This document provides instructions for building simple batteries and fuel cells to illustrate how electrical energy is produced and stored. It includes directions for making a potato battery, aluminum-air cells, and a rechargeable Ritter cell. Chemical reactions in each battery are explained. The potato battery generates around 0.5 volts, while the dry aluminum-air cell produces 1.2 volts, enough to power small devices. The rechargeable Ritter cell uses copper disks and can be recharged and discharged multiple times.
its a brief report on Tesla coil. its help to learn
-How to work
-How to maintain the Tesla coil
- application and advantages
-Prove of Tesla mathematical equations.
its a brief report on Tesla coil. its help to learn
-How to work
-How to maintain the Tesla coil
- application and advantages
-Prove of Tesla mathematical equations.
This experiment will correct the five false premises made by early scientists
who evaluated Faraday's Electric Magnetic Rotation Apparatus (motor)
False premises made by early scientists who evaluated Faraday's Electric Magnetic Rotation Apparatus (motor) – which still exist today 197 years later.
False premise # 1) Electrical energy can be transformed into mechanical energy.
True statement: Electrical energy can not be transformed into mechanical energy in electric motors, it can only be converted to heat energy and dissipated as heat energy due to the resistance of the wire used. Electric motors do not rotate due to heat dissipation.
False premise # 2) Electrical energy is required to create the magnetic field around a current bearing wire.
True statement: Electrical energy is not required to create the magnetic field around a current bearing wire.
The magnitude of current flow in a current bearing wire is dictated by the Electromotive Force (voltage) applied across the wire and the DC resistance of the circuit according to the equation I = E/R.
Some electrical energy is converted to heat (loss) due to the current bearing wire's DC resistance but there is no energy consumption related to the production of the magnetic field which is created for free.
False premise # 3) Electric motors convert electrical energy to heat energy and mechanical energy.
True statement: Electric motors do convert electrical energy to heat energy but they do not convert electrical energy to mechanical energy.
The equation, P = I^R dictates mathematically how much electrical energy is converted to heat energy in the motor's current bearing wire.
100% of the energy consumed in the motor is due to heat conversion.
0% remains mathematically to produce any mechanical conversion.
False premise # 4) Electric motors operate at less than 100% efficiency in their conversion of electrical energy to mechanical energy.
True statement: Electric motors operate at 100% efficiency in their conversion of electrical energy to heat energy.
The mechanical energy which is produced by an electric motor is provided by the magnetic field energy which is created around the current bearing wire with zero energy cost consumption and at infinite efficiency.
All electric motors operate at infinite efficiency in their production of mechanical energy / magnetic rotation and 100% efficiency in their conversion of electrical energy to heat energy.
False premise # 5) Energy cannot be created but can only be converted from one form to another.
True statement: The magnetic fields that are created around a current bearing wire are a form of energy – which is created because they perform work and change the kinetic energy of the current bearing wire according to the Work Energy Principle.
Energy (magnetic field energy) can and is being created around every current bearing wire.
Energy can be created.
Useful in the coarse of energy conversion for computer engineering students.
coverage: history of magnetism, Right hand rule, force due to magnetic field, motor and generator, Electromagnetic of straight conductor, loops, solenoid, magnetic dipole moment, materials of magnetism, faradays law of magnetism,
This experiment will correct the five false premises made by early scientists
who evaluated Faraday's Electric Magnetic Rotation Apparatus (motor)
False premises made by early scientists who evaluated Faraday's Electric Magnetic Rotation Apparatus (motor) – which still exist today 197 years later.
False premise # 1) Electrical energy can be transformed into mechanical energy.
True statement: Electrical energy can not be transformed into mechanical energy in electric motors, it can only be converted to heat energy and dissipated as heat energy due to the resistance of the wire used. Electric motors do not rotate due to heat dissipation.
False premise # 2) Electrical energy is required to create the magnetic field around a current bearing wire.
True statement: Electrical energy is not required to create the magnetic field around a current bearing wire.
The magnitude of current flow in a current bearing wire is dictated by the Electromotive Force (voltage) applied across the wire and the DC resistance of the circuit according to the equation I = E/R.
Some electrical energy is converted to heat (loss) due to the current bearing wire's DC resistance but there is no energy consumption related to the production of the magnetic field which is created for free.
