A Real Sonic Screwdriver?

  • Thread starter 930913
  • Start date
In summary: Sonic Screwdriver is possible."In summary, it is possible to make a sonic screwdriver by using sound waves, to turn a screw. It is easier to have the right side of a screw one metal, and the left another. It can be done, but it would require a lot of expensive equipment and knowledge.
  • #71
Doc Orion said:
Hi;

I had built a working sonic screwdriver once, a few years back.
...
At a certain frequency the screws on the box began to turn fast and easily until they reached the bottom; at a higher frequency they slowly unscrewed themselves...

Can someone please try this one again and get video? If Doc said he got it working, then at least there's hope that it's not purely theoretical...

by the way just thought I should add an article about it: http://www.smh.com.au/world/science...r-a-new-twist-for-science-20101205-18lfb.html
 
Engineering news on Phys.org
  • #72
I don't have the things to do it any more; time has passed on. However, if anyone else wants to do it or is equiped, here's the things that you must have to repeat those early experiments:

1. A piezo speaker box with screws at the back.

I used to get those from Radio Shack. Years ago they were cheap and readily available. I'd buy them and gut them for the piezo speaker element inside, then usually throw away the box except for one I kept for experimenting.

If you can find a similar box, good. But sound waves won't turn wood screws (a real screwdriver has trouble turning wood screws) so you need screws that wil turn easily;
say those on the back of some old woofers, etc.

2. A variable frequency audio sound source.

It should be capable of runing from 0 Hz up to at
least 15 kHz. And preferably, it should be nice clean sine waves; you can use a squarewave
source like a 555 oscillator but because it produces harmonics, things may not go too well.

I used a simple XR2206 circuit in sine wave mode, but I suppose any good electronics or
acoustics lab should have an audio frequency/ function generator sitting around or a kit might be available from some of these electronics places that sell educational kits.


3. A good amplifier connected to a step-up transformer.

The output from the audio generator gets amplified; it's voltage stepped up by the transformer-- 8ohm : 1K is a standard transformer and easy enough to find. Or at least it used to be back in those hobby friendly days. Check Mouser or other suppliers.

4. A piezo buzzer

A piezo buzzer is not a very good speaker, but it will work pretty well in this case because the step-up xformer will make it extremely LOUD. At the resonance frequency of the buzzer,
it can get as loud as 140 to 143 dB some 2" from the buzzer. Also, since there is a small
hole in the buzzer, the sound is somewhat concentrated.

BUT... you can do without the xformer and piezo element if you connect the amplifier directly to a bigg woofer; say 8" or larger. Set the top of the piezo box directly on the speaker cone. Use the standard 8 ohm speaker. Connect it to the amplifier with standard speaker wire or
a shielded cable with an audio plug on one end and a pair of aligator clips on the other.

NOTE: if you use the woofer method, the screws will turn themselves downward but not
upwards. That is, turn the screws up to their stops and the sound at the right resonant frequency will make them turn downwards until they can't go any further. But because this
is considerably more inefficient than using the piezo speaker, a woofer can't produce enough vibration at the "anti-resonance" frequency to make the screws turn upward against the pull of gravity-- for that you need sound at very great intensities and only a piezo speaker can produce sound that loud.

And, Oh, use ear protectors: sound that loud can hurt the ears and give you one hell of a headache.

Here's a lesson from "Acoustics 101:" the resonant frequency of an object depends upon such factors as its size and mass. This is why the resonat frequency of a wine glass is much higher than that of a bridge. A good example is to take a crystal goblet (a wine glass will do but it will be trickier) and feed the sound from the loud speaker and adjust the frequency upwards until resonance; at that point, the goblet will shatter violently. Only sine waves can be used for that experiment.

Good luck-- :-)

'Doc
 
  • #73
Doc Orion said:
I don't have the things to do it any more; time has passed on. However, if anyone else wants to do it or is equipped, here's the things that you must have to repeat those early experiments:

1. A piezo speaker box with screws at the back.
...
2. A variable frequency audio sound source.
...
3. A good amplifier connected to a step-up transformer.
...
4. A piezo buzzer
...
NOTE: if you use the woofer method, the screws will turn themselves downward but not
upwards.
...
And, Oh, use ear protectors: sound that loud can hurt the ears and give you one hell of a headache.
...
Good luck-- :-)

'Doc

Thank you so much! With a list that clear, I really have no excuse not to try building one! (Other than... having no experience in building stuff... but I'll get there :tongue:)
If I ever get one working I'll be sure to post pics and vids here.

Thanks again very much for replying, Doc; you're a legend!
 
