School Science Lessons
33. Cells and batteries, house circuits, instruments, lead cell accumulator,
electric power and energy, thermoelectricity
2012-05-04b SP
Please send comments to: J.Elfick@uq.edu.au
Table of contents
33.3.0 Cells and batteries
33.6.0 Circuit analysis, house circuits
33.4.0 Incandescent, filament lamp, light bulb
33.7.0 Instruments to detect electric current
33.2.0 Lead cell accumulator, car battery
33.5.0 Electric power and electrical energy
33.8.0 Thermoelectricity, thermocouple
33.3.0 Cells and batteries
33.3.0 Cells and batteries, electrochemical cells
33.4.3 Battery, Bring a dead battery to life
32.4.6.5 Battery, source of EMF
15.6.15 Calomel half cell
33.3.6 Chocolate wrapper cell in the mouth
33.6.0 Circuit analysis, house circuits
33.3.3 Coin cells
33.3.12 Contact potential difference
33.6.1 Continuity of current
33.3.13 Crowsfoot or gravity cell
33.4.0 Dry cell capacity
33.4.1 Dry cell in an electric circuit
33.4.4 Dry cell terminals
33.4.2 Dry cell torch battery
4.66 Electric
current detector
4.53 Electric
torch (flashlight) battery, Leclanche cell
4.52 Electricity
from a lemon, lemon cell
4.51 Electricity
from two coins
3.84 Electrical energy from chemical
reactions
15.6.0 Electrochemical cells (Chemistry)
7.9.21 Electrochemical cell
15.7.0 Electrode potential of metals
33.3.11 EMF dependence on electrode material
32.4.6.6 Electromotive force, EMF,
measure EMF of cells
32.4.6.6.1 EMF and internal resistance
of a cell with an ammeter and a voltmeter
32.4.6.6.2 EMF of two cells with
a potentiometer
3.84.4 Galvanic cell, zinc in hydrochloric
acid
33.3.8 Hydrogen / oxygen fuel cell
33.3.10 Ionic friction
33.3.9 Ionic migration
33.2.0 Lead accumulator cell, car battery
4.52.1 Lemon-powered clock
33.3.4 Lemon cell
15.6.13 Magnesium / copper battery
15.6.14 Nickel / cadmium battery, NiCad battery
33.3.7 Noisy potato cell
15.7.1 Potential difference by combining
half cells, zinc and iron, (Chemistry)
32.4.6.8 Power wasted inside a battery
33.3.5 Simple chemical rectifier
33.3.7 Potato cell, noisy potato cell
33.3.5 Simple chemical rectifier
33.3.1 Simple electric cell
33.3.1 Simple electric cell
33.3.2 Voltaic cell (Galvanic cell), Daniell cell,
salt bridge
33.6.0 Circuit analysis,
house circuits
33.6.0 Circuit analysis, house circuits
33.6.8 a.c. Chopstick fan
33.6.1 Continuity of current
33.6.9 Electrical circuits in a room
33.6.7 Equivalent resistance, series and parallel
33.6.6 Light bulb board, 12 V
33.6.2 Superposition of currents
33.6.3 Standard reciprocity circuit with a potentiometer
33.6.4 Wheatstone bridge, bridge circuits, slide
wire, metre wire bridge
33.6.5 Wheatstone bridge with a human galvanometer,
Wheatstone bridge with light bulbs
33.4.0 Incandescent, filament
lamp, light bulb
4.117 Absorption spectrum
7.2.2.3 Ar, Argon properties
3.1.4 Bunsen burner flame and candle flame
13.3.3 Burn steel wool in oxygen, burn
iron filings
8.1.1 1 Candle flame, Parts of a candle
flame (See 2.)
33.5.12 Compare light from incandescent lamps
33.5.11 Compare power of incandescent torch globes
4.65 Electric light bulb (incandescent
filament lamp)
4.116 Incandescent lamp
32.5.8.1 Sources of light, candlepower
(Motor vehicles)
32.3.2.4 Temperature of incandescent
lamps with silicon solar cells
7.2.2.45 Tungsten, W, tungsten wire,
properties
33.7.0 Instruments to detect electric current
33.7.0 Instruments to detect electric current
33.7.3 Ammeter
33.7.1 Current detector
33.7.2.0 Galvanometer
33.7.2.2 Convert a galvanometer to a voltmeter
33.7.2.3 Convert a galvanometer to an ammeter
33.7.2.4 Convert a galvanometer to an hot wire
current meter
33.7.2.5 Reduction factor k of a tangent galvanometer
33.7.2.1 Sensitivity and resistance of a galvanometer
33.7.4 Voltmeter
33.7.4.2 Voltmeter as cell counter
33.7.4.3 Calibrate a voltmeter
33.7.4.1 Connect a voltmeter
33.7.4.5 Loading by a voltmeter
33.7.4.4 Potential difference and electromotive
force
33.2.0 Lead accumulator cell, car battery
33.2.4 Internal resistance of batteries, weak
and good battery
33.2.2 Lead acid simple battery
33.2.1 Lead accumulator cell
3.87 Lead accumulator cell, lead-acid
rechargeable battery (Chemistry)
33.2.3 Melt nail with a storage battery, lead-salt
cell
33.5.0 Electric power and
electrical energy, electrical equivalent of heat
33.5.0 Electric power and electrical energy, electrical equivalent
of heat
3.84 Electrical energy from chemical
reactions
33.5.12 Compare light from incandescent lamps
33.5.11 Compare power of incandescent torch globes
33.5.10 Current through a torch globe
33.5.01 Heat from current through a conductor
is proportional to: 1. time, and 2. current2
33.5.2 Heat from electrical energy
33.5.8 Heat wires in series
33.5.9 Hot dog / pickle cooker
33.5.7 kWh meter and loads, heating with current
33.5.1 Light from electrical energy
33.5.3 Electric heater using steel wool
33.5.5 Electric jug, immersion heater
33.5.4 Electric light and switch
33.5.13 Light from a lamp, exposure meter
33.5.6 Voltage and current to a heating coil in
a calorimeter
33.8.0 Thermoelectricity,
thermocouple
Order online: Thermoelectric Demonstrator
Order online: Thermoelectric Peltier
Device
33.8.3 Copper-iron junctions ring
33.8.11 Pyroelectric crystals, domains of electric
polarization
33.8.2 Seebeck effect and Peltier effects
33.8.1 Thermocouple, Seebeck effect, thermoelectric
effect
33.8.5 Thermocouple coil magnet
33.8.9 Thermocouple magnet
33.8.4 Thermoelectric compass
33.8.6 Thermoelectric effect in a wire
33.8.10 Thermoelectric heat pump
33.8.8 Thermoelectric magnet
33.8.7 Thompson effect
15.6.13 Magnesium / copper battery
Connect the external circuit before adding the sodium sulfate solution.
Clean copper in dilute nitric acid and clean magnesium ribbon in 1 M hydrochloric
acid.
Half cells: 1. Magnesium ribbon in contact with 0.5 M sodium sulfate
solution, in a jar.
2. Copper strip in contact with 0.5 M copper (II) sulfate solution,
in a dialysis tubing bag, then in the same jar
1. Mg (s) --> Mg2+ (aq) + 2e- (Eo 2.36
V at 25oC, 1 atmosphere pressure)
2. 1/2 H2 --> H+ + 2e- (Eo
= 0)
3. Cu (s) --> Cu2+ (aq) + 2e- (Eo
= -0.337 V)
4. Mg (s) + Cu2+ (aq) --> Mg2+ (aq) + Cu (s)
EMF = Eo (oxidation) - Eo (reduction) so EMF =
2.36 - (-0.337) = 2.7 V
At the anode: Oxygen is liberated: 4OH- --> O2
+ 2H2O + 4e-
At the cathode: Hydrogen ions are not reduced to H2 because
the Eo of reaction 2., where Eo = 0 V, is greater
than the Eo of reaction 3. (where Eo = -0.337 V.)