False premise # 3) Electric motors convert electrical energy to heat energy and mechanical energy.
True statement: Electric motors do convert electrical energy to heat energy but they do not convert electrical energy to mechanical energy.
The equation, P = I^R dictates mathematically how much electrical energy is converted to heat energy in the motor's current bearing wire.
100% of the energy consumed in the motor is due to heat conversion.
0% remains mathematically to produce any mechanical conversion.
False premise # 4) Electric motors operate at less than 100% efficiency in their conversion of electrical energy to mechanical energy.
True statement: Electric motors operate at 100% efficiency in their conversion of electrical energy to heat energy.
The mechanical energy which is produced by an electric motor is provided by the magnetic field energy which is created around the current bearing wire with zero energy cost consumption and at infinite efficiency.
All electric motors operate at infinite efficiency in their production of mechanical energy / magnetic rotation and 100% efficiency in their conversion of electrical energy to heat energy.
False premise # 5) Energy cannot be created but can only be converted from one form to another.
True statement: The magnetic fields that are created around a current bearing wire are a form of energy – which is created because they perform work and change the kinetic energy of the current bearing wire according to the Work Energy Principle.
Energy (magnetic field energy) can and is being created around every current bearing wire.
Energy can be created.
Useful in the coarse of energy conversion for computer engineering students.
coverage: history of magnetism, Right hand rule, force due to magnetic field, motor and generator, Electromagnetic of straight conductor, loops, solenoid, magnetic dipole moment, materials of magnetism, faradays law of magnetism,
The research is about (power in oil rig ) after a short description in a basic of electricity and OHM's law , we explained about power in general . at last we searched about the type of power in oil rig we descript (Electric & Mechanical Drilling Rig , Mechanical Drilling Rigs Advantages and Disadvantages , Electric Drilling Rig , Electric Drilling Rig Advantage , DC (SCR) Drilling Rig , AC (VFD) Drilling Rig , AC versus DC Drilling Rig , AC Drilling Rig Advantages , Size according to depth , Typical power range )
Key Trends Shaping the Future of Infrastructure.pdfCheryl Hung
Keynote at DIGIT West Expo, Glasgow on 29 May 2024.
Cheryl Hung, ochery.com
Sr Director, Infrastructure Ecosystem, Arm.
The key trends across hardware, cloud and open-source; exploring how these areas are likely to mature and develop over the short and long-term, and then considering how organisations can position themselves to adapt and thrive.
Search and Society: Reimagining Information Access for Radical FuturesBhaskar Mitra
The field of Information retrieval (IR) is currently undergoing a transformative shift, at least partly due to the emerging applications of generative AI to information access. In this talk, we will deliberate on the sociotechnical implications of generative AI for information access. We will argue that there is both a critical necessity and an exciting opportunity for the IR community to re-center our research agendas on societal needs while dismantling the artificial separation between the work on fairness, accountability, transparency, and ethics in IR and the rest of IR research. Instead of adopting a reactionary strategy of trying to mitigate potential social harms from emerging technologies, the community should aim to proactively set the research agenda for the kinds of systems we should build inspired by diverse explicitly stated sociotechnical imaginaries. The sociotechnical imaginaries that underpin the design and development of information access technologies needs to be explicitly articulated, and we need to develop theories of change in context of these diverse perspectives. Our guiding future imaginaries must be informed by other academic fields, such as democratic theory and critical theory, and should be co-developed with social science scholars, legal scholars, civil rights and social justice activists, and artists, among others.
Smart TV Buyer Insights Survey 2024 by 91mobiles.pdf91mobiles
91mobiles recently conducted a Smart TV Buyer Insights Survey in which we asked over 3,000 respondents about the TV they own, aspects they look at on a new TV, and their TV buying preferences.
"Impact of front-end architecture on development cost", Viktor TurskyiFwdays
I have heard many times that architecture is not important for the front-end. Also, many times I have seen how developers implement features on the front-end just following the standard rules for a framework and think that this is enough to successfully launch the project, and then the project fails. How to prevent this and what approach to choose? I have launched dozens of complex projects and during the talk we will analyze which approaches have worked for me and which have not.
