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EKT112:Principles of Measurement and Instrumentation

Week 2 : Voltage & Current Measurement. EKT112:Principles of Measurement and Instrumentation. Introduction of electric circuit. The ultimate goal of the circuit theory is to predict currents and voltages in complex circuits (circuit analysis) and to design electrical

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EKT112:Principles of Measurement and Instrumentation

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  1. Week 2: Voltage & Current Measurement EKT112:Principles of Measurement and Instrumentation

  2. Introduction of electric circuit The ultimate goal of the circuit theory is to predict currents and voltages in complex circuits (circuit analysis) and to design electrical circuits with desired properties. The circuits are built with circuit elements. Some of these elements (voltmeters, ammeters, wires, resistors, capacitors, inductors, and switches) are described below.

  3. Voltmeters and Ammeters • Electrical currents can be measured with an ammeter. • To measure the current in the wire shown in Fig. 1a, the wire should be cut and the ammeter should be inserted. • The current will flow through the ammeter (Fig. 1b).

  4. Ammeters

  5. Ammeters • An ideal ammeter should have a negligible effect on the circuit. This means that the voltage difference between its two terminals (A and B) should be zero. • In other words,the internal resistance (impedance) of an ideal ammeter is zero.

  6. Voltmeter

  7. Voltmeter • To measure voltage, the two terminals of a voltmeter should be connected to two points in the circuit between which the potential difference is measured. An ideal voltmeter should not affect the circuit. • Therefore, current through the voltmeter (this is current in Fig.2) should be zero. • In other words, internal resistance (impedance) of an ideal voltmeter is infinity. A real voltmeter is never ideal and its impedance is finite.

  8. Kirchhoff laws • Kirchhoff laws are applicable to both the linear and not linear circuits. • They provide a universal tool for circuit analysis.

  9. Kirchhoff laws • Kirchhoff’s current law: • The sum of the currents entering a node is equal to the sum of currents leaving the node. • A node is a point where two or more wires are interconnected.

  10. Kirchhoff laws • Kirchhoff’s voltage law: • An algebraic sum of voltages across all elements along any closed path is zero. • Algebraic sum means that we should take + sign if the voltage rises after a circuit element and “–“ sign if the voltage drops after a circuit element.

  11. Kirchhoff laws (cont…) Analysis of a circuit. General rules: 1. Identify every loop which does not contain another loop (such a loop is called mesh). Assign a current for every loop. The current direction can be chosen arbitrary. This step ensures that the Kirchhoff’s current law is automatically satisfied. 2. Use Ohm’s law (or other relations between voltages and currents if the circuit includes capacitors, inductors, diodes, etc) to calculate the voltage across all elements along every mesh and write equations (for every mesh) usingKirchhoff’s voltage law. Important! If two currents flow through an element, the currents should be added like vectors (their directions are important!). 3. Solve the equations.

  12. Example

  13. Example 2

  14. Example 2

  15. PART 2

  16. EKT112Principles of Measurement and InstrumentationWeeks 2-3

  17. Current, Voltage & Resistance Measurement

  18. Topics Outline 1.0 Device for Current Measurement 1.1 Analog ammeter 1.2 Galvanometer 2.0 Device for Voltage Measurement 2.1 Analog voltmeter 2.2 Oscilloscope 2.3 Potentiometer 3.0 Device for Resistance Measurement 3.1 Ohmmeter 3.2 Wheatstone bridge circuit 4.0 Digital Multimeter

  19. Objective As introduction to the student into some basic measurement device for current, voltage & resistance.

  20. 1.0 Current Measurement

  21. Basic analog measurement of current –uses inductive force on the current carrying conductor in magnetic field. • This force can be used to measure the needle deflection on a display. • Direct Current (DC) • Charges flow in one direction • commonly found in many low-voltage applications, especially where these are powered by batteries • Alternating Current (AC) • Flow of electric charge changes direction regularly • Example: audio & radio signal • Home & school use AC

  22. The D’Arsonval Meter Movement • The basic moving coil system generally referred to as a d’Arsonval meter movement or Permanent Magnet Coil (PMMC) meter movement. • Current-sensitive device capable of directly measuring only very small currents. • Its usefulness as a measuring device is greatly increased with the proper external circuitry. Fig 1-1 The d’Arsonval meter movement

  23. Current from a circuit in which measurements are being made with the meter passes through the windings of the moving coil. Current through the coil causes it to behave as an electromagnet with its own north and south poles. The poles of the electromagnet interact with the poles of the permanent magnet, causing the coil to rotate. The pointer deflects up scale whenever current flows in the proper direction in the coil. For this reason, all dc meter movements show polarity markings.