15.6.14 Nickel / cadmium
battery, NiCad battery
Rechargeable battery used to power various small devices, e.g. electric
toothbrush. During discharge:
At the cathode: nickel (IV) hydroxide + 2 electrons --> nickel (II)
hydroxide (reduction)
At the anode: cadmium - 2 electrons --> cadmium (II) hydroxide (oxidation)
Some people think that this kind of battery shows a "memory effect",
i.e. after recharging, the battery later runs down only to the capacity
at which last recharged. The solution is to let the battery discharge almost
completely before recharging. Constant recharging after use for a short
time may produce overcharging and change the form of cadmium crystals in
the battery resulting in slower release of electric current and apparent
lower voltage.
15.6.15 Calomel half cell
See: Calomel, mercury (I)
chloride, horn quicksilver, Hg2Cl2
A reference electrode consisting of a half cell with a mercury electrode
in a solution of potassium chloride saturated with calomel, mercury (I)
chloride, Hg2Cl2 or HgCl. Standard electrode potential
= -0.2415 V at 25oC.
HgCl (s) <--> Hg+ (aq) + Cl- (aq)
Hg+ (aq) + electron <--> Hg (s)
HgCl (s) + electron <--> Hg (s) + Cl- (aq)
33.2.1 Lead accumulator cell
The Lead cell accumulator has emf about 2 volts and very low internal
resistance. It is a secondary cell. The terminals are usually marked +
(red) and - (black). Since the internal resistance is very low, great care
must be taken to avoid "short circuiting " the cell, i.e. there must always
be a resistance of at least 1 ohm in the external circuit connecting the
terminals.
Use a 250 mL beaker or jar with a cover to prevent drying by evaporation
when the cell is not in use. You need 2 sheets of 40 × 10 cm thin
lead foil and 2 lead strips 2 × 14 cm as terminals. These lead pieces
require thorough cleaning by means of wire wool. Fold the long sheets of
lead tightly to the shorter strips so that they make good electrical contact.
The projecting ends will serve as terminals. A blotting paper B lead c terminals
A sandwich is made of alternating strips of lead foil and blotting paper.
When the sandwich is ready it is rolled up quite tightly, secured round the
outside with one or two elastic bands, and placed with terminals at the
top, in the cup or jar. Mark one terminal positive, and the other negative.
The roll is covered with a solution of sodium sulfate made by dissolving 40
g of anhydrous sodium sulfate crystals in 200 mL water. The cell is now ready
to charge with electricity. This can be done with a 6 volt battery charger,
or with any low voltage direct current supply giving up to 10 amps. Connect
positive on the charger to positive on the cell. After only a few minutes
charging, the cell will light a 1.5 volt bulb. Provided that the cell is always
connected to the charger in the same way, as described above, the more times
it is charged and discharged, the more efficient it becomes. There will be
enough current to make a small 1 volt electric motor spin round. The cell
will remain serviceable for several months if the cover is put on when not
in use.
33.2.2 Lead acid simple battery
Charge a simple lead acid battery with two electrodes, lead plates, in
a sulfuric acid solution for a short time and then discharge through a doorbell.
Charge two lead plates in 30% sulfuric acid and discharge through a flashlight
bulb.
33.2.3 Melt nail with a storage
battery, lead-salt cell
Instead of acid use a saturated salt solution of sodium bicarbonate
and magnesium sulfate.
33.2.4 Internal resistance
of batteries, weak and good battery
Measure similar no load voltage on identical looking batteries and then
apply a load to each and show the difference in voltage between a good and
weak battery.
33.3.0 Cells and batteries,
electrochemical cells
A battery supplies direct current from two or more connected electrolytic
cells. The term "battery" refers to several joined electrical cells, but
one dry cell is commonly called a "battery", e.g. a torch battery, flashlight
battery. A dry cell has the electrolyte in paste form that should not leak
out of the battery. A primary battery is disposable, i.e. it can be discharged
only once. A secondary battery is rechargeable, it can be discharged and later
recharged, so it can be used many times, e.g. the lead cell accumulator
used in motor vehicles. Primary batteries and secondary batteries that no
longer function should be disposed of according to the local environmental
regulations on disposal of batteries in the garbage system.
Dry cell "batteries" include the following:
1. Alkaline batteries (1.5 V) in cassette players and portable radios
2. Nickel-metal hydride batteries, discharge at 30% per month, also ready
to use low self-discharge batteries
3. Nickel-cadmium batteries (1.4 V) that are rechargeable and can produce
a high current
4. Silver oxide cells (1.5 V) in calculators, cameras and watches
5. Lithium ion batteries, replaced the lithium cadmium batteries, Li+
move from -ve electrode to +ve electrode when discharging, in consumer electronics
6. Zinc-carbon batteries (1.5 V), low cost but short life
Anode and cathode
In both voltaic cells (electrochemical cells) and electrolytic cells
(electrolysis), cations (positive ions) move towards the cathode and anions
(negative ions) move towards the anode. In both cells, electrons carry current
through the external circuit and ions carry current through the solutions.
An electrolytic cell uses electrons supplied by an external source. The anode
is the positive electrode of an electrolytic cell through which electrons
leave and conventional current enters. The cathode is the negative electrode
of an electrolytic cell through which electrons enter and conventional current
leaves. In a voltaic cell (electrochemical cell) the reaction occurs spontaneously.
The anode becomes positive attracting electrons from the external circuit.
Electrochemical cells (voltaic cell, galvanic cell) are the devices
to exchange chemical energy into electricity. The current formed by a chemical
cell is from chemical reactions inside the cell. A primary cell is a voltaic
cell in which the chemical reaction that produces the emf cannot be reversed
properly so the cell cannot be recharged by electrical means, e.g. voltaic
cell (galvanic cell), Daniell cell, Leclanche cell, Weston cell (cadmium
cell), mercury cell (HgO cathode). These cells are light, small and easy
to replace. A secondary cell, accumulator, is a voltaic cell that can be
recharged after discharged. However, they are large and heavy and contain
a lot of dangerous liquid electrolyte, e.g. lead cell accumulator (car battery,
storage battery), nickel iron accumulator (Edison cell, NIFE cell), Ni-Cd
storage batteries with potassium hydroxide electrolyte can be loaded again
up to 1000 times. In a circuit where ions conduct electricity, the positive
and negative ions move at the same time as an ion electric current to positive
or negative poles acted on by the electric field force.
In USA, battery labels must include the battery chemistry, the " three
chasing arrows" and an instruction that the user must recycle or dispose of
the battery properly.
33.3.1 Simple electric cell
See diagram 33.3.1: Simple electric cell
1. Copper and zinc in dilute sulfuric acid produce electricity. Put
a piece of zinc metal and a piece of copper metal into a large beaker 3
/ 4 full of dilute sulfuric acid. Connect a galvanometer between the zinc
metal and the copper metal. Observe the deflection of the galvanometer
needle, many hydrogen gas bubbles on the copper surface, but few bubbles
on the zinc surface. Zinc atoms transfer their electrons to the copper so
zinc atoms become zinc ions into the solution. The copper transfers the electrons
to hydrogen ions to form hydrogen gas by the contact surface of the copper
with sulfuric acid. The copper acts as catalyst.
2. Use a beaker containing dilute (5%) sulfuric
acid, copper and zinc electrodes and a galvanometer to show current flow.
Note which electrode the bubbles gather on and how this affects the reading
on the galvanometer? Stir the liquid so as to dislodge the bubbles and
read the galvanometer again.
