Last Updated on March 31, 2024 by Francis
Electricity Through the Same Crystals That They Squeeze by vibrating Back and Forth
I’ve found that one of the most powerful methods to convert energy is to use the same crystal system to produce electricity.
It seems that nature has a way of making things unique, not only in quality but in form.
Some of the best examples are when you see different flowers or different colors of leaves.
Nature is so unique that the energy produced is very specific, from the movement of a pinhead to the energy produced from a bug bite.
This makes it possible for us to use this to create and harness electricity, instead of burning coal and creating harmful gasses.
Squeeze Quartz Crystals Make Electricity Flow Through Them Like Any Other Type of Crystal
Squeeze quartz crystals make electricity flow through them just like any other type of crystal.
Squeeze crystals are quartz beads that are in the shape of a wedge.
All crystals have electrical charges even though they may not be made of pure crystal.
The same is true for these tiny beads. They are essentially just very thin layers of silicon dioxide.
Once you place them in a metal like an automobile battery, they create an electric current.
These small beads when charged up create an electric pulse which is sent to the battery.
Since they are so thin, they charge up to full capacity before they need to be discharged.
- As the battery is charging, the silicon dioxide spheres stay charged up until the battery is completely full.
- When it is time to recharge the battery, the electric current that the battery is creating is sent to the device and it charges the device all over again.
- To understand why this is possible, you need to know how electricity flows through conductors.
- The smaller beads are traveling along the surface area of the device and become charged when they contact an electric field.
Once they get to a conductive surface, they lose their charge because there is no longer a large surface area to give them an electric field.
Once they are charged up again, the crystals send the same electric pulse down the wire to the battery and it charges the battery all over again.
Piezoelectricity: What Does It Mean?
Piezoelectricity occurs when a crystal’s electrical charge imparts an energy gradient which causes an imbalance in the field that exists around it.
In order for this process to occur, the energy gradient must be both zero and uniform.
As stated by The Curie Brothers in 1880, “A uniform energy distribution in the face of the crystal is called geometrical equilibrium.”
The reason why Piezoelectric objects use crystals to create a source of constant current is due to the use of electric field to induce motion into a crystal.
It should be noted that the term Piezoelectric does not mean “piezoelectric force” but rather is a synonym for “energetic charge.”
This method is very similar to the concept of Capacitive bonding in which two dissimilar metals with similar electrical charges but different densities are bonded together by using an applied force.
The difference is that instead of applying force to the metals, they are attracted by their own properties which results in a net charge.
The exact process which generates a net charge is complicated and remains a mystery to modern science, but is also commonly known as a piezoelectric effect.
The effects of piezoelectricity are most noticeable at small voltages where the dissimilar metals do not have enough charge to act in a typical manner.
In fact, the smallest voltages where this effect is apparent is around twenty nanometers.
The smaller areas within a crystal or gemstone that is occupied by crystals makes this phenomenon more pronounced.
Many different varieties of gemstones contain measurable amounts of piezoelectric energy.
Some examples of gemstones are rubies, sapphires, tanzanites, and amethyst.
How Gramophone Would Have Been Using Piezoelectricity to Read the Sounds From LP Records
Gramophone would have been using piezoelectricity to read the vibrations of LP records.
This is because the original gramophone from the eighteenth century was using a pendulum to strike the tonal sounds.
The tonal sounds would then resonate the metal plates inside the gramophone which would then generate a sound.
This would be the basic concept of a gramophone and it did help the gramophone manufacturers.
However, the use of a pendulum caused another problem as it was difficult to tune and adjust to varying conditions and music styles.
As a solution to this, gramophones from the nineteenth century onwards started incorporating spring systems that would then allow them to more finely tune the tonal vibrations.
This system would also help the gramophone reproduce the music with a more uniform tone.
Finally, the technology used in the twentieth century brought about the development of the solid state gramophone which is commonly known as a rotary valve gramophone.
The main difference between a rotary valve gramophone and the gramophone of the past is that the latter incorporates a diaphragm which allows it to produce a lower and higher pitch.