  • #74
Me? Nah... I could never get my screwdriver to work quite right; a problem with the switch. Check out the video of the screwdriver prop--


http://www.youtube.com/watch?v=UXGdSGGvhQY&feature=related

Now that guy's screwdriver is beautiful! Too bad the only thing it does is makes noise. But I guess it's sonic after all... <g>

'Doc
 
  • #75
Doc Orion said:
...

Now that guy's screwdriver is beautiful! Too bad the only thing it does is makes noise. But I guess it's sonic after all...

'Doc

Pah, the aim is to get a *working* screwdriver; one that can remove or put in (probably mostly removing :P) screws using sound and not contact.
Even if yours didn't look like the Doctor's (or perhaps *especially*, for creativity's sake) I'd want it waaaay more xD
 
  • #76
Okay...

I was going to keep this secret until 2022, but doing some much needed cleaning I stumbled across a binder with 95% of the working drawings for the Screwdriver. It's unfortunately missing two things: the drawings for the sound-head, and the bottom end cap/ frequency control knob.

Before anyone starts to salivate uncontrollably, let me make this point clear: I no longer have the original CAD files, and I have no way to transmit these files electronically. For some unexplained reason, every scanner I have ever bought has broken down and stopped working within three days after I buy them. My fax machine didn't last too much longer.

SO, if anyone really wants the working plans-- the circuit diagrams for both the
Doctor-screwdriver and the Romana-screwdriver as well as the machinist drawings for the main pasrts of the Screwdiver-- first, send me an email and I will give you my address. Then you can send me a 8" x 10" SASE and as soon as it warms up here, I'll go to Kinko's and have copies made of the plans. From there, children, you are on your own; this homeboy has too many other projects to juggle. ;-)

'Doc
 
  • #77
For those a ittle too lazy to do it physically, here's an idea: get a copy of the Cool Edit program. This does a lot of things with sound-- for example, it can be set to generate a sine wave of a given frequency and modulate it with another to get the sound the Doctor's Screwdriver makes or the sound european sirens make, whatever...

Cool Edit can be gotten for free-- so it's very cheap for those on a bdget. Get the program, learn to use it, and feed the signal from your sound card into an amplifier and a good hi-fidelity speaker. See what kind of amazing things you can do. <g>

But being software, it doesn't have the versatility a real circuit has, yet it has potential. I should point out though, that the first couple versions of Cool Edit while free, doesn't
allow the use of all of the features at the same time but that's okay; most don't need
every feature at once anyway. ;-)

'Doc
 
  • #78
When I first started out I had a number of engineering directories which had some amazing items listed that weren't your usual consummer products. It's been a long time but they are still around, a 12 kHz piezo transducer that's not quite perfect for the Screwdriver, but very close to it.

http://parts.digikey.com/1/parts/485-buzzer-piezo-element-12khz-13mm-kbs-13da-12a.html

I chose 13 - 15 kHz for the Screwdriver's operating frequency because most people can't hear that high-- and I don't care what the books say: damn few people can hear up to 20 kHz. So some textbooks on sonics consider ultrasound starting at 13 kHz and it's a good compromise since acoustical power goes down as frequency goes up. You want to be able to use the Screwdriver at 4:00 in the morning and not wake the neighbors, so use lower ultrasound and even 12 kHz is on the edge of audibility for a lot of people.

Romana's screwdriver uses "pure" ultrasound so high, it's not even audible when working. The design is a lot simpler, but it gets harder and harder to find a transducer for say 18 kHz. There's a company called APC


http://www.americanpiezo.com/products_services/disc_benders.html [Broken]


who might make custom transducers for a small fortune, but some enterprising person could make them fairly easily from a few really thin 1/2" dia. peizo discs, a 5/8" dia. (or slightly larger) brass disk, and some electrically conductive glue to bond the piezo disk to the brass. Some experimenting with the thickness of the brass would probably sooner or later get you a "bender" that will be resonant at 13 kHz then you really will have some acoustic power! That 12 kHz commercial transducer's problem is that it's kinda small at
1/2" around-- the sound head should be at least 5/8" dia to 3/4" around; the larger the transducer, the more power it puts out.

Of course you can always use a cheap plastic piezo buzzer from Radio Shack, but it won't look that good heh heh. ;-)

'Doc
 
Last edited by a moderator:
  • #79
Doc Orion said:
I don't have the things to do it any more; time has passed on. However, if anyone else wants to do it or is equiped, here's the things that you must have to repeat those early experiments:

1. A piezo speaker box with screws at the back.

I used to get those from Radio Shack. Years ago they were cheap and readily available. I'd buy them and gut them for the piezo speaker element inside, then usually throw away the box except for one I kept for experimenting.

If you can find a similar box, good. But sound waves won't turn wood screws (a real screwdriver has trouble turning wood screws) so you need screws that wil turn easily;
say those on the back of some old woofers, etc.