  24. 1.1 Ammeter • An ammeter is an instrument for measuring the electric current in amperes in a branch of an electric circuit. • It must be placed in series with the measured branch, and must have very low resistance to avoid significant alteration of the current it is to measure. • connecting an ammeter in parallel can damage the meter

  25. Ammeter – Principle of Operation • The earliest design is the D'Arsonvalgalvanometer or moving coil ammeter (respond to ac only) • It uses magnetic deflection, where current passing through a coil causes the coil to move in a magnetic field • The voltage drop across the coil is kept to a minimum to minimize resistance across the ammeter in any circuit into which the it is inserted. • Moving iron ammeters use a piece or pieces of iron which move when acted upon by the electromagnetic force of a fixed coil of (usually heavy gauge) wire (which respond to both dc & ac)

  26. Ammeter Design

  27. An ammeter is placed in series with a circuit element to measure the electric current flow through it. • The meter must be designed offer very little resistance to the current so that it does not appreciably change the circuit it is measuring. • To accomplish this, a small resistor is placed in parallel with the galvanometer to shunt most of the current around the galvanometer. • Its value is chosen so that when the design current flows through the meter it will deflect to its full-scale reading. • A galvanometer full-scale current is very small: on the order of milliamperes.

  28. Basic DC Ammeter Circuit Ammeter In most circuits, Ish >> Im Where Rsh = resistance of the shunt Rm = internal resistance of the meter movement (resistance of the moving coil) Ish = current through the shunt Im = full-scale deflection current of the meter movement I = full-scale deflection current for the ammeter Fig. 1-2 D’Ársonval meter movement used in ammeter circuit

  29. The voltage drop across the meter movement is • The shunt resistor is parallel with the meter movement, thus the voltage drop for both is equal • Then the current through the shunt is, • By using Ohm’s law

  30. Cont. Then we can get shunt resistor as Ohm Example 1-1 Calculate the value of the shunt resistance required to convert a 1-mA meter movement, with a 100-ohm internal resistance, into a 0- to 10-mA ammeter.

  31. Solution:

  32. The Ayrton Shunt • The purpose of designing the shunt circuit is to allow to measure current I that is some number n times larger than Im. • The number n is called a multiplying factor and relates total current and meter current as • We can get shunt resistance with n times larger than Im is I =nIm ………1.1 ………1.3

  33. Examples 1-2 • A 100 µA meter movement with an internal resistance of 800 Ω is used in a 0- to 100 mA ammeter. Find the value of the required shunt resistance. Answ: ~ 0.80 ohm

  34. Advantages of the Ayrton: • Eliminates the possibility of the meter movement being in the circuit without any shunt resistance. • May be used with a wide range of meter movements. Fig 1-3 Ayrton shunt circuit

  35. Cont. • The individual resistance values of the shunts are calculated by starting with the most sensitive range and working toward the least sensitive range • The shunt resistance is • On this range the shunt resistance is equal to Rsh and can be computed by Eqn

  36. Cont.

  37. Ammeter insertion effects • Inserting an ammeter in a circuit always increases the resistance of the circuit and reduces the current in the circuit. This errorcaused by the meter depends on the relationship between the value of resistance in the original circuit and the value of resistance in the ammeter.

  38. Cont. ** For high range ammeter, the internal resistance in the ammeter is low. ** For low range ammeter, the internal resistance in the ammeter is high.

  39. Fig. 2-3: Expected current value in a series circuit Fig 2-4: Series circuit with ammeter

  40. Cont. hence; Therefore Insertion error =

  41. Example 1-3 A current meter that has an internal resistance of 78 ohms is used to measure the current through resistor Rc in Fig. 2.5. Determine the percentage of error of the reading due to ammeter insertion. Fig. 2.5

  42. Solution: The current meter will be connected into the circuit between points X and Y in the schematic in Fig. 2.6. When we look back into the circuit from terminals X and Y, we can express Thevenin’s equivalent resistance as RTH = 1 k + 0.5 k = 1.5 k Fig. 2-6

  43. Cont. Therefore, the ratio of meter current to expected current: Im/Ie= 1.5 k/(1.5 k + 78) = 0.95 Solving for Im yields, Im = 0.95Ie Insertion error = [1 – (Im/Ie)] x 100% = 5.0%

  44. 1.2 Galvanometer • It is an electromechanical transducer that produces a rotary deflection, through a limited arc, in response to electric current flowing through its coil. • Galvanometer has been applied to devices used in measuring, recording, and positioning equipment.

  45. Galvanometer – Principle of Operation • Such devices are constructed with a small pivoting coil of wire in the field of a permanent magnet. The coil is attached to a thin pointer that traverses a calibrated scale. A tiny spring pulls the coil and pointer to the zero position. • In some meters, the magnetic field acts on a small piece of iron to perform the same effect as a spring. When a direct current (DC) flows through the coil, the coil generates a magnetic field. • This field acts with or against the permanent magnet. The coil pivots, pushing against the spring, and moving the pointer. The hand points at a scale indicating the electric current. • A useful meter generally contains some provision for damping the mechanical resonance of the moving coil and pointer so that the pointer position smoothly tracks the current without excess vibration.

  46. Galvanometer – Application • Are used to position the pens of analog chart (example: electrocardiogram)

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