Dev Dives: Train smarter, not harder – active learning and UiPath LLMs for do...UiPathCommunity
💥 Speed, accuracy, and scaling – discover the superpowers of GenAI in action with UiPath Document Understanding and Communications Mining™:
See how to accelerate model training and optimize model performance with active learning
Learn about the latest enhancements to out-of-the-box document processing – with little to no training required
Get an exclusive demo of the new family of UiPath LLMs – GenAI models specialized for processing different types of documents and messages
This is a hands-on session specifically designed for automation developers and AI enthusiasts seeking to enhance their knowledge in leveraging the latest intelligent document processing capabilities offered by UiPath.
Speakers:
👨🏫 Andras Palfi, Senior Product Manager, UiPath
👩🏫 Lenka Dulovicova, Product Program Manager, UiPath
Connector Corner: Automate dynamic content and events by pushing a buttonDianaGray10
Here is something new! In our next Connector Corner webinar, we will demonstrate how you can use a single workflow to:
Create a campaign using Mailchimp with merge tags/fields
Send an interactive Slack channel message (using buttons)
Have the message received by managers and peers along with a test email for review
But there’s more:
In a second workflow supporting the same use case, you’ll see:
Your campaign sent to target colleagues for approval
If the “Approve” button is clicked, a Jira/Zendesk ticket is created for the marketing design team
But—if the “Reject” button is pushed, colleagues will be alerted via Slack message
Join us to learn more about this new, human-in-the-loop capability, brought to you by Integration Service connectors.
And...
Speakers:
Akshay Agnihotri, Product Manager
Charlie Greenberg, Host
Builder.ai Founder Sachin Dev Duggal's Strategic Approach to Create an Innova...Ramesh Iyer
In today's fast-changing business world, Companies that adapt and embrace new ideas often need help to keep up with the competition. However, fostering a culture of innovation takes much work. It takes vision, leadership and willingness to take risks in the right proportion. Sachin Dev Duggal, co-founder of Builder.ai, has perfected the art of this balance, creating a company culture where creativity and growth are nurtured at each stage.
Accelerate your Kubernetes clusters with Varnish CachingThijs Feryn
A presentation about the usage and availability of Varnish on Kubernetes. This talk explores the capabilities of Varnish caching and shows how to use the Varnish Helm chart to deploy it to Kubernetes.
This presentation was delivered at K8SUG Singapore. See https://feryn.eu/presentations/accelerate-your-kubernetes-clusters-with-varnish-caching-k8sug-singapore-28-2024 for more details.
The Art of the Pitch: WordPress Relationships and SalesLaura Byrne
Clients don’t know what they don’t know. What web solutions are right for them? How does WordPress come into the picture? How do you make sure you understand scope and timeline? What do you do if sometime changes?
All these questions and more will be explored as we talk about matching clients’ needs with what your agency offers without pulling teeth or pulling your hair out. Practical tips, and strategies for successful relationship building that leads to closing the deal.
DevOps and Testing slides at DASA ConnectKari Kakkonen
My and Rik Marselis slides at 30.5.2024 DASA Connect conference. We discuss about what is testing, then what is agile testing and finally what is Testing in DevOps. Finally we had lovely workshop with the participants trying to find out different ways to think about quality and testing in different parts of the DevOps infinity loop.
1. 1/15
BATTERIES
Storing energy
This worksheet provides an explanation on how chemical com-
pounds are used to produce electricity (voltaic cells) and store
it (batteries).
It includes several practical applications. Students can build
simple voltaic cells and batteries that illustrate how electrical
energy is produced and stored. At the end of the chapter there
is a simple application that involves the use of a corrosive com-
pound, which is why it is suggested as a possible extension.
Note that the worksheet “SOLAR CELLS” explains how elec-
tricity can be produced from light energy. Together with the
worksheet on “MOTORS,” these two worksheets provide a good
overview of the energy cycle used by Solar Impulse: produc-
tion, consumption, and storage.
Project: EPFL | dgeo | Solar Impulse
Writing: Michel Carrara
Graphic design: Anne-Sylvie Borter, Repro – EPFL Print Center
Project follow-up: Yolande Berga
2. Concepts covered
Science:
• Electricity
• Voltaic piles
• Batteries
Activity duration
Theory: 2 periods
Experiment: 4 experiments, 2 periods each
Some of the activities involve a significant
amount of preparation by the teacher.