2. A variable frequency audio sound source.

It should be capable of runing from 0 Hz up to at
least 15 kHz. And preferably, it should be nice clean sine waves; you can use a squarewave
source like a 555 oscillator but because it produces harmonics, things may not go too well.

I used a simple XR2206 circuit in sine wave mode, but I suppose any good electronics or
acoustics lab should have an audio frequency/ function generator sitting around or a kit might be available from some of these electronics places that sell educational kits.3. A good amplifier connected to a step-up transformer.

The output from the audio generator gets amplified; it's voltage stepped up by the transformer-- 8ohm : 1K is a standard transformer and easy enough to find. Or at least it used to be back in those hobby friendly days. Check Mouser or other suppliers.

4. A piezo buzzer

A piezo buzzer is not a very good speaker, but it will work pretty well in this case because the step-up xformer will make it extremely LOUD. At the resonance frequency of the buzzer,
it can get as loud as 140 to 143 dB some 2" from the buzzer. Also, since there is a small
hole in the buzzer, the sound is somewhat concentrated.

Good luck-- :-)

'Doc

Could you please give me the sizes for all the components?
and are all of those components used for just the SS?
 
Last edited:
  • #80
Doc Orion said:
Hi;

I had built a working sonic screwdriver once, a few years back.

It’s common knowledge that sound/vibration can effect physical structure:soldiers must break step before crossing a bridge, an opera singer can break a wine glass by hitting the proper note, and a helicopter can easily shake a house from a distance overhead. So it seemed to me to be just a matter of frequency and power.

To test the theory I used an old box from a disused piezo-speaker that had a pair of screws on its top as well as a standard stereo speaker. The speaker was connected to a medium-powered stereo amplifier that was being fed by a simple audio sine wave generator.

At a certain frequency the screws on the box began to turn fast and easily until they reached the bottom; at a higher frequency they slowly unscrewed themselves. This was resonance at work. Going one step farther, I placed the speaker up against a solid wood door and adjusted the frequency upward; at a certaain point the key in the door turned itself to the right although not with enough force to open the lock. The key could even be turned when the speaker was some distance from the door (basic Mechanical Engineering 101). At one point I even managed to get dinner plates to spin on the sound head. That was cool.

Once I knew the theory was right, I had to see if I could a practical screwdriver. I tried several ideas but what worked best was a standard piezo buzzer from Radio Shack. Driven at the right frequency and at high enough voltage, it could easily turn the screws on the ox from three to four inches. This was great but at 143 dB, this didn’t work too well for quiet breaking and entering at 3:00 in the morning; not to mention it hurt any bystanders. I decided that this had to work at a near ultrasonic frequency, say 13 kHz. This was a frquency most people could only barely hear. By itself, this frequency didn’t turn the screws too well (resonance effects end at 10 kHz) but when either frequency or amplitude modulated, that worked the same as being used at an audible frequency. It could still be heard, but only because of the secondary modulation—if set for 10 Hz, one would hear the 10 Hz beat and not the 13 kHz even though it was mouch louder.

The final problem to be solved was the size. The SS took a lot of power. One couldn’t use big batteries or carry a battery pack; tat was tacky. The solution came when some company produced a neat little IC that could easily boost 3 volts to 9 VDC. Instead of big batteries, I only needed two sub-C to get all the power the SS needed. When it was finished, the sonic screwdriver was about 11 inches long; a little shorter than the 5th Doctor’s screwdriver (I had a chance to ask Peter Davidson about it once). Made out of aluminum and copper, it was a thing of beauty. Its only design flaw was the on/off switch: I could never get that like on TV. :-)

Eventually, somehow, it got lost...

‘Doc

Didn't you take pictures of the SS when you had it? or a video? if you did I'm sure everyone here would like to see.
 
  • #81
The finished circuit board for the screwdriver is roughly 6" x 1/2" -- this is just a hand wired piece of perf board where all the miniature components are either soldered directly to each other or connected by a few pieces of 24 gauge or thinner hook-up wire. Somebody more experienced in electronics could probably reduce that size down quite a bit further by using a printed circuit board with surface mount parts, but I was just too lazy to do that kind of detailed work.

However, just to do experimental work in sonics, size doesn't really matter when it comes to parts. Any amplifier, speaker, or audio generator will work as well as the next. The only part whre size is critical is the transducer-- the sound head. That has to be built so as to put out
about 140 dB and still be no larger than say 3/4" in diameter. That's a custom piece of work that's immensely tricky to make as two piezo disks have to be bonded together where the
polarity of each face is opposing to that of the other then connected to a diaphragm The whole thing must then be placed in the retaining ring; a time-consuming and intricate little job. All the rest is just machine shop kind of stuff.