This would in effect allow for more flexibility when creating music.
Today, these gramophones are used by most music scholars as they help create the correct pitch necessary for compositions.
What Keeps Quartz Watch Piezoelectricity Regular Time?
The first quartz watch was the Astron made by Seiko unveiled on December 25, 1969 which was a huge step forward for quartz watch technology.
It had many innovative features like a stopwatch, calculator and thermometer.
The quartz watch piezoelectricity is what helps it keep regular time. It uses an energy source to generate its quartz crystals and give them motion.
Quartz crystal has the ability to move when a varying current passes through it.
When the current doesn’t pass through it stays in its place and doesn’t generate any power, but when it passes through it emits tiny bits of electric charge which are detected by sensors in the case and send the signal to the receiver in the form of a signal.
This is how a quartz watch works, and what keeps regular time.
This ability to stay still while it receives signals from different sensors makes it very efficient and valuable as a timepiece.
A quartz watch also has some unique properties.
It can be tuned by simply reversing the polarity of the quartz crystals that generate the motion.
This is why some people refer to quartz watches as time machines. In other words, it shows how unique and advanced these little devices are.
How Piezoelectric Material Produces Electrical Current by Stimulating Motion?
Piezoelectric material is one of the ways to create a magnetic field that produces electricity, it has been around for a long time however recent advances in technology have made this material more efficient and useful.
When piezoelectric materials are used they create an induced current, they have very strong electric fields that are able to change the shape of the material that they are attached too.
How Piezoelectric Material Produces Electrical Current by Stimulating Motion?
Piezoelectric material is one of the ways to create a magnetic field that produces electricity, it has been around for a long time however recent advances in technology have made this material more efficient and useful.
When piezoelectric materials are used they create an induced current, they have very strong electric fields that are able to change the shape of the material that they are attached too.
Piezoelectric material has a lot of potential when it comes to use in electrical engineering because it can be made more efficient and more powerful with just a little change in the structure.
By making the thin layer thicker you can use less material to get the same amount of energy produced.
This allows for smaller devices that require less power to function.
Also by designing the material to have a backface chiasm you can get much more energy than is possible with other systems.
This type of system can be used to produce and transfer the energy to a discharge that is a much smaller amount then the size of the device itself allowing the device to have a smaller footprint on the Earth.
Piezoelectric Crystal As Currents to the Load and You’re Left Without Power
A few months ago I was talking to someone who had recently built their own solar panel and they were using a Piezo Crystal for the solenoid in their system.
You see, there is something to be said for the DIY enthusiast and his or her ability to do things on their own and if you can build something as intricate as a solar panel then you should really consider it.
However, if you’re like me and your not so up to speed on the latest and greatest, you can leave it to the pros and their piezoelectric crystal current supplies.
The thing is; there’s a lot of hype out there about these things and you have to make sure that you’re getting the right supply for the right job.
What Is a Piezo Crystal and How Can It Help Me?
You will find that some people like to use the piezoelectric crystal for different purposes.
For example some use it to make a magnetic motor which moves a magnet from one position to another by passing a current through it.
The power from this is very small but very effective.
There is one very interesting application of the piezoelectric crystal. This is in the context of healing your body.
Some Chinese people believe that by placing the crystal over a certain spot on your body you can correct any imbalances you might have in it.
By placing the crystal over certain places you can change the flow of qi in your body.
This will not only enable you to heal your body, it will also remove any blockages that are preventing you from getting well.
Once you connect a load there is a little bit of trial and error involved.
You will have to try several different applications of the piezoelectric crystal until you find the right one for you.
Do not be disappointed if you do not see results right away. This is a process that takes time. If you persist, you will see results.
Understanding the Press Piezoelectric Crystal
A press piezoelectric crystal can be manufactured by bonding lightweight copper wire to an electric generator.
This process is known as induction and works through a simple principle.
To achieve induction a wire is bent into the shape of a cone and connected to a generator.