3. BATTERIES - GUIDE 3/15
HISTORICAL SIDENOTE
The history of storage batteries begins with the history of Voltaic piles.
At the end of the 18th
century, the Italian doctor and physicist Luigi Galvani noticed that the muscles of
frog legs contracted when they came into contact with metals. Galvani also discovered that the con-
traction is stronger when the instrument used is composed of two different types of metals. He referred
to this newly discovered phenomenon as animal electricity.
Ten years later, Alessandro Volta made the first stacked voltaic pile, basing himself on Galvani’s work.
Volta, an Italian physicist, discovered that it was possible to generate electricity using two metal plates
that are connected by a conducting liquid. He stacked up zinc and copper disks separated by round
cardboard disks that had been soaked in a saline solution to conduct the current, forming a pile. His
invention became known as the Voltaic pile.
Five years later, in 1802, the German physicist and physiologist Johann W. Ritter discovered the prin-
ciple behind rechargeable batteries. He made a stack of copper disks that were each separated by
cardboard disks soaked in a saline solution. Although his device did not produce a current on its own,
he noticed that it could be charged by connecting it to a Voltaic pile. Moreover, the process could be
repeated several times. He called his invention a secondary cell. The storage battery, or accumulator,
was born.
Also in 1802, Doctor William Cruickshank designed the first electric battery that could be mass-pro-
duced. He arranged square sheets of copper that were soldered at their extremities, and placed sheets
of zinc of the same size between them. These sheets were then put into a long rectangular wooden box
that was sealed shut using cement, to make it watertight. Slots inside the box helped keep the metal
plates in place. The box was filled with a saline aqueous solution (lie) or a dilute acid. For quite some
time, batteries contained primary elements, which meant that they were not rechargeable.
In 1859, Gaston Planté developed the first lead accumulator, which is still found in car batteries today.
His device consists of two sheets of lead that are rolled up into spirals and kept apart with insulating
strip. Connecting a battery to his device oxidized the positive electrode, while the iron oxide on the
negative electrode was reduced, polarizing the electrodes. Connecting the two terminals, Planté ob-
served an electric current that had not been there when the electrodes were in their original state. To
increase the surface of the electrodes, Planté rolled up two strips of lead that were separated by two
rubber spacers to keep them from touching each other.
In 1901, Thomas Edison invented the iron-nickel battery, which went on to be used to illuminate mines
and drive carts.
But it would take almost a century for lithium-ion batteries, first commercialized by Sony Energitech
in 1991, to appear. Today, lithium-ion batteries dominate the portable device market (for example in
mobile phones).
This worksheet is designed to familiarize your students with batteries.
It also introduces some notions of the history of science.
4. 4/15 BATTERIES - GUIDE
BATTERIES
You cannot talk about batteries without talking about electricity. Here are some basic concepts that are
needed to understand the topic of this worksheet.
The electrons will quickly reach point A, where
they will neutralize the positive charges. At the
same time, the flow of electrons away from B will
exhaust the supply of electrons. The short-lived
flow comes to a halt. To maintain a current (the
collective displacement of a group of electrons in
a conductor), the electrons have to be removed
from A and returned to B. This is what an electri-
cal generator does. A generator is a device that
acts as an “electron pump.”
In the case of batteries, a redox reaction continuously provides electrons to maintain the flow of the
current, and then makes them disappear.
The origin of electric current
Connect two ends of an electric wire to two equal
but opposite electric charges (+ and –) and an
electric current will flow through the wire: free
electrons in the wire will be attracted by the pos-
itive charges (+) at point A and repelled by the
negative charges (–) at point B.
Salt bridge (filled with NaCl) Copper stripIron strip
CathodeAnode
Cu2+
solutionFe2+
solution
Direction of the electrons
Direction of the current
Fe Fe2+
+ 2e–
An oxidation reaction
supplies electrons
Cu2+
+ 2e–
Cu
A reduction reaction
removes the electrons
Free electrons in the metal
and the direction in which they move
+
A B
+ + –
–
–
Générator
Conductor
+ –
A current in a conductor,
created by a generator
5. BATTERIES - GUIDE 5/15
Electrical circuits
An electrical circuit is made up of an uninterrupted series of conductors that are connected to a gener-
ator. If this sequence is interrupted, for example by a switch, the flow of the current through the circuit is
interrupted as well. This explains why it is necessary to include a salt bridge connecting the containers
of the wet cell: the electrical charges are able to flow only when the circuit is closed.
