TruthArchive.ai - Tweets Saved By @dr_parkinstine
@dr_parkinstine - dr.parkinstine
The key to the universe explained by me. Enjoy 🙂 good vibes 😉 https://t.co/6YHaknO59B
Video Transcript AI Summary
In this video, the speaker explains how everything can be manipulated with frequency. They give examples such as an opera singer shattering a glass at its resonant frequency and tuning forks making each other vibrate without touching. The speaker also discusses how radio waves are a form of alternating current and how wavelength can be converted into frequency. They demonstrate an experiment using a diathermy machine and a coil to show the effects of frequency. The speaker concludes by mentioning Nikola Tesla's quote about energy, frequency, and vibration being the key to the universe.
Full Transcript
Speaker 0: Okay. Today, I'm going to explain how everything can be manipulated with frequency. So in one of my previous videos, somebody said that's so crazy. You can send electricity if it's tuned correctly. And my response to them was you can actually manipulate anything you want with frequency.
So now I'll go ahead and show that comment So now I'm going to explain what I mean by this. So we have atoms and molecules making up everything. So atoms are positive and negative charges, protons, neutrons, electrons, which means they're electricity because charges electricity, so everything, therefore, is electricity. So electricity, It's D. Unless it's direct current, it vibrates in some way.
So that means it has a frequency. So everything must have a frequency. So proof of this concept is, for example, an opera singer will sing and shatter a glass at its resonant frequency if they sing at the right frequency and the right amplitude. They can shatter the glass. Another example, if we have 2 tuning forks tuned identical to each other, are made identical to each other.
Like, for example, we have 2 tuning forks of the frequency 432 hertz, and we hit 1 of them and 1 is right next to it. We can make the other one vibrate without even touching it. That's just a few examples. Another good example of frequency is say you're wanting to listen to an AM radio station. Let's just say AM for now, amplitude modulation.
Say you're wanting to tune into 1,000 kilocycles or 1,000 kilohertz. Do you know what that kilohertz means? It means 1,000 Hertz. So Hertz is, well, for example, your, house current is 60 Hertz. If you live in the US.
Another good example of this is radio. So say you're wanting to listen to AM, amplitude modulation, which means it's modulating the amplitude of a wave. But anyway, so say you're wanting to listen to 1,000 kilocycles or 1,000 kilohertz. Well, kilohertz means 1,000 hertz. So anyway, that's a frequency.
So, Okay. So 1,000 kilohertz would be roughly 1,000,000 hertz because you do a 1000 times a 1000 because killer cycles and there's already a 1,000 in front of it. So that'd be 1,000,000 Hertz. So say you wanna listen to that radio session where you're tuning into a frequency. So the, So in order to tune in to the frequency you want with radios and stuff, you use what's called an LC circuit or tank circuit.
Now I'll show you the definition of an LC c circuit, but it basically means an inductance capacitance circuit. Okay. Now I'm going to share something very interesting. So our power grid, from the the municipal generators all the way to our house, pretty much everything in the US, to get electricity to our house, and what we use is 60 hertz. So 60 hertz alternating current.
Did you know that radio waves or radio frequency or RF, whatever you wanna call it, the stuff that goes from your broadcast station to your radios, The stuff you listen to on your radios, he's actually alternating current as well. When alternating current reaches a frequency of between 20,000 Hertz and 300 Gigahertz is considered RF or radio frequency. So, yes, you're listening to wireless electricity on your radios. It's not the most efficient way to do it, but it works. There is more efficient ways to do this.
So here's another interesting fact. Did you know that we see in wavelengths and light is in wavelengths? There's plenty of other examples of wavelengths, but did you know that wavelength can be converted into frequency? Now I'm going to show you an interesting demonstration. So here I have a diathermy machine, it's from the 19 thirties.
I've already plugged it in. So it's using 60 hertz alternating current. It uses a 110 volts at 6 amps, so roughly 6 50 watts of electricity. Anyway. Okay.