3. Put some strong aqueous copper (II) sulfate solution
in a beaker. Connect copper foil to the positive terminal of a voltmeter and
a zinc rod or foil to the other terminal. Dip the two metals briefly into
the copper (II) sulfate solution. Note the readings on the voltmeter. The
voltage falls to zero after a short time because copper deposited on the
zinc and caused the reaction to stop. Note what happens at the copper rod
and at the zinc rod. Determine the direction of electron flow.
4. Pour concentrated copper (II) sulfate solution
into a beaker. Insert a sheet copper and sheet zinc into the solution.
Measure the voltage drop by connecting the copper to the +ve terminal of
a voltmeter and the zinc to the -ve terminal. Record the reading. Observe
that the sheet zinc dissolves and hydrogen gas bubbles form on the surface
of the copper. Observe that the voltage will decrease to zero with increasing
of the copper on the sheet zinc.
5. Repeat the experiment with magnesium ribbon,
an iron nail or lead foil instead of the zinc. Record the voltage each
time. The larger the difference in activity between two metals, the larger
the voltage. When copper deposits on the zinc electrode, it prevents more
zinc from entering the solution. This causes the voltage fall to zero after
a short time and the cell becomes "dead". You can add some subsidiary devices
to prevent this happening.
6. Use a beaker containing dilute sulfuric acid;
pieces of copper and zinc as electrodes; a switch; conducting wire and
a galvanometer to show current flow. Note on which electrode the bubbles
gather. Note the effect of their formation on the galvanometer. Stir the
liquid to dislodge the bubbles and note what happens. Instead of zinc and
copper strips use two zinc strips and, later, two copper strips. Note any
current flow in either case.
33.3.2 Voltaic cell (Galvanic
cell), Daniell cell, salt bridge
See diagram 33.3.2: Voltaic cells
1. The Daniell cell has emf about 1.1 volts, and low internal resistance.
It is a primary cell whose emf is constant for a considerable period of
time and maintains a steady, small current. However, since the copper (II)
sulfate solution slowly diffuses through the clay porous pot to attack the
zinc rod, the cell must be emptied and washed after use. The Daniell cell
uses a battery jar, clay porous pot, zinc electrode cylinder, copper electrode
rod, 10% copper (II) sulfate solution, 10% zinc sulfate solution.
Put sheet zinc in a beaker containing zinc sulfate solution or dilute
sulfuric acid solution and put a sheet copper in a beaker containing saturated
copper (II) sulfate solution. Connect the copper to the positive terminal
of a voltmeter and the zinc to the negative terminal of the voltmeter.
Observe the voltmeter reading is zero. Make a simple salt bridge by soaking
filter paper in a concentrated solution of an electrolyte, e.g. sodium chloride
or potassium nitrate. Fix the filter paper to dip into the zinc sulfate
and copper (II) sulfate solutions. Observe the voltmeter and record the reading.
The voltmeter shows that current is flowing. Read the voltmeter. Disconnect
the voltmeter and substitute a 1.5 volt bulb, ammeter, and conducting wire.
Record the observations. Examine the electrodes after two minutes. Observe
that the zinc corrodes and new copper has deposited on the copper electrode.
Observe whether the copper (II) sulfate solution loses some of its blue
colour. To prolong the life of the salt bridge, make a permanent salt bridge
from a glass U-tube filled with a 1 M aqueous potassium nitrate solution.
You can mix the solution with agar gel to keep it in the U-tube. Put cotton
wool plugs at each end of the U-tube.
2. Pour concentrated copper (II) sulfate solution
into a clay porous pot in a large beaker. The solutions should be at the
same level. Bend a sheet copper into a cylinder shape and put it in the
beaker to surround the porous pot. Put sheet zinc into the porous pot. Connect
the copper to the positive terminal of a voltmeter. Connect the zinc to
the negative terminal of the voltmeter. Record the reading and observe whether
there are changes in colour of the sheet copper, the sheet zinc and the
solution. Disconnect the voltmeter and substitute: 1.5 volt bulb, ammeter;
conduction wire.
3. Introduce a porous pot to prevent copper deposited
on the zinc. The Daniell cell uses a porous pot and a salt bridge. Put
0.5 M aqueous zinc sulfate in the porous pot. Put a strong solution of aqueous
copper (II) sulfate in the beaker surrounding the porous pot and fill to
the same level as that of the zinc sulfate solution. Make a cylinder shape
with copper foil and place it in the beaker to surround the porous pot.
Connect the copper to the positive terminal of a voltmeter. Connect a zinc
rod to the negative terminal and lower the zinc rod into the zinc sulfate
solution. Note the reading on the voltmeter. Insert a 1.5 volt bulb in place
of the voltmeter. Note whether it glows. Insert an ammeter into the circuit
to measure the current flowing. Try to vary the current by moving the copper
nearer to the zinc, or by changing the surface area of the copper foil.
4. If a porous pot is not available, use a salt
bridge between the two solutions. Make a salt bridge by filling a glass
U-tube with 1 M aqueous potassium nitrate solution and agar gel. Note the
voltage, the current and whether the light bulb glows.
5. Make a voltaic cell with copper and zinc electrodes
in a sulfuric acid solution. Short a few voltaic cells in series through
a loop of iron or nichrome wire.
Use a cardboard model voltaic cell circuit to illustrate potential difference
and electromotive force in a voltaic cell circuit.
To show voltaic cell polarization, heat the copper cathode in a Bunsen
burner flame to oxidize the surface.
33.3.3 Coin cells
1. Take two coins made of different metals. Clean them well with steel
wool or fine sand paper. Fold some paper into a pad so that it is larger than
the coins. Soak the paper in salt water. Place one coin on top of the pad
and the other underneath. Hold them between your thumb and finger. Connect
both leads of a sensitive galvanometer or multimeter to the coins and note
the deflection.
2. Soak absorbent cotton in salt water. Obtain
two coins made of different metals. Place the cotton between the coins.
The thickness of the cotton should be more than 2 mm. Connect both leads
of a sensitive galvanometer to the coins at the same time. Observe the current
flowing at the galvanometer. Clean the coins with steel wool or fine sandpaper
beforehand and make sure that no salt water remains on the leads.
3. Put aluminium foil with a copper coin on it
in water for a day. The water appears cloudy and the aluminium foil is
perforated where the coin was lying on it. The water becomes cloudy due
to dissolved aluminium.
4. Make a pile of copper coins alternating with
pieces of sheet zinc. Between each pair of metals insert newspaper soaked
in sodium chloride solution. Wind thin, insulated copper wire 50 times
around a plotting compass. Press each end of the wire against each end of
the pile. A current causes a deflection of the compass needle.
5. Make a simple cell with two coins. Use two coins
made of different metals. Clean them well with steel wool or fine sand
paper. Fold some paper hand towel or absorbent paper into a pad so that
it is larger than the coins. Soak the absorbent paper in salt water. Put
one coin on top of the pad and the other underneath. Hold them between the
thumb and finger. Connect both leads of a sensitive galvanometer to the coins
and watch the deflection.
6. Use two coins made of different metals. Clean
them well with steel wool or fine sand paper. Fold some paper into a pad
so that it is larger than the coins. Soak the paper in salt water. Place
one coin on top of the pad and the other underneath. Hold them between your
thumb and finger. Connect both leads of a sensitive galvanometer or multimeter
to the coins and note the deflection.