The direction of electrical currents
The terminals of an electrical generator are marked with the symbols + and –. By convention, the direc-
tion of the current is defined as follows: the current leaves the generator at the + terminal and reenters
through the – terminal. This convention was established by André-Marie Ampère (1775 - 1836) at a time
when the true nature of electrical currents was not yet understood. In reality, electrons flow through a
circuit in the opposite direction: the electrons leave the generator through the – terminal and flow back
into it through the + terminal.
The intensity of electric currents
All collective motions, such as cars driving along a road, or a river flowing along its track, can be char-
acterized by their flow rate. The intensity I of an electrical current in a conductor is the rate at which
electrical charges flow through it. That means that the intensity of a current is determined by the num-
ber of electrical charges that flow through a cross section of the conductor per second. The unit used
to quantify the intensity of an electrical current is the ampere [A], in recognition of André-Marie Ampère.
The voltage between two points in a circuit
For electrical charges (electrons) to flow through a conductor, they have to be given a large enough
amount of energy, which is referred to as the voltage U. Voltage can be compared to what happens in
a waterfall. The amount of energy gained for each meter a drop of water falls is the same, whether it
falls from 15 m to 14 m or from 1 m to the ground. A charge has an energy because, when it is repelled
by the negative and attracted by the positive terminal of a battery, it “naturally” flows from the – to the
+ terminal. As a charge flows in this direction, its energy decreases. By definition, the voltage between
two points in a circuit is the amount of electrical energy consumed to displace a charge from one point
to the other. The unit used to quantify voltage is the volt [V], in recognition of Alessandro Volta.
The resistance
The current that a battery can push through an electric circuit is similar to the water than can be pushed
through a tube by a pump: the higher the pressure of the pump, the greater the flow rate through the
tube becomes. In the same way, the higher the voltage of the battery, the greater the intensity of the
current that is generated in the circuit. The resistance R of a conductor is defined as the ratio between
the voltage U that is applied to a conductor and the intensity I of the current that it generates.
Ohm’s Law: U = R ∙ I
R the electrical resistance [Ω]
U the voltage [V]
I the intensity of the electrical current [A]
6. 6/15 BATTERIES - GUIDE
Do it yourself: Make a simple dry cell using potatoes (“Agro-Battery”)
Cut the bottom of a potato so that it
stays upright on a flat surface.
Make a slit using a knife and insert
the copper strip.
Stick in a nail at the chosen distance.
Distance
[cm]
Voltage
[V]
0.5 0.553
1 0.553
1.5 0.553
2 0.556
2.5 0.550
3 0.551
3.5 0.532
4 0.508
4.5 0.460
Voltage [V]
Distance between the two electrodes [cm]
0 0.5 1 1.5 2 2.5 3 3.5 4 4.5
0.6
0.5
0.4
0.3
0.2
0
0.1
Beyond 3 cm, the voltage decreases, which is why a spacing of 2 cm was chosen.
3.5 cm between the electrodes 2 cm between the electrodes
Extension: analysis of the potato cell. (This could serve as the basis for a practical lab session for stu-
dents interested in science or physics.)
Influence of the distance between the nail and the copper strip
7. BATTERIES - GUIDE 7/15
Number of
potatoes
Voltage
[V]
1 0.534
2 1.048
3 1.300
4 1.838
5 2.363
6 2.907
7 3.410
Time
[min]
Voltage
[V]
0 0.540
1 0.539
2 0.537
3 0.536
4 0.535
5 0.535
10 0.532
15 0.529
20 0.525
25 0.519
30 0.516
35 0.520
40 0.517
45 0.514
50 0.513
55 0.513
60 0.512
Voltage [V]
Number of potatoes
0 1 32 4 5 6 7
3.5
3
2.5
2
1.5
1
0
0.5
Variation of the voltage over time (1 potato, 2 cm between the electrodes)
The Influence of the number of potatoes (2 cm distance between the electrodes)
Voltage [V]
Time [min]
0 5 1510 20 25 30 35 40 45 50 55 60
0.6
0.5
0.4
0.3
0.2
0
0.1
For at least one hour, the voltage remains more or less
stable (in 60 minutes the voltage drops by 5%). You can
easily work with this battery during a two hour practical
lab session.