Now I'm going to do my demonstration. I'm actually going to be setting out all this music stand so that it doesn't interfere with my phone. Also, before I do this demonstration, I would like to tell you what's going on. Okay. So first, I will attach a metal object to the cauterizing terminal on the diathermy machine, and you will observe that there are only about an inch long sparks.
Then, after I do that, I will connect this coil to that cauterizing terminal, the bottom of this coil I round, which by the way, this coil is wound up to a fourth of the wavelength of the frequency coming out of this diathermy machine. The frequency on this diathermy machine It's about 29 megacycles. So this is a 4th wavelength of 29 megacycles. So this will act like as a guide, basically for the electricity. So I have wound this coil to a fourth of the wavelength of 29 megacycles.
This works best with this situation, actually with this situation, a half wavelength, a full wavelength and a quarter wavelength work best in this scenario right here. But if you're doing something else with frequency, like Say you're not dealing with this electricity like this. You might find other wavelengths that work better. Okay. Now we'll do the demonstration with the phone on this Music stand right here.
So this hopefully won't interfere with the phone. Okay. Here I have a knife. I'm going to turn this on and observe the inch long sparks. Then I will connect the coil and then observe the sparks.
Okay. Now, I'm going to connect the coil. And I've added this little metal thing on the top. This acts as a capacitor to tune this as well. Okay.
Let's connect this. Okay. It's connected. I hope it's here. Let me bring y'all in to see if I can let you.
Okay. There it is. I'm not gonna flip my camera because it'll stop the video and I don't want to. Anyway, there's the connection. That's the only connection.
Okay. Let me put the phone back in here. Now watch this. Now that was just one example of what you can do with 1 certain frequency. Now with the right combinations of frequencies or the right frequency or the right combination of frequency and harmonics, Anything is possible, and that's what Tesla means.
Nikola Tesla means by his quote. The key to the universe is energy, frequency, and vibration.
@dr_parkinstine - dr.parkinstine
Working on the magnifying transmitter again 11-12-23. Enjoy 🙂 https://t.co/fbIB6rvTtg
Video Transcript AI Summary
Today, I will be demonstrating the magnifying transmitter. The extra coil is off by about 50 kilocycles, so it's not resonating at the right frequency. The signal generator generates the signal that goes into the extra coil, similar to the small coil that lights the fluorescent bulb. I show the coil and the signal generator, and when I bring the coil close, it detunes it. I can adjust the voltage, but the tuning becomes picky at lower voltages. I can relight the bulb by touching it. The extra coil needs to be rewound, but once it's tuned to the right frequency, it will work perfectly. I also demonstrate a coil that is not well-tuned and show the sparks. The magnifying transmitter does not interrupt electronics and you can still hear my voice.
Full Transcript
Speaker 0: Okay. Today, I'm going to be running the magnifying transmitter. It's a little bit chilly, so I might grab my coat. So here is the magnifying transmitter, and there is the extra coil or the center coil the 3rd coil. Think of the extra coil like that coil that I used to light that fluorescent light bulb on 20 volts.
I'll go show you all that coil right now. So keep in mind, the extra coil is off by about 50 kilocycles, give or take. So it is not resonating at the right frequency. And, actually, one more thing before I show y'all that coil that lights the 1st on 20 volts. The outer coils is secondary right there, and the primary and all this are a signal generator, basically.
So this is generating the signal that goes into the extra coil and vibrates back and forth between the ground and the extra The coil. See the bottom of this let's just call this whole core right here a signal generator. The bottom of it goes right there to the ground. See? That's not an ideal ground, though, because it's very tiny.
And, ideally, you want ground points along all these posts at the bottom. But this We'll be generating the signal that goes into the extra coil just like the signal generator generates the signal for that small coil That's lighting the little fluorescent bulb on 20 volts. Now I will show you all that coil. So here is that coil, and there is my signal generator. Instead of the primary and secondary feeding the extra coil in this case, I'm feeding it with a signal generator at its resonant frequency.
And observe this 1st well, let me turn off the living room light. Oh, and I guess the dining room. So we are currently at my dad's house, not my apartment, visiting my dad. There is the fluorescent bomb, And if you look closely, you can see the waves traveling in there. See the waves?
