Function Of Starter
... In this method, 3-phase auto transformer with fixed tappings is used to obtain reduced voltage for starting the 3-phase induction motors. Normally 50% to 60% tappings can be used to obtain a safe value of starting current. Thus, 50% to 60% of the rated voltage is applied at starting and the auto tra ...
... In this method, 3-phase auto transformer with fixed tappings is used to obtain reduced voltage for starting the 3-phase induction motors. Normally 50% to 60% tappings can be used to obtain a safe value of starting current. Thus, 50% to 60% of the rated voltage is applied at starting and the auto tra ...
A Merged-Stage High Efficiency High Power Factor HB
... output. This topology is similar to the one presented in [17,18], used for fluorescent lamps. However, unlike the previous solution, it does not need a big electrolytic capacitor and can operate with high input voltages, i.e. full range of line voltages. In this converter, both stages share a half-b ...
... output. This topology is similar to the one presented in [17,18], used for fluorescent lamps. However, unlike the previous solution, it does not need a big electrolytic capacitor and can operate with high input voltages, i.e. full range of line voltages. In this converter, both stages share a half-b ...
THE HQ-170A ATION S COMMUN 1C RECEIVER
... some cases this being quite obvious by producing 2 spot tuning or 2 peak S meter readings. After tuning in the constant carrier and peaking the S meter, taking the above precautions, rotate the slot frequency control. It will be noticed that upon approaching the zero setting, the S meter reading wil ...
... some cases this being quite obvious by producing 2 spot tuning or 2 peak S meter readings. After tuning in the constant carrier and peaking the S meter, taking the above precautions, rotate the slot frequency control. It will be noticed that upon approaching the zero setting, the S meter reading wil ...
Microsoft Word Format - University of Toronto Physics
... voltage waveform amplitude at the device terminals is large enough to cause the voltage to fall below threshold ET over a portion of each cycle. The domain transit time must be less than the resonant period of the circuit so that the domain may disappear into the anode while the voltage is below thr ...
... voltage waveform amplitude at the device terminals is large enough to cause the voltage to fall below threshold ET over a portion of each cycle. The domain transit time must be less than the resonant period of the circuit so that the domain may disappear into the anode while the voltage is below thr ...
i-class Induction Heating
... Manual via front panel (only jumper on Emergency-OFF-Interlock) 25-pin. Sub-D-connector with main analog and digital signals And a 9-pin.-Sub-D-Interface to load up new Firmware. Optional an additional Interface (also after installation) can be installed. These interface-cards are available as Profi ...
... Manual via front panel (only jumper on Emergency-OFF-Interlock) 25-pin. Sub-D-connector with main analog and digital signals And a 9-pin.-Sub-D-Interface to load up new Firmware. Optional an additional Interface (also after installation) can be installed. These interface-cards are available as Profi ...
Document
... Explain how the forces on a current-carrying coil in a magnetic field produce a turning effect on the coil. Explain how this effect is used in a simple DC electric motor. Describe the effect of changing: • the size of the electric current • the number of turns on the coil • the strength of the magne ...
... Explain how the forces on a current-carrying coil in a magnetic field produce a turning effect on the coil. Explain how this effect is used in a simple DC electric motor. Describe the effect of changing: • the size of the electric current • the number of turns on the coil • the strength of the magne ...
Design of a Regenerative Receiver for the Short-Wave - Inictel-UNI
... 7. Will operate from a 3-volt battery supply. 8. Must have low parts count and may use only BJTs as active devices. 9. Must be fully operational when built on a solderless breadboard. The reason for using the Armstrong topology is that the receiver can be designed with little effort and high chances ...
... 7. Will operate from a 3-volt battery supply. 8. Must have low parts count and may use only BJTs as active devices. 9. Must be fully operational when built on a solderless breadboard. The reason for using the Armstrong topology is that the receiver can be designed with little effort and high chances ...
25471_energy_conversion_9
... • Reluctance of air gap in this machine >> Reluctance of either rotor or stator, B takes shortest possible path across air gap & jumps perpendicularly between rotor & stator • To develop a sinusoidal voltage in this machine, B should vary sinusoidally along the surface of air gap • it needs H to v ...
... • Reluctance of air gap in this machine >> Reluctance of either rotor or stator, B takes shortest possible path across air gap & jumps perpendicularly between rotor & stator • To develop a sinusoidal voltage in this machine, B should vary sinusoidally along the surface of air gap • it needs H to v ...
Resonant inductive coupling
Resonant inductive coupling or electrodynamic induction is the near field wireless transmission of electrical energy between two magnetically coupled coils that are part of resonant circuits tuned to resonate at the same frequency. This process occurs in a resonant transformer, an electrical component which consists of two high Q coils wound on the same core with capacitors connected across the windings to make two coupled LC circuits. Resonant transformers are widely used in radio circuits as bandpass filters, and in switching power supplies. Resonant inductive coupling is also being used in wireless power systems. Here the two LC circuits are in different devices; a transmitter coil in one device transmits electric power across an intervening space to a resonant receiver coil in another device. This technology is being developed for powering and charging portable devices such as cellphones and tablet computers at a distance, without being tethered to an outlet.Resonant transfer works by making a coil ring with an oscillating current. This generates an oscillating magnetic field. Because the coil is highly resonant, any energy placed in the coil dies away relatively slowly over very many cycles; but if a second coil is brought near it, the coil can pick up most of the energy before it is lost, even if it is some distance away. The fields used are predominately non-radiative, near fields (sometimes called evanescent waves), as all hardware is kept well within the 1/4 wavelength distance they radiate little energy from the transmitter to infinity.One of the applications of the resonant transformer is for the CCFL inverter. Another application of the resonant transformer is to couple between stages of a superheterodyne receiver, where the selectivity of the receiver is provided by tuned transformers in the intermediate-frequency amplifiers. The Tesla coil is a resonant transformer circuit used to generate very high voltages, and is able to provide much higher current than high voltage electrostatic machines such as the Van de Graaff generator. Resonant energy transfer is the operating principle behind proposed short range (up to 2 metre) wireless electricity systems such as WiTricity or Rezence and systems that have already been deployed, such as Qi power transfer, passive RFID tags and contactless smart cards.