A loop is formed around the copper wire, this loop when applied to a metallic surface forms a periodic electromagnetic field that is converted into electrical energy.
The induced electric field produced will then produce a motion in the metal causing the wire to deform into a peak and a valley.
A permanent magnet is formed when the induced field pushes on the surface of the object the permanent magnet is attracted to and it becomes a deformed crystal.
Press piezoelectric crystals will be useful for applications where mechanical isolation is required.
A thin metal plate is used to build a partial electric field that acts as a directional filter for the induction.
The plate may need to be extremely thin to reduce the induced field to a low level and the desired results can be achieved.
This is also a useful application where a large number of charge separation paths are required.
To a layman this may seem to be very complicated and even go against current science.
To a scientific research laboratory this may sound very confusing and the answer may not be clear to everyone.
To a professional researcher working in a laboratory that uses controlled exposure to a controlled voltage and current it is very simple and easy to understand.
If you are in need of a new press piezoelectric crystal it will get deformed and the charges will get separated and it will perform better than ever.
How Do Piezoelectric Crystals Produce Music?
Many people have asked me this question, is a Piezoelectric Crystal used in an amplifier, it wouldn’t produce power when held pressed?
The reason I ask this is because when we take a look at the output from such a device, we would see that the current (Amplitude) and the Current (amplitude) are inversed.
We can observe this if we use a white. If we placed the two ends of a skinny wire onto the bottom and top of the white (made out of a barium copper wire), and we then pushed the wire down into a hole, we would see that the current would cancel out the power supplied to the white, and it would only create a small amount of voltage.
The same principle is used in a Piezo Crystal when we find its wouldn’t produce power when held pressed, we would find that the current would be reversed.
Now if we place this kind of crystal next to some conductive material, say some glass, we would then find that the current would be inserted between the glass and the thin film.
If we leave this material alone, we would notice that the current would get stronger as time goes on.
So the current would be inversed between the crystal and the conductive material, it is this current that is used to produce the vibrations that we hear when playing the guitar etc.
In fact these crystals were invented by accident, and after some time they were found to be useful, they were used to stabilise the pitch of the voice and for the first time there was a sense of musicality to music.
If you study this subject, you would see that the real genius of the Piezoelectric crystal lies in the fact that the device allows for infinite variation in the time it functions.
In fact they have been used in so many ways that they are now almost obsolete, as people use them in so many ways they tend to lose their power, this is why nowadays you would find them being used as telephones.
Also they can be used to transmit signals etc. If we look at them from a slightly different angle, you would see that they play themselves without any outside influence, that is to say they don’t need any batteries to operate, unlike conventional generators which need to be kept charged.
This is probably why the engineers designing new devices keep an eye on this aspect, as the future holds many possibilities and as long as the Piezoelectric crystal is around we would see that future.
Electrical Equivalent Model
The electrical equivalent of a piezoelectric crystal has a high DC resistance (impedance), which will prevent it from picking up enough energy to be an effective power source.
However, a thin film can be placed over the crystal and this can be bonded into a thin film electrical coating, which is then formed into a solid piece of silicon called a wafer.
Silicon is very good at conducting electricity so this coating is very thin and the thin film acts like a very thick insulator.
This insulator is able to reduce the energy transfer through the crystal because the current cannot travel through it and only comes through the top of the wafer where the crystal has been deposited.
Silicon can be used in many different types of applications to improve the electrical transfer and also to reduce the resistance.
If you are wondering what this means for electrical equivalent modeling, then it basically means that if you were to use a solenoid as a charge controller you could control the amount of current flowing through the circuit.
You would do this by varying the thickness of the coating on the wafer and the current flowing through it.
This can dramatically reduce the voltage drop across the device.
You will be able to control the current passing through the electrical equivalent of a Piezo electric crystal by varying the thickness of the layers and the current through it.
So why is the electrical equivalent of a Piezo crystal used in electrical engineering? The reason is pretty simple actually, and it’s all to do with cost.
