Electromagnetic Induction
Summary
TLDREl video de Mr. Andersen aborda la inducción electromagnética, la capacidad de un campo magnético para crear corrientes eléctricas en un conductor. Se menciona a científicos como Hans Christian Orsted y Michael Faraday, quienes exploraron la relación entre los campos magnéticos y la electricidad. Faraday utilizó un aparato compuesto por un anillo de hierro y un electromagnete para demostrar que un cambio en el flujo magnético puede inducir una corriente eléctrica. Se discute cómo el flujo magnético, definido como el producto de la intensidad del campo magnético y el área perpendicular a él, influye en la inducción. El video también explica cómo los generadores funcionan, mostrando cómo la rotación de un cable en un campo magnético puede generar corrientes y energía eléctrica. Finalmente, se destaca la importancia de la inducción electromagnética en la generación de energía, como en las centrales hidroeléctricas.
Takeaways
- 🧲 La inducción electromagnética es la capacidad de un campo magnético para crear corriente en un conductor.
- 🔋 Michael Faraday descubrió que un campo magnético puede producir corriente, lo que se conoce como inducción electromagnética.
- 📡 El cambio en el flujo magnético, que es la cantidad de campo magnético que atraviesa una superficie perpendicular a él, provoca la inducción electromagnética.
- 🔗 La corriente se genera cuando se cierra o abre un interruptor, lo que altera el flujo magnético.
- 📏 El flujo magnético también puede cambiar al variar el área de la superficie que está perpendicular al campo magnético.
- 📐 La inclinación de la superficie en relación con el campo magnético requiere de trigonometría para calcular el componente del campo magnético perpendicular a la superficie.
- 💡 La inducción electromagnética tiene aplicaciones prácticas, como en la generación de electricidad y los generadores.
- 🌐 Un generador funciona al girar alambres en un campo magnético, lo que produce cambios en el flujo magnético y, por lo tanto, corriente.
- 🔗 El flujo magnético se puede aumentar en un alambre enroscado, ya que cada hilo contribuye a un flujo magnético individual.
- 🚰 Un aumento en la velocidad del flujo de agua en un generador hidráulico aumenta la cantidad de corriente inducida.
- 💡 La energía cinética del agua en una represa puede ser convertida en energía electromagnética mediante la rotación de imanes por parte del agua.
- 🔋 La inducción electromagnética es fundamental en la construcción de dispositivos como generadores, que son esenciales para la generación de electricidad.
Q & A
¿Qué es la inducción electromagnética?
-La inducción electromagnética es la capacidad de un campo magnético para crear corrientes eléctricas dentro de un conductor.
¿Quién fue el científico que demostró que un campo magnético puede afectar a una aguja de brújula?
-Hans Christian Orsted fue el científico que demostró que un campo magnético puede afectar a una aguja de brújula.
¿Qué científico investigó si un campo magnético podría producir corrientes eléctricas?
-Michael Faraday investigó si un campo magnético podría producir corrientes eléctricas.
¿Qué es la magnitud de flujo magnético?
-El flujo magnético es una medida de cómo un material conductor o cualquier material en general es afectado por un campo magnético. Se define como el producto de la intensidad del campo magnético y el área superficial perpendicular a ese campo.
¿Cómo se produce la inducción electromagnética?
-La inducción electromagnética se produce cuando hay un cambio en el flujo magnético a través de un conductor, lo que puede ocurrir al cambiar la intensidad del campo magnético, el área a través de la cual fluye el campo o la orientación del conductor con respecto al campo magnético.
¿Cómo funciona un generador?
-Un generador funciona rotando alambres a través de un campo magnético. A medida que los alambres se mueven, experimentan cambios en su flujo magnético, lo que provoca cambios en la corriente eléctrica que fluye a través de ellos, generando así energía eléctrica.
¿Cómo se puede aumentar el flujo magnético a través de un conductor?
-Se puede aumentar el flujo magnético a través de un conductor aumentando la intensidad del campo magnético, aumentando la área superficial perpendicular al campo magnético o cambiando la orientación del conductor para maximizar el número de líneas de campo magnéticas que atraviesen el conductor.
¿Por qué la inducción electromagnética es importante para las aplicaciones prácticas?
-La inducción electromagnética es importante para las aplicaciones prácticas porque es el principio detrás de la generación de electricidad en generadores, incluyendo los generadores de electricidad en centrales hidroeléctricas, y es fundamental en la creación de dispositivos electrónicos y equipos de medición como los galvanometros.
¿Cómo afecta el número de alambres a la cantidad de corriente inducida en un generador?
-A medida que se aumenta el número de alambres en un generador, se aumenta la cantidad de corriente inducida, ya que cada alambre contribuye a la suma total de corrientes inducidas, proporcionando así más energía eléctrica.
¿Cómo se relaciona el cambio de orientación de un conductor en un campo magnético con la inducción electromagnética?
-Cuando se cambia la orientación de un conductor en un campo magnético, el número de líneas de campo magnéticas que atraviesan el conductor también cambia, lo que provoca un cambio en el flujo magnético y, en consecuencia, la inducción electromagnética.