33.3.4 Lemon cell
See diagram 32.149: Lemon cell
1. Connect a wire to a piece of zinc. You can use zinc cut from the
can of a used dry cell. Connect another wire to a piece of copper. Roll
a lemon on the table with your hand to break up some tissue inside. Push
the zinc and copper strips through the skin of the lemon so that they do
not touch. Connect both leads of a sensitive galvanometer or multimeter
to wires and note the deflection. Repeat the experiment using a potato. Observe
whether the distance between the metal strips affects the galvanometer reading.
2. Gently press or roll a lemon on the table to
squash the tissue inside. Connect one terminal of a galvanometer to a piece
of zinc and connect the other terminal to a piece of copper. Push the two
pieces of metal through the skin of the lemon. The metals must not touch.
Observe the deflection of the galvanometer needle to see whether current
flows. The lemon juice acts as an electrolyte. Does the distance between
the metals affect the deflection of the galvanometer needle? Repeat the experiment
with a potato. There is almost no deflection.
3. Use a lemon, orange or any piece of fruit, preferably
a juicy one, a copper wire and a coated iron wire such as galvanized packing
case binders, a centre zero galvanometer out of the storeroom, a voltmeter,
0 to 10 volts. Put the different kinds of wire in turn into the lemon,
the acidified water, add a few drops of dilute sulfuric acid, and acidified
hydrogen gas peroxide solution, 5 mL of hydrogen peroxide plus a few drops
of little dilute sulfuric acid. Connect the wires to a galvanometer in each
case and see what the pointer does when the wires are in each electrolyte
or solution such as fruit juice, or acidified peroxide. Leave the wires
in the acid and see that the zinc dissolves off the iron beneath it. The
copper cathode seems unchanged but is covered with bubbles of hydrogen gas.
The peroxide removes these bubbles. Try to light a 11 / 2 volt globe. Remember
that a series connection means copper of one cell to zinc of the next cell
and so on. 4. Connect one terminal of a galvanometer to a piece of zinc
and connect the other terminal to a piece of copper. Use the hand to roll
a lemon on the table to squash the tissue inside. Push the two pieces of
metal through the skin of the lemon. The metals must not touch. Note any
deflection of the galvanometer needle. The lemon juice acts as an electrolyte.
Does the distance between the metals affect the deflection of the galvanometer
needle? Repeat the experiment with a potato. There is almost no deflection.
4. Make two slits in the skin of a lemon and push
a "copper" coin, or a piece of copper (positive terminal), and a zinc
washer or piece of aluminium foil (negative terminal. Attach wires to make
a circuit. A chemical reaction takes place between the metals and the acid
in the lemon juice, causes the current to flow and light a 1.5 volt bulb.
5. To make a lemon battery / voltaic cell, "Lemon
screamer lasagna cell" stick copper and galvanized steel electrodes into
a lemon and attach a voltmeter. Attach zinc and copper strips to a galvanometer
and stick them into fruits and vegetables.
33.3.5 Simple chemical rectifier
Use a glass container filled with saturated solution of borax and electrodes
of aluminium and lead. Use a low volt direct current power source. You can
use this half wave rectifier as a battery charger. Connect four such cells
to form a bridge rectifier. Check "+" and "-" terminals with a voltmeter
33.3.6 Chocolate wrapper cell in the mouth
When the aluminium foil from a chocolate wrapper ("silver paper") touches
an amalgam filling mainly tin, two metals are in contact in the saliva electrolyte.
A current is generated, the aluminium tending to dissolve and the current
of electrons sends an unpleasant pulse along the nerves. Also a metallic
taste may be due to dissolved aluminium ions, Al3+.
33.3.7 Potato cell, noisy potato cell
Push 2 cm of copper wire and zinc wire one into a raw potato. Hold an
earphone connected to the wires to hear a crackling sound caused by a weak
electric current.
33.3.8 Hydrogen / oxygen fuel cell
The fuel cell allows the reaction between hydrogen and oxygen to generate
electricity. The equipment is sold with a 2 V motor to generate power. The
reaction requires potassium hydroxide pellets and palladium (II) chloride.
33.3.9 Ionic migration
Migration of coloured ions in an electrolyte can be shown with a flat
chamber the size of a microscope slide and coloured ions, e.g. MnO4-,
Cu2+, Cr202.
Dissolve some sodium sulfate in sufficient water to half fill a U-tube.
Add drops of universal indicator that is red in acidic solutions and blue
purple in alkaline solutions. The colour of the indicator should be green
showing that the solution is neutral. To an equal volume of water add 1
gram agar agar gel for each 100 mL of water. Warm until the gel dissolves
and then mix the two solutions. Pour this solution into the U-tube until
the arms are about half full. When the gel has set, pour dilute sulfuric
acid into one arm and dilute sodium hydroxide into the other. Insert platinum
or carbon electrodes into the solutions. Connect the electrode in contact
with sulfuric acid to the positive terminal of a battery. Connect the electrode
in contact with the sodium hydroxide solution to the negative terminal
of the battery. Allow the current to pass for some time and observe the colour
changes produced in each arm. The violet colour in the gel below the sodium
hydroxide solution is because of the movement of hydroxide ions into it under
the influence of the electric field. The red colour in the gel below the sulfuric
acid solution is because of the movement of hydrogen ions into it. So there
is evidence for a two way flow of ions.
33.3.10 Ionic friction
The apparatus contains a floater with 2 flags which start rotating due
to ionic movement. A direct voltage between the central bar electrode and
the ring electrode cause two radial and contrary ion streams in the absence
of a magnetic field. The vertically orientated field of the inserted ring
magnet cause a deviation towards the right or the left depending on the polarity
of the ions This cause a tangential flow component in the same direction for
both types of ions which is transferred to the water molecules and lets the
floater rotate, (Lorentz force).
33.3.11 EMF dependence on
electrode material
Use two stands each holding several strips of different metals which
can be paired and dipped into a dilute acid bath. Dip combinations of copper,
lead, zinc and iron into a dilute sulfuric acid solution.
33.3.12 Contact potential
difference
Show the contact potential difference between copper and zinc with a
condensing electroscope.
33.3.13 Crowsfoot or gravity
cell
Use a zinc-zinc sulfate / copper-copper (II) sulfate battery.
33.4.0 Dry cell capacity
Dry cells are are voltaic cells with the electrolyte in the form of a
paste, usually ammonium chloride, to avoid spilling of the electrolyte.
The total charge output from the cell is called the capacity of the
cell. You measure capacity of a cell or accumulator in the number of ampere
hours of charge it can deliver. The capacity of the cell and its work principle
depend on the volume. The more the capacity the cell has, the greater work
current appliance can be used and the longer the times it uses. Use different
dry cells. Connect a dry cell with a light bulb to form a circuit. Observe
the normal brightness of the bulb and record the time. Then insert in parallel
other bulbs to the bulb on the circuit in turn and observe the variation of
the brightness of the bulbs. When the bulbs no longer light, stop the experiment
and record the number of the bulbs connected to the circuit and time after
first connection in the circuit. If the bulbs still give light, wait until
they all no longer light and record the time from the first connection in
the circuit. Repeat the experiment with some different size dry cells. Note
the numbers of the bulbs increased until they go out and stop doing the experiment.
Compare the difference of the discharge time between the dry cells. Use a
millivoltmeter to measure the voltage of dry cells before and after discharge.
The voltage of new cells is about 1.5 V. The voltage of "no charge" cells
is about 0.75 V, the discharge stop voltage.
33.4.1 Dry cell in an electric
circuit
See diagram: 32.151.1: Simple electric circuit
| See diagram: 32.151.2: Torch battery electrical
experiments
Connect an electric bulb, e.g. 2.4 V, 0.5 A, and lampholder, to the
+ve and -ve terminals of a dry cell or lead cell accumulator or low voltage
power supply. Notice the filament made of tungsten carbide. Passage of the
electric current through the tungsten carbide wire causes it to become very
hot and give off light. Reverse the connections to the source of electricity
and the lamp still operates although the electricity is flowing in the
opposite direction. Draw a diagram to show the path of the current through
the bulb and around to the other end of the cell. This is a simple electric
circuit. Use circuit diagrams to represent the electrical components in a
circuit.