The large bulk of crystals used as electrical insulators can be rather expensive to produce (by orders of magnitude) and the wafer manufacturing process itself is very inefficient and wasteful.
However, as the efficiency of manufacturing improves the cost of the crystals decreases and we can start to reuse these crystals to provide a very cost effective solution.
So although electrical equivalent modeling may not be something that you’re immediately going to want to get into, it is something that will more than likely become necessary in the near future and we could all see an increased dependence on these types of electrical equivalent models in the future.
How Much Do Piezoelectric Crystals Cost?
How much do piezoelectric crystals cost?
Piezo materials are made of pure silica, magnetized, and/or coated graphite or silica sand.
It is a silica crystal that contains a hyperlink neighbor, a quartz crystal that has impurities that change its electronic properties by causing an excess of dipoles, a hydrophobic crystal that changes the electrical charge of the substrate, a metal oxide coating that inhibit impurities from coming in contact with the crystal, and an ionic gas that change the electrical charge of the substrate to a higher level.
Piezo material is used in applications where the crystal will be shaped by mechanical forces, compressed in a container to form a ring, and passed through an electric arc to create an arc beam which will cut shapes in an appropriate fashion.
It is a versatile material and has many uses.
The amount of energy needed to form the best quality of the crystal depends on the thickness of the crystalline silica.
Since thin crystalline silica contains less silicon dioxide than thick crystalline silica the energy needed to form the best quality of slice is lower.
The second major benefit derived from how much do piezoelectric crystals cost is the development of a giant covalent structure around the crystal, which allows it to generate electricity.
The silicon dioxide in the crystal is excited by an electric field and splits into three separate photons, which are then reflected back into the machine.
The electricity generated by the structure is used to drive a current through an array of electrodes.
This current drives a millimeter-sized piece of ribbon through a wire grid, which in turn sends the signal into a device such as a computer or a digital LED display.
Once the signal reaches its destination, the computer or display converts the analog signal to a digital signal, which can then be read and manipulated by the appropriate software programs.
Do Piezoelectric Crystals Vibrate?
Piezoelectric crystals are objects that create a small amount of friction between two points by the use of a piezoelectric material.
These are generally found within an environment that has a small amount of kinetic energy such as the ocean or an outer space satellite.
When the energy is spread out over a larger surface area than the frequency of this vibration will increase as the Doppler effect takes place.
In reality, when we hear a small ripple on water or a rock we can actually see the Doppler effect taking place with the slight displacement of the object.
Many think that the use of a crystal could enable them to have more energy and thus power up their home appliances, thus eliminating the need for electricity.
It is thought that by using the Doppler effect we can transfer this energy to other items to power them up.
When we use the Doppler effect we can also transfer the energy from a crystal through a filament and into an electrical generator.
This would be especially beneficial as our power supply would no longer rely on fossil fuels and nuclear energy, which cost a fortune to produce.
However the question still remains – do piezoelectric crystals vibrate?
This can best be answered by those brilliant scientists that created the very first piezoelectric crystal.
They were astonished by how these crystals resonated and were able to detect the frequency of the vibration by placing them next to an ultrasonic sensor.
Although this technology is no longer in use today the Doppler effect and other types of piezoelectric devices are still around and used by many scientific organisations in the World.
The Doppler effect and other types of piezoelectric devices are still used today for a wide range of scientific and research purposes.
Piezoelectric Technology
The piezoelectric effect is related to the natural piezoelectric properties of crystals. It shows in nature when a crystal separates from its companion crystal when stimulated with an alternating electric current.
This effect can be seen not only in Nature but in laboratory experiments too. Researchers have observed the effect in diamond, silicon carbide, boron, phosphorus and other alloys.
The quartz crystals are among the most studied due to their piezoelectric properties.
In most cases a crystal will cut or fracture when mechanical stress is applied on it.
As the crystal grows, the stresses grow too, until the crystal breaks or becomes unstable.
