ELECTRIC CIRCUIT series1970-01-01T00:00:00+00:00ELECTRIC CIRCUIT series. Components are arranged one after another (in series) along the circuit. The current therefore flows through each element in turn. If one element is removed then the circuit is broken. This animation shows a simple DC electrica...PT11Shttps://d3e1m60ptf1oym.cloudfront.net/e023bc73-a2c0-4e7f-a498-4593385f037e/Electric-circuit-bulbs-series-FHD-Russell-Kightley_xlarge.jpghttps://d3e1m60ptf1oym.cloudfront.net/e023bc73-a2c0-4e7f-a498-4593385f037e/Electric-circuit-bulbs-series-FHD-Russell-Kightley_mp4_hd_video.mp4https://www.scientific.pictures/-/galleries/physics/-/medias/e023bc73-a2c0-4e7f-a498-4593385f037e/pricehttps://www.scientific.pictures/-/galleries/physics/-/medias/e023bc73-a2c0-4e7f-a498-4593385f037e/price
ELECTRIC CIRCUIT parallel
ELECTRIC CIRCUIT parallel: light bulbs (globes or lamps) in parallel.
PARALLEL ELECTRIC CIRCUITS have elements arranged side by side (in parallel) along the circuit. The current therefore flows through each element at the same time. If one element is removed then the circuit is not broken because current can still flow through the collateral route. This animation shows a simple DC electrical circuit with one bulb. A second bulb appears in parallel. Notice how both bulbs remain as bright as the original lone bulb and how the amount of current flowing increases.
EXPLANATION: as the second bulb appears, so the resistance of the circuit drops. In this simple case we ignore the resistance of the wire. Adding an identical second bulb in parallel will give the electric current two routes around the circuit instead of one. The resistance therefore drops by half (there is twice the available pathway for the current). The voltage provided by the battery (cell) stays the same. With half the resistance, the current doubles. With double the current flowing down the same voltage drop, the energy dissipated by the entire circuit doubles. This doubled energy is now divided between the two bulbs. Each bulb therefore has half of double the energy or the same as before. Consequently, when you add a second bulb in parallel, the brightness of the bulbs is the same as the brightness of the bulb in the original circuit.
SI UNITS used in electricity:
VOLTS (V): unit of potential difference, emf, or voltage
OHM (Ω): unit of resistance
AMPS (AMPERES) (A): unit of current
COULOMBS (C): unit of charge (= the charge moved when one amp of current runs for one second).
WATTS (W): unit of power (power energy per unit time). In electrical circuits, one watt is produced when a current of one amp flows down a potential difference of one volt.
JOULE (J): unit of energy.
these units are all related to each other by simple rules. For example, if the potential difference is 1 volt and the resistance is 1 ohm then the current that will flow will be 1 amp. One watt is one joule per second. One amp is one coulomb per second. All things being equal, if you double the voltage the current will double. If you halve the voltage the current will halve. If you double the resistance the current will halve. If you halve the resistance the current will double.
PARALLEL ELECTRIC CIRCUITS have elements arranged side by side (in parallel) along the circuit. The current therefore flows through each element at the same time. If one element is removed then the circuit is not broken because current can still flow through the collateral route. This animation shows a simple DC electrical circuit with one bulb. A second bulb appears in parallel. Notice how both bulbs remain as bright as the original lone bulb and how the amount of current flowing increases.
EXPLANATION: as the second bulb appears, so the resistance of the circuit drops. In this simple case we ignore the resistance of the wire. Adding an identical second bulb in parallel will give the electric current two routes around the circuit instead of one. The resistance therefore drops by half (there is twice the available pathway for the current). The voltage provided by the battery (cell) stays the same. With half the resistance, the current doubles. With double the current flowing down the same voltage drop, the energy dissipated by the entire circuit doubles. This doubled energy is now divided between the two bulbs. Each bulb therefore has half of double the energy or the same as before. Consequently, when you add a second bulb in parallel, the brightness of the bulbs is the same as the brightness of the bulb in the original circuit.
SI UNITS used in electricity:
VOLTS (V): unit of potential difference, emf, or voltage
OHM (Ω): unit of resistance
AMPS (AMPERES) (A): unit of current
COULOMBS (C): unit of charge (= the charge moved when one amp of current runs for one second).
WATTS (W): unit of power (power energy per unit time). In electrical circuits, one watt is produced when a current of one amp flows down a potential difference of one volt.
JOULE (J): unit of energy.
these units are all related to each other by simple rules. For example, if the potential difference is 1 volt and the resistance is 1 ohm then the current that will flow will be 1 amp. One watt is one joule per second. One amp is one coulomb per second. All things being equal, if you double the voltage the current will double. If you halve the voltage the current will halve. If you double the resistance the current will halve. If you halve the resistance the current will double.
Animation ID: Electric-circuit-bulbs-parallel-FHD-4-Russell-Kightley
Duration: 0:12
copyright Russell Kightley
Animation resolution: 1920x1080 pixels @ 30.0 fps, ~6.8 Mbits/s
Animation keywords: battery, bulbs, charge, current, dc, direct, electric circuit, electricity, EMF, light bulb, light globe, parallel, switch, wire
ELECTRIC CIRCUIT parallel2020-08-17T08:09:57ZELECTRIC CIRCUIT parallel: light bulbs (globes or lamps) in parallel.
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