33.4.2 Dry cell torch battery
See diagram 32.150: Battery cut vertically
| See diagram 32.154.1: Electric torch
1. Remove the outer covering from an old dry cell. Use a saw to cut
the cell in half and observe its structure. Note the carbon (+ ve pole)
in the centre. The zinc container is the negative (- ve pole). The material
between the two poles is the ammonium chloride electrolyte. Note how the
zinc has been eaten away by the chemical.
2. Take apart an electric torch, e.g. electric torch,
2.4V, 0.5A, to see the different parts. Draw a circuit diagram. Note the
directions of insertion of batteries.
33.4.3 Battery, Bring a dead battery to life
Warm a used 1.5 v torch battery. The bulb may light again. The zinc
container of a battery cell becomes corroded by the ammonium chloride solution
as a paste. This creates an excess of electrons in the zinc and an electron
loss in the carbon rod. The carbon rod is coated with manganese dioxide
to prevent the build-up of hydrogen gas that would stop the reaction. The
bulb's incandescent filament gives out light when enough electrons flow through
it. When the chemical reactions in the battery slow and flow of the electrons
are not enough to make the filament glow. However, warming the battery accelerates
the chemical reaction so that the filament can briefly give out light again.
No chemical reaction can occur. When the zinc has corroded entirely and
turned into white powder, zinc chloride.
33.4.4 Dry cell terminals
Charge an electroscope with batteries in series. Connect several dry cells
in series to a condensing electroscope, remove the capacitance and test polarity
with charged rods
33.5.0 Power and energy, electrical
equivalent of heat, electrical energy
Power and Energy, watt W = 1 joule per second, watts = volts × amps,
filament lamps, fluorescent lamps, radiant electric fires, three heat switch,
fuses, W (joules = Q (coulombs) × V (volts)
Electrical energy, W, consumed by an electrical appliance is equal to
the work done to move charge through the appliance. If potential difference
is v volts and quantity of electricity passed = Q coulombs, the work done
= QV joules. Charge (Q) = current (I) × time (t) so work done = QV
= VIt joules.
Electric power, P, is the rate at which electrical energy, supplied by
batteries, thermocouples, photoelectric cells (photo-cells), generators,
is converted to another form of energy. The unit of power is joules per
second or watt, W. Power = work done / time taken, = Volts × Amperes,
VI = joule / coulomb × coulomb / second = joule / second = watt. So
a 100 watt light globe, an incandescent lamp, consumes 100 joules of electrical
energy per second. In this example "consumes" means converts electrical
energy to heat energy and light energy. The amount of electric energy used
by an electrical appliance, is equal to the work done to move charge through
that appliance. The longer the appliance operates, the more electrical energy
is used. All the electrical energy supplied to ohmic resistors is converted
into heat. The I-V graph for an ohmic resistor is a straight line graph. Ohm's
Law states that the ratio of the potential difference across the conductor
to the current flowing through it is constant, volt / amp = ohm, V / I = R.
Power = VI watt, IR watt, VAR. watt. Some circuit elements, e.g. vacuum diode,
do not have uniform I-V graphs and do not have a constant value for resistance.
Electric current, I, ampere, A, potential difference, volt, V
Power = work done / time taken, P = W / t
Charge transferred = current time, Q = It
Power, P in watts = VI, volts × amps
Power = current2 × resistance
Power systems, UK, 50 Hz 240 volts, RMS.
33.5.01 Heat from current through
a conductor is proportional to: 1. time, and 2. current2
See diagram 32.2.63d
When heat losses are small due to efficient lagging, the temperature
rise of water in the calorimeter is proportional to the heat given out by
the coil. Pour water in the calorimeter to cover the heating coil, resistance
2 ohms. Adjust the rheostat so current of 3 amps flows through the coil.
Record the initial temperature of the water. Close switch S and record the
time. Stir the water continuously and record the temperature after each
minute for 10 minutes. Plot a graph of temperature (Y axis) against 1. time
of passage of current (x axis) and 2. the square of the current. Close switch
S and adjust the rheostat for a current of 3 amps. Open the switch S, stir
the water and note its initial temperature. Close the switch and note the
time. Stir continuously until the temperature reaches 10oC, open
switch S, record the time and record the highest temperature reached by
the water in the calorimeter. Repeat the procedure but adjust the rheostat
for a current of 4 amps. Repeat the procedure but adjust the rheostat for
a current of 5 amps. Plot a graph of temperature rise (y axis) against the
square of the current (x axis).
Repeat the experiment with another heating coil R, of resistance 3 ohms.
Adjust the rheostat for a current of 3 amps. Note the initial temperature
of the water. Close switch S, record the time and stir well. When the temperature
has risen by 15oC, open switch S, record the time, continue stirring
and record the highest steady temperature. Replace the heating coil with another
of known resistance R, e.g. 5 ohms.
Repeat the above procedure with the same current, after adjusting the
rheostat Rh, for the same time with the same volume of water at the same
initial temperature. Record the initial and final temperatures.
33.5.1 Light from electrical energy
See diagram 32.5.4
Connect a 2.5 volt torch globe to a single 1½ volt torch cell
using a fine metal wire. Connect the cap of the globe to the cap of the
cell. Connect the side of the globe to the bottom of the cell. What happens
when the connections are broken? Repeat the experiment using two cells in
series, i.e. the cap of one connected to the base of the other. Also, do
the experiment with three cells. Can you detect a difference from the use
of the second and third cells? Cover the globe with a scrap of clear plastic
to prevent flying glass. Carefully break the glass so as not to damage the
wire filament and connect as before to one cell. What do you observe? What
purposes does the glass serve?
33.5.2 Heat from electrical energy
See diagram 32.5.4
Connect a piece of jug element wire, about 5 cm long, to a pair of torch
cells in parallel, i.e. each connected in the same way to the element wire.
Observe any effect on the jug element wire. Compare with the effect of one
cell and of three cells, connected both in series and in parallel. A jug
element should not be switched on unless covered by water.
33.5.3 Electric heater using steel wool
See diagram 32.5.3: Steel wool heater
Connect a bare copper wire to the outer case or outer terminal of an
ordinary torch cell by means of solder, sticky tape. That wire is the negative
wire because electrons leave the cell and travel along it. Similarly fasten
another bare copper wire to the brass end of the centre terminal or the
inner terminal of the cell where there is a deficiency of electrons and
twist a piece of bare copper wire on this clip. That wire is the positive
wire. Electrons return to the cell along it. The steel wool becomes hot
and not the copper leads connecting it to the battery because copper is a
better conductor than steel and the steel in steel wool is much thinner than
the copper in the leads.
33.5.4 Electric light and switch
See diagram 32.5.4: Light switches
Use a bored cork as a lamp holder or use a simple torch globe holder
that takes a screw-in globe. The positive wire touches the screw part of
your torch globe and the negative wire touches the little solder blob at
the end of the globe. Squeeze the switch wires together and light up your
lamp.
33.5.5 Electric jug, immersion heater
See diagram 32.5.5: Immersion heater circuit
| See diagram 32.5.5a: Electric jug
1. Use electric jug element wire and attach it to a heavy duty dry cell.
Use a 6 volt storage battery. Include a switch in your circuit. The wire in
the jug element is called nichrome wire because it has nickel and chromium
in it. Hang this electric jug element in a cup of water and switch on the
current. The water gets hot because much of the heat produced by the current
in the wire is transferred to it.