And when I come close to this, it detunes it. And I can also pick these up. If I move it too far, it'll go out, and you have to relight it like a candle. And if the frequency gets off, let's just watch this. Okay.
So that's Let's do off by, 0.1 megacycle. See? Now I go back. Okay. That's that's back on the tuning of this resonant frequency of this coil.
Now I just have to touch it to get it going or move it back here. There we go. Oops. Hang on. Okay.
Anyway, there it is again. And I can turn down the voltage. So this is 20 volts. The video cut when I was trying to dial down the voltage. We're gonna try to go down to 8 volts.
It may cut off the bulb because the tuning becomes very picky at 8 volts. Okay. That is 10 11 10 volts right there. 9 volts. That is 9 volts.
It's gonna go out at 8, it looks like. Let me bring my hand near the oh, see. You can see my hand is detuning it when I get near it. Oh, I just extinguished it. Let's turn up the voltage and relight it.
Okay. That's 20 volts again. 19, 18, 17, 16, 15, 14, 13, 12, 11, 10, 9. That was 8. See, the tuning comes very picky.
Just touch it to reline it. Okay. I'll show y'all me dialing it down to 9 volts. It's 9 volts. Okay.
I'm kind of helping tune the coil at this point, but this is 7 volts Right there. See? You can see the 7 volt input. If I go down, lower, it'll, turn off, But I am helping tune the coil by holding this light bulb. And I just moved it too far away, and it went out.
But, I'll put it back there, we'll turn it back up to 20 volts, and I will touch the light bulb to that, and it lights up again. There it is. So think of this like that extra coil and that big giant contraption outside, and the signal generator Was replaced outside with those, coil that coil wire along the outside and the tape circuit. That's generating our signal now, So keep that in mind when you look at this now. So now you can probably see that.
The extra coil, however, needs to be rewound because it's off, as I said. But once it's, it has the right frequency. Once it's tuned to the right frequency and this is supplying that frequency, then, yes, it will work perfectly. And it already has worked to transmit electricity 918 miles to my friend in Chicago, but the extra coil didn't really have that much to do with it. It's mainly the signal generator part right there, but imagine it with the extra coil.
Straight shit. I'm gonna take this galvanized nail, and I'm gonna bring this coil over here. This coil is not tuned as well. It's far off on the tuning, but here it is. I'm gonna set this coil well let's actually set it right here.
Right right here. This where the ground is level. Now I'm going to take the bottom wire on this corner right here. I can't see it, but I'm gonna wrap it Around this nail, I'll show y'all in a minute, with it zoomed in. I'm just gonna put this nail right in the ground over here.
The ground is kinda wet. It's a little bit chilly, so I might grab my Coke. Okay. Now I'm going to fire up the magnifying transmitter. Keep in mind that that coil is not in tune.
It's like trying to pick up a radio station and you're a certain radio station and you're tuned in to a whole different radio station. Okay. See those little sparks? Let's adjust our rotary spark. Okay.
Things should go smoother now. I've adjusted the rotary spark gap. And, actually, if I can find it, I have a little here it is. This little baby neon light bulb right here, And this will show it better than it's sparking to my hand. It'll catch on in a minute.
The rotor is parked up, I guess. Let's make one more adjustment. Okay. I've adjusted the spark again. This should be okay.
The adjustment is okay now. Notice you can still hear me talking. Most people think With a Tesla coil or magnifying transmitter, it will interrupt the video and stuff, and you won't be able to have electronics near it. That's not the case. You can hear my voice right now.
Anyway and here's the receiving coil. See? I'm picking up the electricity right in front of me. It's a little bit chilly, so I might grab my coat. But it's right there.
