Magnetic Switch・Magnetic Contactor Manual DANGER CAUTION
... Confirm that setting current is in accordance with rated current of the motor. 2)When the thermal overload relay operates, push the button after taking off the causes of overload. ...
... Confirm that setting current is in accordance with rated current of the motor. 2)When the thermal overload relay operates, push the button after taking off the causes of overload. ...
Lecture 2. Transistors
... A diode is a two terminal electrical device created by joining two materials together, one having an excess of positive charge carriers, P material, and the other having an excess of negative charge carriers, N material. When the two materials are joined there is a migration of carriers across the j ...
... A diode is a two terminal electrical device created by joining two materials together, one having an excess of positive charge carriers, P material, and the other having an excess of negative charge carriers, N material. When the two materials are joined there is a migration of carriers across the j ...
The ABC`s of electric energy and power
... The ABC’s of Electric Energy and Power Write ‘T’ for true and ‘F’ for False for the explanation of each term. If the description is false, rewrite for correction. The last one is done for you. ...
... The ABC’s of Electric Energy and Power Write ‘T’ for true and ‘F’ for False for the explanation of each term. If the description is false, rewrite for correction. The last one is done for you. ...
How is current electricity different from static electricity
... 10. What is current? 11. What is the unit measure for current and its symbol? 12. How many amps can do damage to a person? 13. How much current runs through the wires of household circuits? 14. What safety devices are put in place in homes so the current in circuits are not overloaded and start fire ...
... 10. What is current? 11. What is the unit measure for current and its symbol? 12. How many amps can do damage to a person? 13. How much current runs through the wires of household circuits? 14. What safety devices are put in place in homes so the current in circuits are not overloaded and start fire ...
EXPERIMENT 11: Uni-junction transistor (UJT) CHARACTERISTICS
... This is what makes the UJT useful, especially in simple oscillator circuits. When the emitter voltage reaches Vp, the current starts to increase and the emitter voltage starts to decrease. This is represented by negative slope of the characteristics which is referred to as the negative resistance re ...
... This is what makes the UJT useful, especially in simple oscillator circuits. When the emitter voltage reaches Vp, the current starts to increase and the emitter voltage starts to decrease. This is represented by negative slope of the characteristics which is referred to as the negative resistance re ...
Spirit 2
... transformers ideally the ratio of voltage change to the change in the number of turns in the conducting wire is equal: where “V” is voltage, “N” number of turns, “p” for primary, and “s” for secondary. Putting “Electric Current” in Process terms: Electric current can be controlled by creating a clos ...
... transformers ideally the ratio of voltage change to the change in the number of turns in the conducting wire is equal: where “V” is voltage, “N” number of turns, “p” for primary, and “s” for secondary. Putting “Electric Current” in Process terms: Electric current can be controlled by creating a clos ...
June 1999 - Vicphysics
... As in Q’n 1 for the 60 W globe to glow appropriately, the RMS current should be 0.25 A, which should also be the current through globe X (in series). (2) The voltage across globe X = 264 – 240 = 24V (1), so the power used in globe X = 24 x 0.25 = 6.0 W F = nBIl (1) = 50 x 0.040 x 1.5 x 0.050 = 0.15 ...
... As in Q’n 1 for the 60 W globe to glow appropriately, the RMS current should be 0.25 A, which should also be the current through globe X (in series). (2) The voltage across globe X = 264 – 240 = 24V (1), so the power used in globe X = 24 x 0.25 = 6.0 W F = nBIl (1) = 50 x 0.040 x 1.5 x 0.050 = 0.15 ...
unit-2: field effect transistors
... 1. The BJT is a current-controlled device since its output is determined on the input current, while FET is considered as a voltage-controlled device, because it depends on the field effect of the applied voltage. 2. The BJT (Bipolar Junction Transistor) uses both the minority and majority carriers ...
... 1. The BJT is a current-controlled device since its output is determined on the input current, while FET is considered as a voltage-controlled device, because it depends on the field effect of the applied voltage. 2. The BJT (Bipolar Junction Transistor) uses both the minority and majority carriers ...
H parameter equivalent circuit
... The input circuit appears as a resistance h11 in series with a voltage generator h12 v2. The output circuit involves two components ; a current generator h21 i1 and shunt resistance h22. ...
... The input circuit appears as a resistance h11 in series with a voltage generator h12 v2. The output circuit involves two components ; a current generator h21 i1 and shunt resistance h22. ...
Transistors-II
... • We can therefore draw an input characteristic (plotting base current IB against base-emitter voltage VBE) and • an output characteristic (plotting collector current Ic against collector-emitter voltage VCE) ...
... • We can therefore draw an input characteristic (plotting base current IB against base-emitter voltage VBE) and • an output characteristic (plotting collector current Ic against collector-emitter voltage VCE) ...
Lab I Critique
... It is assumed that the customers equipment is designed to operate when provided with that standard, specified voltage, and that such equipments are connected in parallel with respect to the internal power network. Any compensating device placed in series between the utility connection and the custom ...
... It is assumed that the customers equipment is designed to operate when provided with that standard, specified voltage, and that such equipments are connected in parallel with respect to the internal power network. Any compensating device placed in series between the utility connection and the custom ...
Section 20.2 Electric Current and Ohm`s Law
... Electric current is a continuous flow of charge. ...
... Electric current is a continuous flow of charge. ...
Worksheet - Electric Circuits
... 7) What is the current through a 400 W electric appliance when it is connected to a 120 V power line? 8) a. When an electric appliance is connected to a 120 V power line, there is a current through the appliance of 18.3 A. What is its resistance? b. What is the average amount of energy given to each ...
... 7) What is the current through a 400 W electric appliance when it is connected to a 120 V power line? 8) a. When an electric appliance is connected to a 120 V power line, there is a current through the appliance of 18.3 A. What is its resistance? b. What is the average amount of energy given to each ...
Circuit Breaker Types.ppt
... current in a network. However the instantaneous current following a fault will also contain the dc component. In a high power circuit breaker selection, the subtransient current is multiplied by a factor of 1.6 to determine the rms value of the current the circuit breaker must withstand. This curren ...
... current in a network. However the instantaneous current following a fault will also contain the dc component. In a high power circuit breaker selection, the subtransient current is multiplied by a factor of 1.6 to determine the rms value of the current the circuit breaker must withstand. This curren ...
TRIAC
TRIAC, from triode for alternating current, is a genericized tradename for an electronic component that can conduct current in either direction when it is triggered (turned on), and is formally called a bidirectional triode thyristor or bilateral triode thyristor.TRIACs are a subset of thyristors and are closely related to silicon controlled rectifiers (SCR). However, unlike SCRs, which are unidirectional devices (that is, they can conduct current only in one direction), TRIACs are bidirectional and so allow current in either direction. Another difference from SCRs is that TRIAC current can be enabled by either a positive or negative current applied to its gate electrode, whereas SCRs can be triggered only by positive current into the gate. To create a triggering current, a positive or negative voltage has to be applied to the gate with respect to the MT1 terminal (otherwise known as A1).Once triggered, the device continues to conduct until the current drops below a certain threshold called the holding current.The bidirectionality makes TRIACs very convenient switches for alternating-current (AC) circuits, also allowing them to control very large power flows with milliampere-scale gate currents. In addition, applying a trigger pulse at a controlled phase angle in an AC cycle allows control of the percentage of current that flows through the TRIAC to the load (phase control), which is commonly used, for example, in controlling the speed of low-power induction motors, in dimming lamps, and in controlling AC heating resistors.