The piezoelectric effect shows that when the crystal grows to fill the surrounding space, the stresses cause the crystal to grow in size until it becomes the same size as the surrounding area – this is called “piezoelectric effect”.
The size of the crystal determines its electrical and mechanical properties.
To demonstrate the piezoelectric effect it is important to have a crystal that is perfectly spherical with opposite sides having identical heights and diameters.
Then place a weight on the crystal; note the amount of stress that is placed on the crystal while it grows or shrinks or the amount that is lost when the crystal becomes smaller or larger than the weight.
The results are a predetermined correction that makes the crystal become the size of the weight without causing damage.
Using these techniques you can build up quite a large amount of voltage which you can hook up to your cars battery to power it.
Piezoelectricity – Why Is It Important?
Piezoelectricity is also used in spark lighters for barbecues and gas stoves, however not much attention is paid to the device by most folks.
There are a couple of reasons why; firstly it’s not all that easy to source a sparkler ignition source that works perfectly in your type of piezo device.
Also there are a lot of problems associated with piezoelectricity which you really need to know about before you start messing around with the controls on your sparkler.
The fact is that many folks do not give a crap about piezoelectricity but only care about the light aspect of the device.
It’s really the type of light that produces a spark that determines how well your device will function.
Without sufficient amount of sparkle your device will never ignite properly and will never burn down wood efficiently.
Piezoelectricity is defined as any electric charge present in a material that is electrically charged, this is different from electromagnetic charge which is present in all kinds of light sources.
In simple terms you can say that all light is piezoelectric in nature.
This is the principle behind the ignition of your device and the reason why a sparkler always works so beautifully.
The spark is created because the charge in your pyro device is just right when ignition is found.
If you have a lighter without piezoelectricity you would just get a long drawn out constant stream of colorful sparks rather than the beautiful blue white flame that we all recognize as the sign of a good pyrotechnic.
All in all piezoelectricity is very important to your lighting system. It’s just that most folks don’t give it much thought.
Piezo Electronics – A Typical Piezo Transducer
If you have no idea what a piezoelectric transducer is, it is a transducer that uses sound waves in order to produce an electric output.
It is used for a variety of applications and is quite popular for two reasons.
The first reason being that it is very easy to use and the second reason being that it can be controlled and fined tuned as needed. You can easily fine tune this type of transducers by tuning the transmitter.
You need to make sure that the frequency of the signal produced is near the threshold frequency of the transducer. If it is too high then you won’t get the output and if it is too low then you won’t get any output at all.
The second common application for a piezoelectric transducer is in the medical industry.
In fact, I won’t be surprised if I were to tell you that there are hospitals and clinics that use this technology every day.
You name it, they’ve probably had it work for you. For example, here is a common problem that they have to deal with on a daily basis.
They have a patient that is unresponsive to their standard IV procedures such as IV Vitamin D and/or Acupuncture.
They use a piezoelectric transducer to determine the exact reason why this person is unresponsive.
What Are the Charges in a Piezo Crystal?
The typical charges in a Piezo Crystal are also known as polarity charges, and normally there is a slightly negative polarity charge on each face.
These charges actually balance out to give the crystal its normal attractive look.
Although the negative polarity of this particular crystal is unique to this material, the positive charge is normal for most crystals.
Generally the polarity of a crystal will depend on its atomic or molecular structure.
When a new crystal is synthesized, the crystal structures are altered slightly.
This is usually done by adding or removing some of the existing element, or bonding them with some other element.
Once this has been done, the crystal is usually grown by passing it through a chemical process, such as heating.
This produces heat that shifts the atoms around, which changes their position and ultimately causes a charge.
Piezo Crystals are used for many different purposes, not just music.
They can be used to make medical equipment, such as heart monitors.
These are useful in that they do not alter the way that the device functions, but rather they provide an extra source of current, making the device run more efficiently and thus save battery power.
Also, these crystals make very sensitive instruments work more accurately, and can help to prevent errors when instruments are run at high speeds.
They are used to create clocks that run at different times around the world, and can also help to create artificial intelligence units.