¿Cómo se mide la corriente inducida en una demostración de inducción electromagnética?
-La corriente inducida en una demostración de inducción electromagnética se mide utilizando un galvanometro o un voltímetro, que miden la cantidad de voltaje generado por la corriente inducida en el conductor.
¿Por qué la inducción electromagnética solo ocurre cuando se cierra o se abre el interruptor en la demostración?
-La inducción electromagnética solo ocurre cuando se cierra o se abre el interruptor porque estos movimientos provocan un cambio en el flujo magnético a través del conductor, que es la condición necesaria para la inducción electromagnética.
Outlines
🧲电磁感应的基本原理
在这段视频中,Mr. Andersen介绍了电磁感应的概念,即磁场在导体中产生电流的能力。他回顾了科学家如汉斯·克里斯蒂安·奥斯特发现电流可以产生磁场,而法拉第则探索了磁场是否也能产生电流。通过实验,法拉第发现当电路闭合和断开时,导体中会产生电流,这表明电磁感应的存在。Mr. Andersen还解释了磁通量的概念,即材料如何受到磁场的影响,并通过磁通量的变化来理解电磁感应的产生。
🔌电磁感应在实际应用中的重要性
Mr. Andersen进一步讨论了电磁感应的实际应用,包括我们日常使用的电力和麦克风。他通过发电机的工作原理来说明电磁感应是如何工作的。在发电机中,导体在磁场中旋转,导致磁通量的巨大变化,从而产生电流。他还展示了如何通过改变磁场的大小、导体的表面积或导体的角度来改变磁通量,从而产生电流。通过模拟实验,观众可以看到改变磁体位置时电流的产生,以及增加导体数量如何增加电流。最后,他解释了水力发电站的工作原理,即水流带动磁体旋转,从而产生电能。
Mindmap
Keywords
💡Inducción electromagnética
💡Campo magnético
💡Hans Christian Ørsted
💡Michael Faraday
💡Fluxo magnético
💡Galvanómetro
💡Conductor
💡Electromagnetismo
💡Transformación de energía
💡Generador
💡Fuerza magnética
Highlights
Electromagnetic induction is the ability of a magnetic field to create current inside a conductor.
Hans Christian Orsted demonstrated that electric current in a wire creates a magnetic field.
Michael Faraday investigated whether a magnetic field could produce electric current.
Faraday's apparatus used an electromagnet and a galvanometer to study electromagnetic induction.
Closing the switch in the circuit generates current, but it stops when the switch is opened.
Magnetic flux is the product of the magnetic field strength and the surface area perpendicular to the field.
A change in magnetic flux induces electric current in a conductor.
Doubling the magnetic field strength causes a change in magnetic flux and induces current.
Changing the surface area or angle of the conductor relative to the magnetic field also changes magnetic flux and induces current.
Electromagnetic induction has real-world applications in electricity generation and devices like generators and microphones.
A generator works by rotating wires in a magnetic field to induce current as the magnetic flux changes.
Increasing the magnetic field strength, surface area of the conductor, or angle of the conductor increases the magnetic flux and induced current.
Wrapping multiple wires together increases the magnetic flux and induced current in a generator.
A PHET simulation demonstrates how changing the position of a magnet relative to a wire induces current by changing magnetic flux.
In a generator, spinning a magnet changes the magnetic field and induces current in the wire as the magnetic flux changes.
Increasing the speed of the spinning magnet or the number of wires in the generator increases the induced current and energy output.
Generators in dams work by using the kinetic energy of flowing water to spin magnets and induce electricity through electromagnetic induction.
Transcripts
Hi. It’s Mr. Andersen and this AP Physics essentials video 71. It is on electromagnetic
induction which is the ability of a magnetic field to create current inside a conductor.
Now scientists like Hans Christian Orsted have already shown that if you have current
in a wire like this it creates a magnetic field. And that magnetic field could affect
this compass needle which is really a small little magnet. And so current can produce
magnetic fields. But what scientists like Michael Faraday wondered is could you take
a magnetic field and produce current from it? In other words was the opposite true?
And this is the apparatus that he used to study that. And so we have basically have
two parts. We have a ring of iron but on the left side we have an electromagnet. So you
are going to connect this to a batter and that is going to produce magnetic fields over
on the left side. And so the hope is on the right side, that could produce current inside
this wire. And then we would be able to measure that using a galvanometer. And so he set it
up like this and then he closed the switch. And so what what happens to the current in
the wire on the right side as I close that switch. And you can see that we generate a
little bit of current. But then it goes away. And this is puzzling. So he opened up the
switch and watched what happened. We have a little bit more current but it is in the
opposite direction. So let me kind of close that switch and we have a little bit of current.
