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POTENTIOMETER
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POTENTIOMETER , an See also:instrument for the measurement of electromotive force and also of difference of electric potential between two points. The See also:term potentiometer is usually applied to an instrument for the measurement of steady or continuous potential difference between two points in terms of the potential difference of the terminals of a See also:standard voltaic See also:cell of some See also:kind, such as a See also:Clark or See also:Weston cell. The See also:modern potentiometer has been See also:developed out of an arrangement due to J. C. See also:Poggendorff, employed also by J. See also:Latimer Clark, but converted into its modern See also:direct See also:reading See also:form by J. A. See also:Fleming in 1885 (see See also:Industries, 1886, i. 152). In principle the modern potentiometer consists of an arrangement by means of which any potential difference not exceeding a certain assigned value can be compared with that of a standard cell having a known electromotive force. In simplest form it consists of a See also:long, straight, See also:fine, See also:uniform See also:wire stretched over a divided See also:scale. The ends of this wire are connected to one or more secondary cells of See also:constant electromotive force, a variable resistance being interposed so as to regulate the current flowing through the fine wire. To one end of this fine wire is attached one terminal of a sensitive See also:galvanometer. Sliding contacts can be moved along the fine wire into any position. Supposing that the scale under this wire is divided into 2000 parts and that we are in See also:possession of a standard Clark cell, the electromotive force being known at various temperatures, and equal, say, to 1.434 volts at 15° C. The first See also:process is to set the potentiometer. The slider is placed so as to See also:touch the fine wire at See also:division No. 1434 on the fine wire, and the Clark cell is connected in between the sliding contact and one terminal of the galvanometer, so that its negative See also:pole is connected through the galvanometer with that end of the fine wire to which the negative pole of the working See also:battery is attached. The resistance in See also:circuit with the fine wire is then altered until the galvanometer shows no deflexion. We then know that the fall of potential down the 2000 divisions of the fine wire must be exactly 2 volts. If then we substitute for the standard cell any other source of electromotive force, we can move the slider into another position in which the galvanometer will show no deflection. The scale reading then indicates directly the electromotive force of this second source of potential. Thus, for instance, if an experiment were made with a Leclanche cell, and if the balancing-point were found to be at 1500 divisions on the scale, the electromotive force would be determined as 1.500 volts. Instead of adjusting in this manner the electromotive force of any form of cell, if we pass any constant current through a known resistance and bring wires from the extremities of that resistance into connexion with the slider and the galvanometer terminal, we can in the same way determine the fall of potential down the above resistance in terms of the electromotive force of the standard cell and thus measure the current flowing through the standard resistance. In the See also:practical form the potentiometer wire is partly replaced by a number of coils of wire, say 14 (see fig. 1), and the potentiometer wire itself has a resistance equal to one of these coils. One terminal of the galvanometer can then be shifted to the junction S between any pair of consecutive coils and the slider shifted to any point on the potentiometer wire. By such an arrangement the potential difference can be measured of any amount from o to 1.5 volts. In some cases the potentiometer wire is wholly replaced by a See also:series of coils divided into small subdivisions. We may employ such a potentiometer to measure large potential difference greater than the electromotive force of the working battery, as follows: The two points between which the potential difference is required are connected by high resistance, say of 100,000 ohms or more, and from the extremities of a known fraction of this resistance, say, I/Too or I/l000 or I/to,000 wires are brought to the potentiometer and connected in between the slider and the corresponding galvanometer terminal. We can thus measure as described the drop in volts down a known fraction of the whole high resistance and therefore calculate the fall in potential down the whole of the high resistance, which is the potential difference required. The potentiometer and the divided resistance constitute a sort of See also:electrical scaleyard by means of which any electromotive force or difference of potential can be compared with the electromotive force of a standard cell. Very convenient and practical forms of potentiometer have been devised by See also:Crompton (fig. 2), Nalder, Elliot Bros., Fleming a b, The scale wire. c, The set of equal potentiometer coils in series with it. d, The See also:double pole switch connecting the 6 pairs of terminals A B C D E F in See also:succession to the slide contacts.
e, The resistance coils.
f, The rheostat.
g, The galvanometer See also: In the same manner the potentiometer may be used to calibrate a See also:voltmeter by the aid of a divided resistance of known value. . In electrical measurements connected with incandescent electric lamps the potentiometer is of See also:great use, as it enables us to make accurately and nearly simultaneously two measurements, one of the current through the See also:lamp and the other of the potential difference of the terminals. For this purpose a resistance, say, of one ohm is placed in series with the lamp and a resistance of 100,000 ohms placed across the terminals of the lamp; the latter resistance is divided into two parts, one consisting of moo ohms and the other of 99,00p ohms. The potentiometer enables us to measure therefore the current through the lamp by measuring the drop in volts down a resistance in series with it and the potential difference of the terminals of the lamp by measuring the drop in volts down the tooth See also:part of the high resistance of too,000 ohms connected across the terminals of the lamp. Standard Cells.—A necessary See also:adjunct to the potentiometer is some form of standard cell to be used as a standard of electromotive force. In the See also:case of the Clark standard cell above mentioned the elements are See also:mercury and See also:zinc separated by a See also:paste of mercurous sulphate mixed with a saturated See also:solution of zinc sulphate. Other voltaic See also:standards of electromotive force are in use, such as the Weston See also:cadmium cell, the See also:Helmholtz See also:calomel cell, and the standard See also:Daniell cell. The Clark cell is made in two forms, the See also:board of See also:trade or tubular form, and the H form of cell devised by See also:Lord See also:Rayleigh. The See also:German experts seem to favour the latter form; the See also:specification issued by the Physikalisch-Technische Reichsanstalt of See also:Berlin may be found in the Electrician, xxxi. 265-266. The electromotive force of the cell diminishes with rise of temperature, the board of trade value being 1.434 volts at 15° C.1 and 1.434 (I -0.00077 (t—15)) volts at t° C. A more exact expression is obtained if instead of 0.00077 the quantity 0.00078+0.000017 (t—15) is used. In the Weston standard cell cadmium and cadmium sulphate are substituted for zinc and zinc sulphate; it has the See also:advantage of a much smaller coefficient of temperature variation than the Clark cell. It is most conveniently made up in a See also:glass See also:vessel of H form, pure mercury and cadmium See also:amalgam being the two elements (fig. 3), i According to K. Kahle and W. Wien, the electromotive force of the H form of Clark cell is 1.4322 volts at 15° C. Additional information and CommentsThere are no comments yet for this article.
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