Okay. I've adjusted the coil a little better. We'll have a spark gap. Now I'm gonna go fire
@dr_parkinstine - dr.parkinstine
Working on the magnifying transmitter again 11-12-23. Enjoy 🙂 https://t.co/fbIB6rvTtg
Video Transcript AI Summary
In this video, the speaker demonstrates the magnifying transmitter and its components. They show the extra coil, which is not resonating at the right frequency, and explain how the signal generator generates the signal for the coil. The speaker then shows a coil that lights up a fluorescent bulb and adjusts the voltage to demonstrate the tuning of the coil. They mention that the extra coil needs to be rewound for it to work properly. The speaker also shows another coil and demonstrates the sparks produced by the magnifying transmitter. They mention that the transmitter does not interrupt electronics and show a receiving coil picking up electricity.
Full Transcript
Speaker 0: Okay. Today, I'm going to be running the magnifying transmitter. It's a little bit chilly, so I might grab my coat. So here is the magnifying transmitter, and there is the extra coil or the center coil the 3rd coil. Think of the extra coil like that coil that I used to light that fluorescent light bulb on 20 volts.
I'll go show you all that coil right now. So keep in mind, the extra coil is off by about 50 kilocycles, give or take. So it is not resonating at the right frequency. And, actually, one more thing before I show y'all that coil that lights the 1st on 20 volts. The outer coils is secondary right there, and the primary and all this are a signal generator, basically.
So this is generating the signal that goes into the extra coil and vibrates back and forth between the ground and the extra The coil. See the bottom of this let's just call this whole core right here a signal generator. The bottom of it goes right there to the ground. See? That's not an ideal ground, though, because it's very tiny.
And, ideally, you want ground points along all these posts at the bottom. But this We'll be generating the signal that goes into the extra coil just like the signal generator generates the signal for that small coil That's lighting the little fluorescent bulb on 20 volts. Now I will show you all that coil. So here is that coil, and there is my signal generator. Instead of the primary and secondary feeding the extra coil in this case, I'm feeding it with a signal generator at its resonant frequency.
And observe this 1st well, let me turn off the living room light. Oh, and I guess the dining room. So we are currently at my dad's house, not my apartment, visiting my dad. There is the fluorescent bomb, And if you look closely, you can see the waves traveling in there. See the waves?
And when I come close to this, it detunes it. And I can also pick these up. If I move it too far, it'll go out, and you have to relight it like a candle. And if the frequency gets off, let's just watch this. Okay.
So that's Let's do off by, 0.1 megacycle. See? Now I go back. Okay. That's that's back on the tuning of this resonant frequency of this coil.
Now I just have to touch it to get it going or move it back here. There we go. Oops. Hang on. Okay.
Anyway, there it is again. And I can turn down the voltage. So this is 20 volts. The video cut when I was trying to dial down the voltage. We're gonna try to go down to 8 volts.
It may cut off the bulb because the tuning becomes very picky at 8 volts. Okay. That is 10 11 10 volts right there. 9 volts. That is 9 volts.
It's gonna go out at 8, it looks like. Let me bring my hand near the oh, see. You can see my hand is detuning it when I get near it. Oh, I just extinguished it. Let's turn up the voltage and relight it.
Okay. That's 20 volts again. 19, 18, 17, 16, 15, 14, 13, 12, 11, 10, 9. That was 8. See, the tuning comes very picky.
Just touch it to reline it. Okay. I'll show y'all me dialing it down to 9 volts. It's 9 volts. Okay.
I'm kind of helping tune the coil at this point, but this is 7 volts Right there. See? You can see the 7 volt input. If I go down, lower, it'll, turn off, But I am helping tune the coil by holding this light bulb. And I just moved it too far away, and it went out.
But, I'll put it back there, we'll turn it back up to 20 volts, and I will touch the light bulb to that, and it lights up again. There it is. So think of this like that extra coil and that big giant contraption outside, and the signal generator Was replaced outside with those, coil that coil wire along the outside and the tape circuit. That's generating our signal now, So keep that in mind when you look at this now. So now you can probably see that.
The extra coil, however, needs to be rewound because it's off, as I said. But once it's, it has the right frequency. Once it's tuned to the right frequency and this is supplying that frequency, then, yes, it will work perfectly. And it already has worked to transmit electricity 918 miles to my friend in Chicago, but the extra coil didn't really have that much to do with it. It's mainly the signal generator part right there, but imagine it with the extra coil.