But it goes away. And then we open the switch and we have a little bit of current but its
going in the other direction. And so that is electromagnetic induction. But what he
wondered is why is it only occurring right when I close the switch? So to understand
that you really have to understand the specifics of electromagnetic induction. And to understand
that you have to understand what magnetic flux is. Magnetic flux is how a conducting
material or any material for that matter is affected by a magnetic field. And so what
would be something similar? It would be how you or any material on our planet is affected
by light from the sun. And so it is going to be the amount of light from the sun. But
it is also going to be the angle at which that light hits. And so magnetic flux is going
to be the product of the strength of the magnetic field, how much or how large that magnetic
field is and then we are going to multiply that times the surface area perpendicular
to that magnetic field. And so imagine that this right down here is a wire loop. And so
we have a little bit of a wire. And then we have a magnetic field. And so if we ever have
change in that magnetic flux, then we are going to have electromagnetic induction occurring.
And so what happened right when he closed that circuit? Well the magnetic field before
he closed the circuit was zero. But then he added this magnetic field, so was there change
in magnetic flux? Yes. And so was there electromagnetic induction? Yes. So it created current. What
would happen if we were to increase the magnetic fields? So let’s double the magnetic field.
Well for a moment as we are doubling the electromagnetic field, are we getting a change in the magnetic
flux? Yes. Are we getting induction? Yes. And therefore we are going to have current
in that wire. And so by varying the amount of that magnetic field we can get induction,
or we can get current in that wire. Now what is another way we could go at that? Again
we could look at the surface area that we are impacting. And so if you think of this
as a wire, all of these magnetic field lines are perpendicular to this wire. And so we
are going to have a large magnetic flux. But watch what happens when I turn it at an angle.
And a good way to do this is simply count the lines of the magnetic field that it is
hitting. You can see there is a reduction. And so the number of lines is different but
also these are not hitting it straight on. It is not perpendicular so we would have to
use a little bit of trigonometry to figure out what component of that magnetic field
is actually perpendicular to the surface area. But did it change between those two rotations?
Yes. And so was there electromagnetic induction? Yes. And so there would be current as well.
And so let’s say we turn it like this. The magnetic flux is going to be zero because
none of these magnetic field lines are going to be perpendicular to the surface. But it
changed between those two points. And so we are going to have induction and we are going
to have current. So that seems a little non intuitive, but it has real world applications.
And so the electricity that you are using right now and the microphone that I am using
right now as well, use this idea of electromagnetic induction. And a great way to look at that
would just be looking through a generator. And so how does a generator work? Well in
a magnetic field what we can do is we can take these wires and we can start to rotate
them. And as we rotate them we are getting huge changes in magnetic flux and so we are
going to have huge changes in the current itself. And so if we look at the equation,
magnetic flux or phi sub B is going to be a product of the magnetic field, how big that
magnetic field is, times the cross-sectional area perpendicular to that magnetic field.
And so if I take this wire, right here and I compare it to this wire right here, which
one is going to have a larger magnetic flux? It is going to be the one on the left. And
the reason why is we are going to have more of those magnetic field lines go through it.
What is a good way that we could increase magnetic flux is we could just wrap that wire
a bunch. And so each of those wires, we are going to have the magnetic flux of that individual
wire. And so by changing the magnetic field or by changing the size of that area we can
change magnetic flux. But also remember we could angle it. And so if I angle it like
this, we are going to have fewer of those magnetic field lines go through it and so
we are going to get a change in the magnetic flux. And here we would actually have no magnetic
flux. But it is not a measure of magnetic flux that is important in producing current.
It is are we getting changes over time. And so this is a PHET simulation that gets at
that. And so we have magnet over on the left side. And then on the right side we simply
have a wire hooked up to a galvanometer or it is a voltmeter. It is going to measure
the amount of voltage. And you can see that there is no current right now. But as I start
to change that position of the magnet, I am starting to get current. And you can see,
you can even see the electrons moving in the wire. And so if I increase the number of wires
I can increase how much I am deflecting that needle. How much current I am actually moving
inside the wire itself. Why is that? Now the magnetic field lines, you can see the magnetic
field lines are changing. And as they change we are getting change in magnetic flux. And
so we are getting current inside the wire. Now another way to look at this would be through
a generator. And so in this set up what I have is a magnet down here on a wheel so that
I can spin that magnet. I have my wire again. And I am trying to induce current inside that
wire. And then I am going to measure the amount that I am going to change. And so watch what
happens now when I start to turn on the water inside that faucet. It is changing the position
of the magnet. As is it changes the position of the magnet it changes the magnetic field.
You can see the magnetic field lines are changing. And so I am starting to get a little bit of
current. What happens if I increase the speed of that water? I am getting more current.
You could even have a light bulb connected to it. And so now I am starting to get usable
energy. Watch what happens as I increase the number of wires. I even have more energy coming
out. Now if I increase the water again I even have more energy being produced. And so we
are taking that energy of the flow of the water and actually making electromagnetic
energy out of it. And so this is how the generators in a dam would work. We have the water flowing
down through the dam. It is spinning these magnets and it is creating that electricity.
And so did you learn to construct an explanation for how a simple electromagnetic device, like
a generator, works? I hope so. And I hope that was helpful.
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