are wound on frames made of electrical insulating material, equipped with contact bends and mounted on the horizontal electrically conductive surface of the carrier grounded platform so that the axis of symmetry of the cylindrical windings are parallel to each other and perpendicular to the surface of the carrier platform, while the high-voltage winding of the receiving high-frequency resonant transformer is connected to the electrical circuit load consisting of a low voltage winding receiving high-frequency reason

Claims (1)

A stand for researching a resonant system for transmitting electric energy, comprising an increased frequency alternating current source, a transmitting transformer connected by an electric conductor to a receiving transformer and a load, sensors and measuring instruments, characterized in that the increased and tunable frequency alternating current source through a first switch and an electric store capacitors connected to the low-voltage winding of the transmitting high-frequency resonant transformer, which form an electric circuit of a power source for supplying electric energy of alternating current of increased frequency to a high-voltage electric circuit containing a high-voltage single-layer cylindrical winding of a transmitting high-frequency resonant transformer, the upper high-voltage output of which is connected by a wire of a power transmission line to the upper high-voltage output of a high-voltage single-layer cylindrical winding of a receiving high-frequency resonant transformer, both high voltage monolith Cylindrical coil windings are wound on frames made of electrical insulating material, equipped with contact bends and mounted on the horizontal electrically conductive surface of the carrier grounded platform so that the axis of symmetry of the cylindrical windings are parallel to each other and perpendicular to the surface of the carrier platform, while the high-voltage winding of the receiving high-frequency resonant transformer is connected to the electrical circuit load consisting of a low voltage winding receiving high-frequency reason a transformer installed in the lower part of the high-voltage winding, the second switch and a store of electric capacitors connected to an electric load, while the lower terminals of the high-voltage windings of the resonant transformers are connected by conductors through the first and second sensors of magnitude and phase of the electric current, a double switch, a common point and a third sensor of magnitude and phase of electric current, as well as contact taps of high-voltage windings through a probe and a potential meter, with electrically conductive The surface of the carrier platform and the ground, at the input of the low-voltage winding of the transmitting high-frequency resonant transformer and at the output of the low-voltage winding of the receiving high-frequency resonant transformer, voltage and current meters are installed, while the output of the potential meter at the contact taps of the high-voltage windings, the outputs of the first, second and third sensors of magnitude and phase current, as well as voltage and current meters in the low-voltage winding of a transmitting high-frequency resonant transformer the transmitter and the low-voltage winding of the receiving high-frequency resonant transformer are connected to the inputs of a multi-channel oscilloscope connected to a computer for monitoring, monitoring and recording the parameters measured by them.