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Transcript
LAB 6 ELECTRICAL CIRCUITS May 1, 2017 Lab 6 Set-up and Figure 1 1 LAB 6 ELECTRICAL CIRCUITS May 1, 2017 OVERVIEW: Electrical energy is useful when changed to heat, light, or mechanical energy. An electrical circuit is required to convert electrical energy to a useful form. An electrical circuit has four essential parts: a power source, a control element, conductors and a load. See figure A. The power source supplies electrical energy to the circuit. The control element is a switch, a dimmer or a variable speed control for the circuit. The conductor provides the path for the current flow through the circuit. The load converts electrical energy to a useful form. A series circuit contains only one conductive path for the current. See figure B. As the current travels around the circuit, the voltage drops across each load when converting the electrical energy to other energy forms. The total voltage across the circuit must equal the sum of the voltages used up in each load. This can be expressed by the following equation: ššššššš = V1 + V2 + V3 A parallel circuit contains two or more current paths. See figure C. The current in a parallel circuit divides, and each path conducts only a portion of the total current. The sum of these currents equals the total current leaving the battery or voltage source. In a parallel circuit, the voltage across each load is the same as the voltage read directly across the battery or voltage source. š°š»šššš = š°š + š°š + š°š ššššššš = šš = šš = šš In this experiment you will construct a series and a parallel circuit, using light bulbs as the load. The voltage is measured "across the load", which means that the meter must be connected in parallel with the load. This means that the voltmeter is connected with the + probe on the side of the bulb closest to the positive (+) terminal of the battery, and the (-) probe on the other side of the bulb. Notice that the meter is measuring potential difference (voltage), not current (amperage). 2 LAB 6 ELECTRICAL CIRCUITS May 1, 2017 OBJECTIVES: A) Construct a series and parallel circuit from a schematic diagram. B) Draw a schematic diagram of a series and a parallel circuit. C) Measure the voltage drops around a series and parallel circuit. EQUIPMENT REQUIRED: Circuit Panel Universal Lead Set Two Lamps on Mounted Base Hook-Up-Wire & Strippers Circuit Panel Easel SPST Knife Switch 6V Battery Digital Multi-meter (DMM) Lab Equipment Discussion: The Circuit Panel has 150 bronze conducting islands. Each island has five holes in it, into which stripped wire or test leads with spring tips may be inserted. All wires plugged into the same island are electrically connected. See Figure 5. Many of the components needed for your experiments are mounted on boards that fit into your Circuit Panel. To mount these components to the Circuit Panel, position the component so that each mounting pin is inserted into a separate island. Figure 6 shows the correct placement of the SPST (single-throw single-pole) Knife Switch on the Circuit Panel. You use segments of hook-up wire to connect components together on your Circuit Panel. Cut wire to the necessary length, and strip approximately 3/4" of insulation off of each end. This will allow proper insertion into the island holes. See Figure 7. 3 LAB 6 ELECTRICAL CIRCUITS May 1, 2017 PROCEDURE: The basic setup for this experiment is shown in Figure 1. A) VOLTAGE DISTRIBUTION IN A SERIES CIRCUIT 1. Construct a two load series circuit, as pictured in Figure 8. 2. Close the knife switch. The bulbs should light. If they do not, recheck your wiring and all connections. 3. You are going to measure the voltage across each lamp, and the voltage of the power source. Figure 9 shows the polarity of each load and the voltmeter connections for measuring the voltage across lamp #1. 4. Set the voltmeter to measure DC voltage on the 20V range. Touch the multimeter probes to the power supply leads where they connect to the Circuit Panel. Be sure to observe the proper polarity. Read the voltage as displayed on the multimeter, and record the value as the source voltage (V3) in Data Table 1. 5. Measure the voltage across each lamp in the circuit. Be sure to observe the proper polarity of each load when connecting the multimeter probes. Record your measurements as V1 and V2 in Data Table 1. Note the brightness of each lamp. 6. Draw a schematic diagram of your series circuit in the space provided. Indicate the polarity of the battery with + and B) VOLTAGE DISTRIBUTION IN PARALLEL CIRCUITS 1. Construct a two load parallel circuit, using the schematic diagram of Figure 10. 2. Close the switch and check the circuit for proper operation. 3. Observe whether the bulbs appear to be brighter, dimmer, or the same brightness compared to the series circuit of Part A. Complete this comparison by filling in the remarks between Tables I and II, 4. Measure the voltage of the source (Vš ), and the voltage of each lamp (V1 and V2 ).. Record the readings in Data Table 2. 5. Draw a schematic diagram of your parallel circuit in the space provided. Indicate the polarity of the battery. 6. Take the circuit apart. Turn the DMM off before storing. ANALYSIS: Discuss the questions on the back of the lab form with your partners, filling in the answers that you agree upon. If you cannot agree on a question, ask for help from the instructor. 4 LAB 6 ELECTRICAL CIRCUITS OBJECTIVES: May 1, 2017 SKETCH OF LAB SET-UP: DATA TABLE 1: SERIES CIRCUIT Power Supply Voltage: Vs = Lamp #1 Voltage: V1 = Lamp #2 Voltage: V2 = SCHEMATIC DIAGRAM OF SERIES CIRCUIT LAMP BRIGHTNESS: OBSERVATIONS DATA TABLE 2: PARALLEL CIRCUIT Power Supply Voltage: Vs = Lamp #1 Voltage: V1 = Lamp #2 Voltage: V2 = SCHEMATIC DIAGRAM OF PARALLEL CIRCUIT 5 LAB 6 ELECTRICAL CIRCUITS May 1, 2017 Lab #6 ANALYSIS: 1. Using the voltage measurements from Data Table 1, verify that, for a series circuit that Vs = V1 + V2. 2. Explain why the sum of the lamp voltages from question 1 might not equal the source voltage. ___________________________________________________________________________ 3. Using the measurements from Table 2, verify that Vs = V1 = V2 4. In which circuit did the bulbs have the highest voltage? ______________________________________________________________________________ 5. Explain why a difference in bulb brightness occurs for the two types of circuit. ______________________________________________________________________________ 6. In the space below, draw a schematic diagram for a four load series circuit. Use lamps as the loads, a battery for the source, and include an ON/OFF switch. 7. In the space below, show a schematic diagram a three load parallel circuit. Use two batteries in series for the source and lamps as the loads. Include three switches in the circuit, each one controlling a separate lamp. 6
