Relationships in Circuits

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Presentation transcript:

Relationships in Circuits S1-3-14 Compare and contrast voltage (electric potential difference) and current in series and parallel circuits. Include: cells, resistance S1-3-16 Investigate and describe qualitatively the relationship among current, voltage (electric potential difference), and resistance in a simple electric circuit S1-3-16 Relate the energy dissipated in a circuit to the resistance, current, and brightness of bulbs

Relationships in Series Circuits… Remember that a series circuit has only one path for electrons to follow. Because of this, there are basic relationships (rules) that are true in all series circuits: 1. The same current flows through each part of a series circuit. In a series circuit, the amperage (current) at any point in the circuit is the same. Notice from the diagram that 1 amp continually flows through the circuit.

Relationships in Series Circuits… 2. The total resistance of a series circuit is equal to the sum of individual resistances. In a series circuit you will need to calculate the total resistance. This is done by adding up the resistance of each component in series.

Relationships in Series Circuits… 3. The sum of the individual voltage drops equals the total voltage from the power source. The voltage from the battery or cell is divided up amongst all the loads, so therefore: V total = V1 + V2 + V3 ... In our example, this means that 5V + 5V = 10V. All the energy going into the circuit is used by the loads.

Relationships in Series Circuits… 4. If the circuit is broken at any point, no current will flow. The best way to illustrate this is with a string of light bulbs. If one is burnt out, the whole thing stops working.

Relationships in Parallel Circuits… Remember that a parallel circuit has many paths for electrons to follow. Because of this, there are basic relationships (rules) that are true in all parallel circuits: 1. A parallel circuit has two or more paths for current to flow through. Remember that PARALLEL means two paths up to thousands of paths. The flow of electricity is divided between each according to the resistance along each route Every time a path is added, more current can flow.

Relationships in Parallel Circuits… 2. Voltage is the same across each component of the parallel circuit. Every path will get the full amount of energy that the power source is producing. This is why lights that are wired in parallel are brighter than those wired in series

Relationships in Parallel Circuits… 3. The total current from the source is divided amongst each path. The current in each path of the circuit must add to equal the source current. Each time a new path is added, the total current will increase

Summary of Series and Parallel Circuits… Relationship Series Parallel Number of paths Current Voltage Resistance Brightness of Lights When a path is broken