2. Use a wasted electric heater wire. Cut pieces
of the wire so you can parallel connect them to make a new heater. The
number of the wires depends on the electric current provided by source power.
The working current of each wire can be calculated according to original
working volt and power. Put the wires in a U-tube. Dip the U-tube into a
cup of water and turn on the power. The water in the jug absorbs the heat
from the element and thus keeps the temperature down below the melting point
of the metal in the element.
33.5.6 Voltage and current to a heating coil in
a calorimeter
Use an electrocalorimeter to determine the power delivered by temperature
change in water and compare to that computed from voltage current and time.
33.5.7 kWh meter and loads, heating with current
Measure the power consumed by an assortment of household appliances.
Pass large currents through No. 18 nichrome wire and measure the volts and
amps.
33.5.8 Heat wires in series
Solder together several lengths of different wires of the same length
in series and hang a piece of paper from each wire with soft wax so that
as current is passed through the wire the pieces of paper falls off at different
times.
33.5.9 Hot dog / pickle cooker
Hook nails to 110V and place them on and then in a hot dog sausage.
Apply 110 V through a hot dog and cook it.
33.5.10 Current through a torch globe
Place the ammeter in series with the globe so that any charge that passes
through the globe must also pass through the ammeter. Switch on the current
and note the reading on the ammeter. One ampere = one coulomb per second.
Two torch globes connected in series to one battery each give a duller light
than one globe attached to the battery because two similar torch globes connected
in series would have twice the resistance of a single globe, less current
would flow through the globes and the light emitted would be duller. However,
as the current from the battery is reduced, it would last longer.
33.5.11 Compare power of incandescent torch globes
Use different globes, headlamps, tail-light
globes and even torch globes, provided you have a suitable socket for them.
Short lengths of wire with small bulldog clips soldered at each end are useful
leads for electrical connections.
33.5.12 Compare light from incandescent lamps
Show that the two lamps using the same current
emit different amounts of light. Fit the two lamp holders with insulated
4 mm terminals. In two circuits one circuit contains a mains lamp taking about
0.4 amp and is connected to a 240 volt power supply and the other circuit
contains a motor car side lamp or tail lamp taking about 0.5 amp from a 12
volt a.c. supply. Connect the two lamp bases in series with the ammeter and
connect the circuit to the 240 volt main supply. A low voltage lamp and a
high voltage lamp take the same current. Similarly with a small electric motor
and a large electric motor that take the same current, e.g. 1.6 amps, the
large motor may turn a generator and light 3 lamps in series while the small
motor may not even turn the generator.
33.5.13 Light from a lamp, exposure meter
See diagram 32.5.13: Exposure meter circuit
If the lamp is lit from the a.c. terminals of the variable voltage supply
and not the d.c. then a.c. meters will be required. Place the exposure meter
15 cm from the lamp. Record readings of the light meter reading for various
currents through the lamp. Change the input power from 10 to 30 watts, corresponding
to a change of 7-14 volts. Draw a graph of light meter readings against power
input. The graph will be a straight line, not passing through the origin.
If a mains lamp is used, put the exposure meter further away from the lamp.
For a 100 watt lamp, a variac provides a suitable supply used with an a.c.
meter giving I amp full scale deflection or better 500 mA full scale deflection.
33.6.0 Circuit analysis, house circuits
Kirchhoff's voltage law, house circuits, circuits in parallel, switches,
fuses, two way staircase switch, ring main circuit, fused plugs, earthing,
3-pin plug, electricity meter, kilowatt hour, power ratings
Measure the voltages around a three resistor and battery series circuit.
33.6.1 Continuity of current
Insert an ammeter into any branch of a circuit to show currents in and
out of a node.
33.6.2 Superposition of currents
Measure the current from one battery, the current from a second battery
in another position and the combination in a circuit.
33.6.3 Standard reciprocity circuit with a potentiometer
Use a slide wire potentiometer with a battery and demonstration galvanometer.
Use a slide wire potentiometer with a standard cell. Contrast the slide
wire rheostat when used as a rheostat, or potential divider with rheostat
and six volt battery.
33.6.4 Wheatstone bridge, bridge circuits, slide
wire, metre wire bridge
See diagram 32.2.60
Stretch two nichrome wires across the bench and connect sliding clips
to a galvanometer to find equal potential points.
A bridge circuit usually contains 4 resistors, a source of direct or
alternating current and a galvanometer as a null point detector. If resistors
A and B are connected in series in one arm, resistors C and D are connected
in series in the other arm. Connect the galvanometer from between A and
B to between C and D, when the bridge is balanced, i.e. the galvanometer
shows no current flowing, then A / C = B / 4.
Examples of bridge circuits include the following:
Measure a resistance with a Wheatstone bridge, metre wire bridge, post
office box
Measure a capacitance or frequency with a Wien bridge
Measure inductance with a Maxwell bridge.
Measure the value of an unknown resistance with
a metre wire bridge. When switch S is closed and the resistances are such
that no current flows through the galvanometer G, the bridge is balanced,
R1 / R2 = R3 / R4. A 100 cm length of uniform resistance wire a.c. is attached
to brass strips of negligible resistance. The resistance of a uniform wire
is proportional to its length, so if B is the balance point, R1 / R2 = AB
/ BC, R1 = R2 × (BC /AB). 1. Use the sliding contact to find B on the
wire where no current flows through the galvanometer when the switch is closed.
Remove the shunt to make the galvanometer more sensitive and find the
balance point B more accurately. Measure AB and B3.
Replace the shunt and interchange R1 and R2 and measure AB and BC again.
33.6.5 Wheatstone bridge with a human galvanometer,
Wheatstone bridge with light bulbs
1. Stretch a loop of clothesline previously soaked in salt solution
in a parallelogram and hook the ends to a 110 V line then touch two points
of the same potential without electric shock.
2. Use a Wheatstone bridge configuration with 4
light bulbs for resistors using 110 ac. Use four 60 W lamps in a diamond-shaped
bridge with a 10 W lamp as the indicator then switch in an additional 6
V lamp when the circuit is balanced. Use three 110 V lamps and a rheostat
to make up the diamond of a Wheatstone bridge and use a small lamp to serve
as an indicator. Use series and parallel light bulbs in a light bulb board
with switches to allows configuration of several combinations. Use three
similar wattage lamps in series, three in parallel. Connect a series and
parallel circuit with three bulbs and six switches in 14 ways! Use three
110 V lamps wired in series and three wired in parallel.
33.6.6 Light bulb board, 12 V
Use a board with 12V bulbs and a car battery to allow combinations of
up to three series or
three parallel loads. Measure the current flowing through a wire resistor
with 6 V applied and then series and parallel combinations.
33.6.7 Equivalent resistance, series and parallel
Replace a series of resistors in a circuit by a single resistor. Use the
formula for obtaining integral values of resistors in parallel to obtain an
integral equivalent resistance. Replace parallel resistors by a single resistor
in a circuit. Use a Wheatstone bridge resistance circuit to reduce resistor
combinations to an equivalent resistance. Use a neon flasher circuit to show
the combination rules for series and parallel combinations of resistance and
capacitance by timing light flashes. Use a circuit board laid out so meters
can be plugged in and readings taken for demonstrations of series and parallel
circuits and Kirchhoff's laws.
33.6.8 a.c. Chopstick fan
Wave a white chopstick quickly forwards and backwards in neon light.
A Chinese fan with light and dark ribs appears. Neon tubes contain a gas,
which flashes on and off 60 (in US) times a second because of rapid reversals
in alternating current. The moving rod is thrown alternatively into light
and darkness in rapid sequence, so that it seems to move by jerks in a
semicircle. The light from a television set will produce the same effect.