Straight shit. I'm gonna take this galvanized nail, and I'm gonna bring this coil over here. This coil is not tuned as well. It's far off on the tuning, but here it is. I'm gonna set this coil well let's actually set it right here.
Right right here. This where the ground is level. Now I'm going to take the bottom wire on this corner right here. I can't see it, but I'm gonna wrap it Around this nail, I'll show y'all in a minute, with it zoomed in. I'm just gonna put this nail right in the ground over here.
The ground is kinda wet. It's a little bit chilly, so I might grab my Coke. Okay. Now I'm going to fire up the magnifying transmitter. Keep in mind that that coil is not in tune.
It's like trying to pick up a radio station and you're a certain radio station and you're tuned in to a whole different radio station. Okay. See those little sparks? Let's adjust our rotary spark. Okay.
Things should go smoother now. I've adjusted the rotary spark gap. And, actually, if I can find it, I have a little here it is. This little baby neon light bulb right here, And this will show it better than it's sparking to my hand. It'll catch on in a minute.
The rotor is parked up, I guess. Let's make one more adjustment. Okay. I've adjusted the spark again. This should be okay.
The adjustment is okay now. Notice you can still hear me talking. Most people think With a Tesla coil or magnifying transmitter, it will interrupt the video and stuff, and you won't be able to have electronics near it. That's not the case. You can hear my voice right now.
Anyway and here's the receiving coil. See? I'm picking up the electricity right in front of me. It's a little bit chilly, so I might grab my coat. But it's right there.
Okay. I've adjusted the coil a little better. We'll have a spark gap. Now I'm gonna go fire
@dr_parkinstine - dr.parkinstine
Making 100+ year old batteries work again without re stuffing them. Enjoy 🙂 https://t.co/ABWQqf7XUH
Video Transcript AI Summary
In this video, the speaker demonstrates how to restore the charge in old batteries. They show a wireless coil and explain how alternating current works. They then proceed to wire the batteries in series and test them with LEDs. The speaker mentions the use of ammonia hydroxide and demonstrates how to poke holes in the battery casing. They fill a container with ammonia and place the batteries inside. After adding the ammonia, the LEDs become brighter. The speaker concludes by showing the improved performance of the batteries.
Full Transcript
Speaker 0: Okay. Today, I'm going to be restoring the charge in these 100 plus Euro batteries. This is a rail back battery. It's from it's definitely from before 1950. Anyway, there is a simple process to go about to restore the charge in these old batteries.
So before I begin, restoring the charge in those old dry cells, I wanted to show y'all. This is from the previous 2 TikToks. This is the little wireless coil thing. See when I get close, it detunes it. Anyway, you can see the lines of alternating current in there.
As I say, alternating current vibrates back and forth. You can literally see it doing that right now. And, At a certain point, you can see it like waves and water. You can see it vibrating back and forth like a piston right there, and then it looks like the waves and water that way, and the same thing's happening over there. Oh, whoops.
I touched it. Here, let me rewrite that side. Okay. See if I touch this side, the other side just will go out. See?
Anyway, you can see it vibrating if you really look hard. See? Okay. That's been going all day. I had that set it, that that calls resonant frequency, and it's at 20 volts.
But actually, I can power this with, less than 9 volts. So, basically, this can run on less than a 9 volt battery if it's at the right frequency. Let me demonstrate. So see, the coil is at 20, volts. That's 10 volts right there.
Let's go over and then make that Seven volts. That is 7 volts right there. See? So that's 7 volts. Now let's go back up to 20 volts.
There we are. Okay. Let's get to the point of this video which is restoring the charge in these old batteries. These batteries should each be 1.5 volts or 1 and a half volts. So, I've just found some LEDs.
I believe these operate on 3 volts, possibly. Anyway, I know some of these are burnt out because this got a little too close to the, spark on the diathermy machine one time, that blew out some of these bulbs. But anyway, I know some of them work. So that's what we'll be testing these batteries with. Okay, to start I'm just gonna wire these batteries in series.
So, I believe the center terminal is negative. Oh, no. Just kidding. The negative terminal is on the side. Okay.