Connecting the potatoes in a series leads to the expected result: the voltages of each
individual battery add up. With 5 to 7 potatoes, we are able to switch on a diode.
8. 8/15 BATTERIES - GUIDE
TECHNOLOGY: BUILD A BATTERY
A SIMPLE FUEL CELL: A WET ALUMINUM – AIR CELL
Below are the reactions that occur in this type of fuel cell.
For the aluminum (anode): Al + 3 OH–
Al(OH)3 + 3e–
For the air (cathode): O2 + 2 H2O + 4e–
4 OH–
The overall reaction is: 4 Al + 3 O2 + 6 H2O 4 Al(OH)3
The steel wool does not react. Its purpose is to
act as a cathode for the current to flow through.
Here, the voltage is around 300 mV.
The influence of the choice of fruit or vegetable
orange: 0.532 V lemon: 0.601 V shallot: 0.434 V
The same exercise can be repeated with other types of fruits and vegetables.
9. BATTERIES - GUIDE 9/15
A SIMPLE FUEL CELL: A DRY ALUMINUM – AIR CELL
Below are the reactions that occur in this type of fuel cell.
For the aluminum (anode): Al + 3 OH–
Al(OH)3 + 3e–
For the air (cathode): O2 + 2 H2O + 4e–
4 OH–
The overall reaction is: 4 Al + 3 O2 + 6 H2O 4 Al(OH)3
The carbon in the pencil leads does not react. Its purpose is to
act as a cathode for the current to flow through.
Here the voltage is about 1,2 V.
This dry cell can power a musical postcard or a small low-power
electromotor, such as the one presented in the “MOTORS”
worksheet.
10. 10/15 BATTERIES - GUIDE
A SIMPLE RECHARGEABLE BATTERY: A SECONDARY RITTER CELL
Instructions
1) It might be a good idea to cut out the shapes before carrying out the experiment with the students,
as this first step takes a lot of time.
3) The contact between the individual elements can be improved by placing a weight on top of the
stack. If the weight is not heavy enough, you may even have to press down on the stack throughout
the experiment. The NaCl solution may spill out, carrying copper oxide with it; the workbench will
have to be cleaned following the experiment.
If you connect a multimeter to the terminals of the setup at this time, no voltage will be measured.
For more information on the details of this type of rechargeable battery, please refer to the measure-
ments reported below.
5) The following chemical reactions can be observed in the Ritter cell.
When it is being recharged, copper oxide Cu2O is formed (using water and oxygen from the air).
At the anode: 2 H2O + O2 + 4e–
4 OH–
At the cathode: 2 Cu + H2O Cu2O + 2H+
+ 2e–
The overall reaction is: 4 Cu + 4 H2O + O2 2 Cu2O + 4H+
+ 4 OH–
Or simplifying: 4 Cu + O2 2 Cu2O
When it is being discharged.
At the anode: 2 Cu2O + O2 4 CuO + 2e–
At the cathode: 2 Cu2O + 4e–
4 Cu + O2
The overall reaction is: 6 Cu2O + O2 4 Cu + 8 CuO
When it is being discharged, the Cu+
(contained in the Cu2O) is transformed into Cu2+
at the anode
(contained in the CuO) and into Cu at the cathode; this process is referred to as a disproportionation.
Using 20 copper disks, and after recharging the
cell for 3 minutes, the voltage is approximately
120 mV.
At the end of the experiment, we can see that
electrical charges have oxidized the copper
disks. After three charge / discharge cycles:
Final note: The rechargeable battery presented here dries out quickly, in less than one hour. Once it
is dry, it no longer works. All of the materials can be reused to make a new Ritter cell (blotting paper,
copper; the copper has to be cleaned using steel wool.)