Normally, the eye is too slow to notice these breaks in illumination clearly.
In a regular electric light bulb, the metal filament continues glowing between
the peaks in current.
33.6.9 Electrical circuits in a room
Investigate that the positions of every electrical appliance in the
house you live in and how their circuit connected. This activity will help
you to learn the lighting circuit and its application. If some day you want
to decorate or fit up your house, it will help you too. Observe the actual
position of every electrical appliance and draw an actual distribution curve.
Again begin at the place that the wires goes in, observe how the circuit
is connected. Draw a circuit of the room to show from which wire the electrical
appliances in the room use the electric current and how the switch on the
wall control the electrical appliances. Do not touch the dangerous parts
like a switch, plug. [Some teachers fail to see the point of this exercise
because if students cannot trace circuits they are not be able to find how
circuits are wired. The exercise only allows students to see what elements
are included in the circuit not how they are connected. However, there are
no safety problems with the activity.]
33.7.0 Instruments to detect electric current
Electrical measuring instruments include voltmeters 5 / 15 V and 0.3 to
300 V, ammeters 1 / 5 A and 1 mA to 3 A, with overload protection through
fuses and diodes. Multi-range meters are moving coil instruments to measure
direct and alternating currents and voltages that can be used for all current
ranges up to 10 1. Work and power meters show the relationship between voltages
and current intensity, time, power and energy and find the efficiency during
energy transformations. Special measuring instruments include light intensity
measuring instrument or lux meter and liquid conductivity meter.
33.7.1 Current detector
See diagram 32.163.1
Make a simple instrument to show electric current. Wrap 50 to 60 turns
of bell wire to form a coil around a jar 8 cm in diameter. Remove the coil
from the jar and bind it with short pieces of wire or insulating tape. Mount
the coil on a piece of cardboard. Attach a 16 mm plotting compass to a cork
and fix it inside the vertical coil. Rotate the coil until it is in line with
the compass needle. Connect a battery to the coil and observe the deflexion
of the compass needle. Reverse the connections, and observe the deflexion
of the compass needle again. Make a more sensitive instrument by putting
a compass in the tray of a match box then winding the coil wire over the box.
33.7.2.0 Galvanometer
See diagram: 32.3.01 | See diagram 32.0.1.1.6: Right hand motor rule
1. A galvanometer is an instrument for detecting small electric currents
by observing the deflection of a magnetic needle by an electric current
in a magnetic field. Meters for measuring voltage or current are made from
moving coil galvanometers. To keep the maximum force acting on the moving
coil, the magnetic field is drawn inwards by a "soft" iron core, making
the field appear radial. The moving coil turns against springs, which carry
the galvanometer current in and out of the coil, and return the coil to
zero. The moving coil turns a pointer across a scale, so that the scale reading
is proportional to the current through the coil.
2. The galvanometer is an instrument that detects an electric current.
Many types exist but usually use the moving coil galvanometer. The current
to be detected passes through a coil inside the instrument is in a magnetic
field. This causes the coil and the attached pointer to be deflected, the
direction and size of the deflection depending upon the direction and size
of the current. There is a risk of sending a larger current through the galvanometer
than is safe for the instrument. While this risk persists, for example when
trying to find a balance point in a potentiometer experiment, the greater
part of this current is made to "bypass" the galvanometer through a "protective
shunt" as in the diagram. A short length of fine, cotton covered copper wire
serves as a convenient shunt. This moving coil meter works on the same principle
as a simple d.c. electric motor and is called the D'Arsonval movement after
its inventor. It consists of a stationary magnet and a moving coil. When current
flows through the coil the resultant magnetic field reacts with the magnetic
field from the permanent magnet and causes the coil to rotate. The greater
the current the greater the rotation.
3. Mount a coil vertically on a phosphor bronze suspension that conducts
current between the circuit under the test and the coil. The phosphor bronze
suspension also provides the restoring force when it twists balanced against
the driving force of the coil's magnetic field. In some galvanometers a
coil spring below the moving coil, with an attached pointer, controls how
far the coil turns and measures the current. The direction of movement
follows the right hand motor rule for electron flow, where first finger
points towards from North to South, the second finger points in the direction
of electron flow in the conductor, the thumb points to the direction of motion
of the conductor.
33.7.2.1 Sensitivity and resistance of a galvanometer
Determination of galvanometric constants. Use external resistors to measure
the resistance and sensitivity of a galvanometer. Connect series resistance
to a galvanometer to make a voltmeter with low sensitivity and measure several
dry batteries in series with both the voltmeter and an electroscope.
33.7.2.2 Convert a galvanometer to a voltmeter
Knowing the resistance and sensitivity of a galvanometer add a series
resistance and then measure a voltage. Use a galvanometer with shunt and
series resistors.
33.7.2.3 Convert a galvanometer to an ammeter
Knowing the resistance and sensitivity of a galvanometer add a shunt
resistance and then measure a current.
33.7.2.4 Convert a galvanometer to an ammeter,
hot wire ammeter
See diagram 32.7.2.4
In a hot wire metre you pass the current through a platinum alloy hot
wire. When current passes through the wire, the wire expands due to the heat
effect of the current. The expansion is taken up by the spring metal strip.
The spring metal strip is much like a spring in mechanical watch that it
always maintains a tendency of stretch that pulls a silk thread tightly.
Wind the silk thread around a small pulley attached to the pointer. When
the silk strip moves, it pulls the pulley resulting in the deflection of
the pointer. Tie the other end of the silk strip to a phosphor bronze wire
attached to the hot wire. The silk strip could not be connected directly
to the wire, as it would burn when large current passed through the wire.
The phosphor bronze wire is insulated from heat. So the hot wire expands
as the current passes through it and loosens the phosphor bronze wire, stretch
the spring metal strip through silk's transfer. Finally, silk, pulley and
pointer move in turn. In view of energy, first the electric energy transforms
into heat energy. Then heat energy transforms into kinetic energy of pointer
and potential energy.
33.7.2.5 Reduction factor k of a tangent galvanometer
See diagram 32.2.66
The tangent galvanometer measures current flowing through a vertical
circular coil of known number of turns of insulated wire. The magnetic effect
of this current at right angles to the plane of the coil is measured by an
aluminium pointer attached to a turning bar magnet. The galvanometer is made
horizontal with adjustable legs and a spirit level. If the strength of
the magnetic field at the centre of the coil is H oersted, and the horizontal
component of the earth's magnetic field at that point is H1 oersted,
and θ (Greek) is the angle of deflection of the pivoted magnet, H = H1
tan θ. H, is a constant at a particular place so H is proportional to tan
θ. H is proportional to I, so I is proportional to tan θ or I = k tan θ,
The symbol k represents the reduction factor constant of the tangent galvanometer.
Using two turns of the coil. Place the tangent galvanometer away from any
magnetic fields from other devices in the circuit. Rotate the tangent galvanometer
until the plane of the coil is in the magnetic meridian as shown by the pivoted
magnet, and one end of the aluminium pointer is over the 0o mark.
Check that the tangent galvanometer is horizontal. Close switch S1.
Adjust the rheostat Rh until the galvanometer deflection is 30o.
Record the readings of both ends of the pointer (θ1o and
θ2o). Reverse the current with the reversing switch
S2 and again read both ends of the pointer (θ3o
and θ4o). Record the current I amps. Repeat to
give more deflections between 30o and 60o, each time
reversing the current through the galvanometer and recording the current
I amps.