So I went to 4 different stores, to find this ammonia hydroxide. But anyway, I found it at the Family Dollar, and it was $2.67. But it took me a while to find it. I was thinking I was gonna have to make my own ammonia by boiling down urine and making ammonia that way, but luckily I didn't have to do that. Anyway, so there's that.
So I'm going to start by wiring these in series. So this negative will go to this positive and so on. Okay. Let's test this LED with the 20 volt signal out of the signal generator. See, it's still lighting that light, by the way.
But this will extinguish the light when I do this because it'll interrupt the frequency. See, it already extinguished because I got too close. Okay. So we're just going to touch this. You're really positive.
Okay. So we're just gonna take this LED and attach the shorter lead to the negative. And the lead that is a little bit longer will go to the positive with the signal generated. There, it's glowing. Okay.
So this one worked. Let's re light our 4 s r. There we go. It's like lighting a candle. Okay.
Now we're going to try this, with all these battery series before we dip the batteries in the ammonia solution, and I guarantee you it will not work. So surprisingly, I haven't done anything to these batteries, and there is a glow on the LED, but it's very very faint. Hang on. Let me connect it. Let me turn off the lights, and I'll show you.
Okay. These are the unrestored, unchanged 100 year old batteries. They're series connected. Let's touch it to this LED and see if we get anything. Oh, we have a tiny bit of light.
See it flashing? Let me turn off the kitchen light and y'all see it better. But it'll get brighter when I, so these batteries and ammonia, I can't even see what I'm doing right now. Here's the LED, there it is, see, here's it again, I've lost it, there it is, So that here, let me turn on the flash now. See?
And I believe these batteries have an Expiration date on them. It says install before and it's pointing at something. Where is the wait. Is that a date? No.
It's called before when? Nobody knows. So now we're going to have to stab holes in the side of this casing, that houses the battery. This is ammonia battery, I believe. It works on ammonia solution, Manganese Beside, I believe, in a carbon rod.
I think that's how it works, if I remember correctly. Okay. I've determined the easiest and cleanest way to poke a hole in this battery is to use these nails and this little, sledgehammer, this baby sledgehammer, and poke them up here, where the ammonia solution will go in over here and then down. I almost Forgot an important part of what makes this battery work besides the carbon rod, the manganese dioxide, I believe it is, and the ammonia solution is the zinc casing. So this is called a dry cell because it is semi dry.
Okay. Let's start, hammering this into that. Okay. I've hammered it in there. Let's pull it out now and there should be a white powder in there.
Anyway okay. So a word of advice. If you try this with old batteries, make sure they're this type of battery. If you poke holes in modern batteries, they won't be too happy with you. You may think of your iPhone battery and puncturing the battery system on your iPhone.
They wouldn't be too happy with it. They'll puff up and may get real hot and rush into flames. But my thieves okay. Our holes are poked in the battery. Our batteries.
Now we will get a container and fill it with ammonia and place these in the container of ammonia. So this container should work nicely to hold our batteries. It used to be in my apothecary, and it had exactly what's on the label in it. It was called Copper A Star Arsenide, which they still use, by the way, the color fireworks. I believe white.
Okay. I've placed the batteries in here. Well, I had them. Okay. There we go.
Now we're gonna series connect them again. Okay. Our batteries are series connected again. Now I'm just gonna turn this and reconnect the LED and show y'all before, and then I'll add the ammonia and show y'all after. Okay.
This is before the addition of the ammonia. It's still lighting fairly good for 100 gigahertz batteries. Now we're just gonna add the ammonia to the and it should get brighter if I can open this. Okay. This one need so ammonia is what they make crystalline smelling salts out of, so it's Very nasty smelly.
Oh, y'all can't even see me adding this. Okay. It's being added. Oh, look. It just got brighter.
See? It got way brighter. Here it is. Look how bright that thing is now. Look at that.
Woah. Wait. Let me pick this up. Inhale, take it in the dining room. Oh, this thing is heavy.
Ow. Ow. Ow. Ow. Ow.
Let me turn on the flash. See, now they're working good!