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Electrodynamics – Science of electric charges in motion Flow Electric Charges May Occur: 1. In a vacum 2. In a gas 3. In ionic solution 4. In a metallic.

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Presentation on theme: "Electrodynamics – Science of electric charges in motion Flow Electric Charges May Occur: 1. In a vacum 2. In a gas 3. In ionic solution 4. In a metallic."— Presentation transcript:

1 Electrodynamics – Science of electric charges in motion Flow Electric Charges May Occur: 1. In a vacum 2. In a gas 3. In ionic solution 4. In a metallic conductor

2 Sources of Electricity 1) Chemical 2) Mechanical 3) Solar 4) Atomic

3 Electric current flows in an electric circuit (the path over which current flows) The Three physical components of a circuit include: 1) Battery (source) 2) Conductor 3) Load (resistance) The switch – Current flows only when the switch is closed Voltage exists even when the switch is open (be careful!) Conductor

4 Three Factors That Characterize an Electric Circuit 1) Current (intensity) – Number of electrons flowing per second - Measured in amps or milliamps (A or mA) - Ampere – One coulomb quantity of electricity flowing per sec. (6.3 X 10 10 electrons per sec) 2) Potential Difference - Also referred to as the electromotive force (EMF) or voltage drop - Pressure or push behind the current - Measured in volts or kilovolts (V or kV) - Volt – That potential difference which will cause a current of one amp to flow in a circuit whose resistance is one ohm - Higher resistance leads to a larger voltage drop

5 3) Resistance – That property that impedes the flow of electrons - Measured in ohms Three Factors That Characterize an Electric Circuit Resistance Depends on Four Factors 1. Material 2. Length of material 3. Cross-sectional area 4. Temperature Ω

6 Chemical Devices That Make Electricity May be a dry cell or wet cell battery – 1) Dry Cell – Contains dry chemical along with an cathode (neg.) and anode (pos.) 2) Wet Cell – Contains wet chemical (i.e. sulfuric acid) with cathode and anode

7 More on Circuits Polarity – Direction of current flow - Assumed to be negative to positive Open Circuit – A circuit that is broken as some point Closed Circuit – A circuit that is completed (unbroken) Overloaded Circuit – Too much amperage causing over-heating in circuit - Prevented by fuses

8 Two Types of Circuits Series Circuit – One whose parts are arranged end-to-end Parallel circuit – One whose parts are arranged as branches off the main circuit

9 Connecting Meters to Circuits Voltmeter – Measures potential difference between two points in a circuit - Must be connected in parallel to work properly Ammeter – Measures the amperage in a circuit - Must be connected in series to work properly

10 Ohms Law – The value of a current in a resistance circuit supplied by direct current (DC) is equal to the voltage divided by the resistance. Ohm’s Law Ohm – German physicist – Discovered the relationship between voltage, amperage and resistance I = V/R I= Intensity (A) V = Potential Difference (V) R = Resistance (Ohms) May also be algebraically manipulated: V = I X R R = V/I V IR

11 Using Ohms Law You can find out the voltage, amperage or resistance if you know 2 of 3 variables in a circuit For example, what is the intensity of a circuit if there is 2 ohms of resistance and 10 volts? Circuit has 10 V and 2 ohms of resistance

12 Rules Differ by Circuit Type 1) Series Circuit - The amperage is the same everywhere in the circuit - The voltage and resistance is equal to the sum of the voltages and resistances of the circuit 2) Parallel Circuits: - The amperage differs in each branch, the smallest current flowing in the branch with the largest resistance. The total amperage is equal to the sum of currents provided by all sources across all resistances - The voltage is the same across the entire circuit - The total resistance is equal to the reciprocal of the whole resistance of the sum of the reciprocals of the individual resistances in the circuit

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15 Rule: The total resistance is equal to the reciprocal of the whole resistance of the sum of the reciprocals of the individual resistances in the circuit

16 Parallel Circuit

17 Storing Electrical Energy Parallel Plate Capacitors Capacitor – A device that stores electrical energy. - Used in various radiology devices (automatic exposure controls and mobile units) - Unit of capacitance – farad - Composed of: 1. Two metal plates 2. Dielectric (i.e., air) between plates 3. Battery source 4. Conductor

18 Method of Operation: 1) The plates are connected to a battery. 2) Electrons pass from the neg. battery terminal to the plate to which it’s connected 3) An equal number of electrons pass from the opposite plate to the positive battery terminal Parallel Plate Capacitor 4) When fully charged, voltage ceases to flow from source 5) Capacitor is disconnected and retains its charge until connected to a conductor. 6) The capacitor discharges in the opposite direction as the original charging current

19 The Work and Power of DC Current Power – The amount of work current can do per sec. Power is stated in Watts or Kilowatts P (Watts) = I X V P = Power I = Intensity of current in (A) V = Voltage (V) Examples 20 A X 60 V = 1200 Watts 200 mA X 60,000 =.2 A X 60,000 = 12,000 Watts (12 KW)

20 Power Loss Power is lost in the transmission of power and in x-ray equipment due to heat loss! - Also state in Watts PL (Watts) = I 2 X R PL = Power loss (Watts) I 2 = Intensity squared R = Resistance Example: How much power loss results in an electric line carrying 20 amps and 2 ohms of resistance? Answer: 20 X 20 X 2 = 800 Watts


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