11. BATTERIES - GUIDE 11/15
Analysis of the secondary Ritter cell
(Can be used as the basis of a practical laboratory session for students interested in science and physics)
Influence of the number of copper disks on the voltage (charged at 4.5 V for 5 minutes)
Discharge
time
[min]
Voltage [mV] as a function of
the number of copper disks
5 10 15 20
0 100 280 410 310
0.5 52 219 352 239
1 48 177 332 203
1.5 31 134 314 170
2 33 112 301 153
2.5 28 104 288 136
3 21 92 279 133
3.5 17 75 271 127
4 16 70 263 122
4.5 13 72 256 116
5 12 68 248 112
Discharge
time
[min]
Tension [mV] as a function
of the charging time
1 min 2 min 3 min 4 min 5 min
0 210 302 402 467 510
0.5 128 195 268 318 352
1 98 154 200 239 287
1.5 70 120 144 171 229
2 45 64 93 112 164
Influence of the charging time (15 copper disks, charged at 4.5 V)
We can see that the differences in voltage become smaller as we approach 5 minutes of charging
using a 4.5 V battery (at t = 0 min in the table on the left), which is why we chose to charge our cell
for 5 minutes.
With the copper sheet used here, we can see that we reach an optimum at 15 disks, which is why the
remaining measurements will be made using a secondary Ritter cell with 15 layers. The appearance
of an optimum can be explained quite simply. By using more elements we increase the maximum
available charge, but at the same time, we increase the resistance, as well as problems caused by the
contact between the individual elements of the secondary Ritter cell. Therefore, there is an optimum
number of elements that depends on various factors, such as the thickness of the copper sheet, the
thickness of the blotting paper, the quality of the contact between the individual elements, etc.
Voltage [mV]
400
350
300
250
200
150
0
50
100
Discharge time [min]
5 disks 10 disks 15 disks 20 disks
0 1 32 4 5
Voltage [mV]
500
400
300
200
0
100
Discharge time [min]
Charging time:
1 2 43 5
2min 3min 4min 5min1min
12. 12/15 BATTERIES - GUIDE
Discharge
time
[min]
Voltage [mV]
as a function of the
number of cycles
1 2 3
0 702 720 732
0.5 519 491 503
1 417 400 412
1.5 329 327 339
2 270 294 306
2.5 232 262 274
3 207 240 252
3.5 188 221 233
4 170 205 217
4.5 156 192 204
5 144 181 193
5.5 133 172 184
6 124 163 175
6.5 116 156 168
7 108 149 161
7.5 101 143 155
8 96 137 149
8.5 91 132 144
9 86 125 137
9.5 82 122 134
10 79 118 130
Influence of the number of charge/discharge cycles (15 disks, charged at 4.5 V for 5 minutes)
The cell can be recharged several times. We can see that the charge remains essentially the same
even after 3 charge / discharge cycles.
Voltage [mV]
700
500
600
400
300
200
0
100
Discharge time [min]
Number of cycles:
0 1 32 9764 85 10
2nd
cycle 3rd
cycle1st
cycle
13. BATTERIES - GUIDE 13/15
Discharge
time
[min]
Voltage [mV]
as a function of the
number of cycles
1 2 3
0 200 340 360
0.5 160 260 297
1 130 240 212
1.5 130 195 172
2 110 174 140
2.5 120 135 124
3 120 140 110
3.5 110 120 95
4 100 97 88
4.5 110 94 87
5 90 85 83
5.5 95 80 78
6 80 74 71
6.5 80 68 70
7 80 65 69
7.5 60 68 65
8 55 61 63
8.5 40 55 58
9 45 51 62
9.5 35 47 57
10 30 46 55
Influence of the number of charge / discharge cycles (20 disks, charged at 4.5 V for 5 minutes)
Here, the copper disks were “new” during the first charging cycle, which is why the performance
was worse than in the following ones. During the first cycle, there was probably still some coating
on the copper disks, which would have made the cell less efficient. In fact, during the first charging
cycle, the cell heated up more than usual, hinting at a higher consumption of current caused by the
coating on the copper disks (and a consequently higher resistance). This heating was not observed
in the following two charging cycles.
Voltage [mV]
350
250
300
200
150
100
0
50
Discharge time [min]
0 1 32 9764 85 10
Number of cycles: 2nd
cycle 3rd
cycle1st
cycle
14. 14/15 BATTERIES - GUIDE
A SIMPLE RECHARGEABLE BATTERY: EDISON’S NICKEL–IRON BATTERY
This experiment is easier to carry out than the Ritter cell, but it requires the use of 0.1 M NaOH,
which must be handled with care.
