Resistor ?

Question

When a resistor connects the + and - terminals of a battery, what happens?

Answer 1

Current flows. The greater the resistance, the less current. The resistor heats up as well, so as well as their resistance, and the tolerance of the resistance value, resistor are rated in watts, telling how much heat they can dissipate, indicating the current (amperes) that they can safely handle.

Answer 2

electricity flows through the resistor. The resistance to current converts electrical energy to heat energy based on the formula E=ixR. This also works out as i=E/R. When you know the current, you find the power with the formula P=i^2xR, or P=ixE
The power is the amount of heat generated, also. If you put the resistor in a cup of water, you will have a water heater.
If you exceed the power rating of the resistor, then the magic smoke comes out and it doesn't work anymore.
(All electronics work with magic smoke. If you let it out, they don't work.)

Answer 3

The resistor will resist some electricity, or short-circuit the battery, depending on the level of resistance.. It happens when anything directly connects the pos + negative ends.

Answer 4

The amount of current flowing out of the battery will be limited by the resistor and be dissipated in the form of heat.

Answer 5

Hi. The resistor may get hot as it tries to limit the flow of electricity.

Answer 6

The voltage potential (voltage of the battery) will show across the resistor, and the amperage running across will be the voltage divided by the resistance in Ohms.
The Wattage dissipated across the resistor will be equal to voltage times amperage.

Answer 7

Current flows.

Answer 8

Resistor
One of the three basic passive components of an electric circuit that displays a voltage drop across its terminals and produces heat when an electric current passes through it. The electrical resistance, measured in ohms, is equal to the ratio of the voltage drop across the resistor terminals measured in volts divided by the current measured in amperes. See also Ohm's law.

Resistors are described by stating their total resistance in ohms along with their safe power-dissipating ability in watts. The tolerance and temperature coefficient of the resistance value may also be given. See also Electrical resistance; Electrical resistivity.

All resistors possess a finite shunt capacitance across their terminals, leading to a reduced impedance at high frequencies. Resistors also possess inductance, the magnitude of which depends greatly on the construction and is largest for wire-wound types. See also Capacitance; Electrical impedance; Inductance.

Resistors may be classified according to the general field of engineering in which they are used. Power resistors range in size from about 5 W to many kilowatts and may be cooled by air convection, air blast, or water. The smaller sizes, up to several hundred watts, are used in both the power and electronics fields of engineering.

Direct-current (dc) ammeters employ resistors as meter shunts to bypass the major portion of the current around the low-current elements. These high-accuracy, four-terminal resistors are commonly designed to provide a voltage drop of 50–100 mV when a stated current passes through the shunt. See also Ammeter.

Voltmeters of both the dc and the ac types employ scale-multiplying resistors designed for accuracy and stability. The arc-over voltage rating of these resistors is of importance in the case of high-voltage voltmeters. See also Voltmeter.

Standard resistors are used for calibration purposes in resistance measurements and are made to be as stable as possible, in value, with time, temperature, and other influences. Resistors with values from 1 ohm to 10 megohms are wound by using wire made from special alloys. The best performance is obtained from quaternary alloys, which contain four metals. The proportions are chosen to give a shallow parabolic variation of resistance with temperature, with a peak, and therefore the slowest rate of change, near room temperature. See also Electrical units and standards.

By far the greatest number of resistors manufactured are intended for use in the electronics field. The major application of these resistors is in transistor analog and digital circuits which operate at voltage levels between 0.1 and 200 V, currents between 1 ?A and 100 mA, and frequencies from dc to 100 MHz. Their power-dissipating ability is small, as is their physical size.

Since their exact value is rarely important, resistors are supplied in decade values (0.1, 1, 10, 100 ohms, and so forth) with the interval between these divided into a geometric series, thus having a constant percentage increase. For noncritical applications, values from a series with intervals of 20% (12 per decade) are appropriate. A series with 10% intervals (24 per decade) is often used for resistors having a tolerance of 1%. Where the precise value of a resistor is important, a series with 2.5% intervals (96 per decade) may be used.

Resistors are also classified according to their construction, which may be composition, film-type, wire-wound, or integrated circuit.

The composition resistor is in wide use because of its low cost, high reliability, and small size. Basically it is a mixture of resistive materials, usually carbon, and a suitable binder molded into a cylinder. Copper wire leads are attached to the ends of the cylinder, and the entire resistor is molded into a plastic or ceramic jacket. Composition resistors are commonly used in the range from several ohms to 10–20 M?, and are available with tolerances of 20, 10, or 5%.

The film-type resistor is now the preferred type for most electronic applications because its performance has surpassed that of composition resistors and mass-production techniques have reduced the cost to a comparable level. Basically this resistor consists of a thin conducting film of carbon, metal, or metal oxide deposited on a cylindrical ceramic or glass former. The resistance is controlled by cutting a helical groove through the conducting film. This helical groove increases the length and decreases the width of the conducting path, thereby determining its ohmic value. By controlling the conductivity, thickness of the film, and pitch of the helix, resistors over a wide range of values can be manufactured. Film construction is used for very high value resistors, up to and even beyond 1 T? (1012 ohms).

Wire remains the most stable form of resistance material available; therefore, all high-precision instruments rely upon wire-wound resistors. Wire also will tolerate operation at high temperatures, and so compact high-power resistors use this construction. Power resistors are available in resistance values from a fraction of an ohm to several hundred thousand ohms, at power ratings from one to several thousand watts, and at tolerances from 10 to 0.1%. The usual design of a power resistor is a helical winding of wire on a cylindrical ceramic former. After winding, the entire resistor is coated in vitreous enamel. Alternatively, the wound element may be fitted inside a ceramic or metal package, which will assist in heat dissipation. The helical winding results in the resistor having significant inductance, which may become objectionable at the higher audio frequencies and all radio frequencies. Precision wire-wound resistors are usually wound in several sections on ceramic or plastic bobbins and are available in the range from 0.1 ? to 10 M?.

Integrated circuit resistors must be capable of fabrication on a silicon integrated circuit chip along with transistors and capacitors. There are two major types: thin-film resistors and diffused resistors. Thin-film resistors are formed by vacuum deposition or sputtering of nichrome, tantalum, or Cermet (Cr-SiO). Such resistors are stable, and the resistance may be adjusted to close tolerances by trimming the film by using a laser. Typical resistor values lie in the range from 100 ? to 10 k? with a matching tolerance of ±0.2% and a temperature coefficient of resistance of ±10 to ±200 ppm/°C.

Diffused resistors are based upon the same fabrication geometry and techniques used to produce the active transistors on the silicon chip or die. A diffused base, emitter, or epitaxial layer may be formed as a bar with contacts at its extremities. The resistance of such a semiconductor resistor depends upon the impurity doping and the length and cross section of the resistor region. In the case of the base-diffused resistor, the emitter and collector regions may be formed so as to pinch the base region to a very small cross-sectional area, thereby appreciably increasing the resistance. The relatively large impurity carrier concentration in n- and p-type regions limits the resistance value. Resistor values between 100 ? and 10 k? are common. See also Integrated circuits.

The deposited-film and wire-wound resistors lend themselves to the design of adjustable resistors or rheostats and potentiometers. Adjustable-slider power resistors are constructed in the same manner as any wire-wound resistor on a cylindrical form except that when the vitreous outer coating is applied an uncovered strip is provided. The resistance wire is exposed along this strip, and a suitable slider contact can be used to adjust the overall resistance, or the slider can be used as the tap on a potentiometer. See also Potentiometer; Rheostat.

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