33.7.3 Ammeter
See diagram: 32.3.02: Ammeter
The ammeter is an instrument that measures an electric current. The
resistance of an ammeter must be very small so that when it is placed in
a circuit it will not diminish the current it is intended to measure. The
ammeter is always placed in series in the circuit, and to make the pointer
deflect the right way, its positive terminal must be connected to the positive
side of the circuit. An ammeter is a galvanometer with a low value resistor
placed in parallel across its terminals so that the largest current in the
circuit causes full scale deflection and no more. Ammeters include moving
coil ammeter, moving iron ammeter, thermocouple, hot wire ammeter.
33.7.4.0 Voltmeter
See diagram: 32.3.03
The voltmeter is an instrument that measures the potential difference
between two points in a circuit. The resistance of a voltmeter must be
very high so that when it is placed across part of a circuit it does not
divert an appreciable amount of current from the main circuit. The voltmeter
is always placed in parallel with (i.e. across) the resistance to measure
the potential difference between its ends. When, connecting, make sure that
you connect the positive terminal to the positive side of the circuit. A
voltmeter is a sensitive galvanometer with a high value resistor placed
in series so that the largest voltage in the circuit causes full scale deflection
and no more, i.e. a shunted galvanometer. Connect a voltmeter across a resistor
to measure resistance and power consumption. Connect an ammeter in series
in the circuit to measure the current flowing through the ohmic resistor.
The voltmeter counts how many joules each coulomb delivers as it travels
through a lamp or motor. A voltmeter measure the energy transferred from
electrical energy to heat or mechanical energy. Volts = joules per coulomb,
or volts = joules of energy transferred from electrical form of energy to
other forms of energy in that part of the circuit for every coulomb passing
through it.
Resistance value of a resistor, R, = V / I, ohm = volt / amps.
Power consumed by resistor, P = V × I = volt × amps
Resistance, R, of a material increases with length, decreases with cross-section
area, and
depends on the resistivity quality of the material.
R = resistivity × length / area, e.g. resistivity copper = 1.7 ×
10-8 ohm metre, rubber = 1013 ohm metre.
33.7.4.1 Connect a voltmeter
See diagram 32.3.03.1
Connect the whole circuit first without a voltmeter then add the voltmeter,
e.g. across a lamp.
Set up a simple series circuit of 12 V battery, lamp and ammeter. Connect
a voltmeter in parallel with the lamp. Add an electric heating element or
small motor to the circuit. Connect the voltmeter may be connected across
the lamp then across the heating element.
Connect a series circuit of two similar lamps in series and repeat the
experiment. The circuit should always be switched off during changes in wiring.
3. Voltmeter connections: Wire the lamp fitted to the lamp base into a series
circuit with the ammeter. Switch on 12 volt battery. Switch off and connect
the voltmeter parallel with the lamp.
33.7.4.2 Voltmeter as cell counter
See diagram 32.3.03.2a
Connect a voltmeter to one cell of the 12 volt battery. Then connect
to two, three, four, five and six cells. The 12 volt car batteries used
must allow you to tap off intermediate voltages. Use 4 mm sockets for connection.
Connect a series circuit of seven dry cells, two rheostats and ammeter,
and record the current. Use two rheostats to keep a low current. Allow the
current to flow for a very short time only. Reverse one cell so that five
cells are effective to drive current through the circuit. Record the current.
Repeat this procedure by reversing two cells, leaving three cells effective.
Record the current.
Reverse 3 cells leaving one cell effective. Record the current. Tabulate
the currents and the numbers of effective cells. Change the current, either
by reversing cells, or by adding a rheostat to the circuit. Record the
corresponding values of the ammeter and voltmeter.
33.7.4.3 Calibrate a voltmeter
See diagram 32.3.03.3
Use plastic drinking cups with a low heat capacity. Put 200 g water
in a container. Put an immersion heater in the circuit. Record the initial
temperature. Close the switch and note the time. Use the heater as a stirrer.
Allow the current to flow for two minutes. Record ammeter and voltmeter
readings. At the end of two minutes open the circuit, stir the water again
and note the maximum temperature.
33.7.4.4 Potential difference and electromotive
force
See diagram 32.3.03.4
Potential difference can be thought of as "electrical pressure difference"
between the ends of a part of a circuit, where energy transfer occurs,
e.g. electrical energy to heat.
1. Connect the voltmeter first across lamp 1, then across the ammeter,
then across lamp 2, then across the three together (between P and Q), and
finally connect across the battery. Note the potential difference in each
case.
2. Repeat with a series of dry cells. Prepare this battery using accumulators
joined with about 50 cm of SWG 26 high resistance wire.
33.7.4.5 Loading by a voltmeter
Measure the voltage across a high resistance circuit with high and low
impedance.
33.8.1 Thermocouple, Seebeck
effect, thermoelectric effect
A thermocouple consists of two dissimilar metals, joined together at one
end. When the junction of the two metals is heated or cooled a voltage is
produced that can be correlated back to the temperature. Thermocouples are
cheap and available in different combinations of metals or calibrations
but may not be accurate enough or consistent enough for some applications..
The alloys used in thermocouples are commonly available as wire. A beaded
wire thermocouple consists of two pieces of thermocouple wire joined together
with a welded bead. A thermocouple probe consists of thermocouple wire housed
inside a metallic tube. A thermocouple surface probe is used to measure the
temperature of a solid surface. The thermocouple is based on the Seebeck
effect (thermoelectric effect) discovered by Thomas Johann Seebeck
1821 that a conductor generates a voltage when in a thermal gradient. A thermopile
is a set of joined thermocouples
Connect to a galvanometer two iron-copper junctions one in ice and the
other in a flame. Attach a voltmeter to the iron wires of two iron-copper
junctions while they are differentially heated. Place a twisted wire thermocouple
in a flame and observe the current. A commercial thermoelectric generator
is made from 150 constantan / nickel molybdenum thermocouples in series.
33.8.2 Seebeck effect and
Peltier effects
To show the thermoelectric effect of copper-iron junctions, send current
through a copper-iron-copper circuit for several seconds and immediately
disconnect and switch to a galvanometer. For a thermoelectric cooler, use
a Peltier device to cool a drop of water. Make an antimony-bismuth junction
and an apparatus to show heating and cooling due to the Peltier effect.
33.8.3 Copper-iron junctions
ring
Use a Bunsen burner to simultaneously heat sixty copper-iron junctions
in series and arrayed in a ring to produce 90 mA current
33.8.4 Thermoelectric compass
Join bars of copper and iron to form a case for a compass needle. The
needle will indicate the direction of the current as one or the other junction
is heated.
33.8.5 Thermocouple coil magnet
Heat a thermocouple loop and the current produces a magnetic field that
can be detected by a compass needle.
33.8.6 Thermoelectric effect
in a wire
A piece of soft iron wire connected to a galvanometer has little thermoelectric
effect until the wire is kinked.
33.8.7 Thompson effect
A flame moved along a long wire will push ahead current.
33.8.8 Thermoelectric magnet
Heat one side of a heavy copper loop closed by an unknown metal to generate
thermoelectricity for an electromagnet. A ring of copper shorted by iron
forms a thermocouple that powers an electromagnet when one end is in water
and the other is heated in a flame. Bend one end of a heavy copper bar into
a loop and closed with a copper-nickel alloy, heat one end and cool the other
end.
33.8.9 Thermocouple magnet
Use a Bunsen burner to heat one side of a thermocouple magnet supporting
over 10 Kg. Heat and cool opposite sides of a large thermocouple then suspend
a large weight from an electromagnet powered by the thermocouple current.
33.8.10 Thermoelectric heat
pump
Mount aluminium blocks with digital thermometers on either side of a
Peltier device. Run the current both ways.
33.8.11 Pyroelectric crystals,
domains of electric polarization
Show the temperature effect on the polarization of pyroelectric crystals
by heating tiny BaTiO3 crystals on a microscope slide until
the domains disappear.