Instructions
1) The piece of nickel used is a former French one
franc coin.
2) If you connect a multimeter to the terminals at
this moment, a weak voltage of a few mV may be
measurable. This voltage decreases over time,
dropping from 0.111 V to 0.078 V in three min-
utes. It is caused by the different metals coming
into contact.
3) When charging the battery, small gas bubbles can
be seen on the nail and on the nickel. Applying a
voltage of 4.5 V electrolyzes the water, which is
decomposed into oxygen (O2) and hydrogen (H2).
The oxygen appears on the nickel and the hydro-
gen on the iron.
4) The battery gives about 1.5 V.
For more details on this battery, see the results of
the analysis given below.
The following chemical reactions can be observed on this battery.
When it is being charged (dipping the iron and the nickel into the NaOH solution creates a layer of
iron hydroxide Fe(OH)2 and nickel hydroxide Ni(OH)2 on their surfaces.)
At the anode (the iron electrode): Fe(OH)2 + 2e–
Fe + 2 OH–
At the cathode (the nickel electrode): Ni(OH)2 + OH–
NiO2H + H2O + e–
The overall reaction is: Fe(OH)2 + 2 Ni(OH)2 Fe + 2 NiO2H + 2 H2O
When it is being consumed.
At the anode: Fe + 2 OH–
Fe(OH)2 + 2e–
At the cathode: NiO2H + H2O + e–
Ni(OH)2 + OH–
The overall reaction is: Fe + 2 NiO2H + 2 H2O Fe(OH)2 + 2 Ni(OH)2
Once the cell has been discharged, the electrodes are again covered by iron and nickel hydroxide.
15. BATTERIES - GUIDE 15/15
Analysis of the Edison Battery
(can be used as the basis of a practical laboratory session for students interested in science and physics)
Influence of charging time (charged at 4.5 V)
Discharge
Time
[min]
Voltage [V]
as a function of the charging time
10 s 20 s 30 s 60 s 120 s
0 1.558 1.558 1.548 1.563 1.521
0.5 1.465 1.467 1.471 1.485 1.446
1 1.395 1.400 1.406 1.427 1.394
1.5 1.328 1.338 1.348 1.371 1.346
2 1.274 1.284 1.301 1.322 1.309
2.5 1.225 1.237 1.257 1.278 1.268
3 1.186 1.195 1.217 1.238 1.240
3.5 1.115 1.164 1.183 1.201 1.209
4 1.113 1.127 1.156 1.172 1.170
4.5 1.079 1.091 1.124 1.148 1.150
5 1.051 1.061 1.090 1.114 1.128
This battery can be recharged very quickly, in
just a few seconds, but it is also consumed very
quickly. In 5 minutes, it loses 30% of its charge.
Influence of the number of charge / discharge cycles (charged at 4.5 V for 1 minute)
Discharge
Time
[min]
Tension [V] as a function
of the number of cycles
1 2 3
0 1.521 1.532 1.555
0.5 1.446 1.560 1.462
1 1.394 1.401 1.416
1.5 1.346 1.354 1.360
2 1.309 1.313 1.325
2.5 1.268 1.273 1.270
3 1.240 1.239 1.223
3.5 1.209 1.205 1.184
4 1.170 1.178 1.151
4.5 1.150 1.155 1.110
5 1.128 1.134 1.077
5.5 1.109 1.106 1.050
6 1.090 1.080 1.025
6.5 1.067 1.057 1.004
7 1.046 1.037 0.986
7.5 1.026 1.018 0.971
8 1.008 1.001 0.958
8.5 0.991 0.984 0.948
9 0.976 0.969 0.932
9.5 0.961 0.957 0.925
10 0.948 0.945 0.920
Voltage [V]
1.6
1.4
1.0
1.2
Discharge time [min]
Charging time [sec]: 12020 6010 30
1 2 43 5
Voltage [V]
1.6
1.4
1.2
1.0
0
0.8
0.2
0.4
0.6
Discharge time [min]
0 1 32 9764 85 10
Number of cycles: 2nd
cycle 3rd
cycle1st
cycle