* * *

It's been over four or five years since I had finished the screwdriver-- a long time before YouTube came along, so there ar no photos. 'Was no need for any, and nobody believed the screwdriver could be made anyway. Most people still don't think it can actually be done, but
a little knowledge of sonics & acoustics... is what most people lack, heh heh. Well, it doesn't matter.

I may put a picture of the new circuit board up here in a week or two; if I have the time. It's not the same as the original as I couldn't quite find some of the original parts and I made a
change in the output transistors, replacing the flat 220-type power transistors for 5 watt
metal can transistors... mostly because they look cool. :cool: They probably won't give any more acoustical power then the original flat power transistors but it might be fun to see how well the design works.

'Doc
 
  • #82
Oh my! :OO :FF

I just stumbled upon this tread randomly from google! and as I've been a member of physicsforums for some time now, I don't believe I've ever sat down and read one as thoroughly as this one! it's simply fascinating! I'm going to build one of these within the next year for sure! :D

Doc, you are amazing! :D love the hard work! ^_^ and same to everyone else! =)
 
  • #83
Hey Doc is it possible to get a schematic of the circuit board and a parts list with all the sound ranges that needed be needed for your Sonic Screwdriver. Or as I like to call it a Frictionless Screwdriver.
 
  • #84
zzzspawn said:
Oh my! :OO :FF

I just stumbled upon this tread randomly from google! and as I've been a member of physicsforums for some time now, I don't believe I've ever sat down and read one as thoroughly as this one! it's simply fascinating! I'm going to build one of these within the next year for sure! :D

Doc, you are amazing! :D love the hard work! ^_^ and same to everyone else! =)

I have to say that while it's the best I can do, it is a bit crude. But unless one has access to Time Lord technology, it's hard to get sophisticated ciruitry to fit into a sleder tube.

Since the orignial device, it has occurred to me that I could probably get more acoustical power from a better transformer. I used a standard Radio Shack xformer because 1) they're cheap and 2) they work okay. But if I had been a smarter fellow I would have made a special 'former that was round instead of square and with a higher turns ratio. The standard RS transformer was 1K: 8 ohms bcause you can get those anywhere-- at any Radio Shack or places like Mouser for a few bucks. I used to know the turns ratio but these days I've forgotten it, but I know it's not high.

A 'formr with say a 50:1 or even 100 :1 would put out a lot more voltage-- and more voltage means more power from the piezo ceramic. The only thing is that standard piezo discs are not made for very high voltages; maybe 60 volts max! Too much voltage and the ceramic cracks before you can blink an eye. But you need more voltage to get more sound power. Might be a Catch-22 situation *but* some ceramic companies make high power ceramics such as PZT-8 that can take a higher voltage without cracking. Now here's the catch (and there's always a ctach): PZT-8 doesn't work as well as PZT-5A, the ceramic used in standard piezo beepers, speakers, etc on a volt-to-volt basis. But the PZT-8 can take higher voltages so it kinda becomes a trade-off: you would need a lot more voltage to get the amount of power gotten from driving PZT-5A, but 5A will crack when driven from excessive voltages. Still, it *is* more power, but it might make the Screwdrivr a litle bit bigger using a round transformer.

Something to think about. ;-)

'Doc
 
  • #85
ajs84 said:
Hey Doc is it possible to get a schematic of the circuit board and a parts list with all the sound ranges that needed be needed for your Sonic Screwdriver. Or as I like to call it a Frictionless Screwdriver.

I was lucky: by accident, I found the hard copy for most of my Screwdriver files. I even offered to copy them for a few folks-- all I asked for was a SASE (self-addressed stamped envelope), but what I got was people who wasted my time. As Scotty once said, "Fool me once, shame on you. Fool me, shame on me."

Short answer, these days I don't offer to make copies any more. 'Sorry.

'Doc
 
  • #86
Doc Orion said:
I was lucky: by accident, I found the hard copy for most of my Screwdriver files. I even offered to copy them for a few folks-- all I asked for was a SASE (self-addressed stamped envelope), but what I got was people who wasted my time. As Scotty once said, "Fool me once, shame on you. Fool me, shame on me."

Short answer, these days I don't offer to make copies any more. 'Sorry.

'Doc

Would you be able to upload pics of the sonic circuit board and a parts list?
I really want to build one.
 
  • #87
I totally agree I have been pondering and pondering how when I finish building this how cool it will look plus when I pull it out at a job and people ask what is that? I'll be like it's my Sonic Screwdriver :P
 
  • #88
I'm building a casing for a sonic and I really need a brain for it (ie. the schematics/parts list)
It'll be a mix of Tennant and Smith screwdriver
:)
 
  • #89
acron said:
Would you be able to upload pics of the sonic circuit board and a parts list?
I really want to build one.

My life is extremely complicated right now so I don't know when-- or if-- I'll be able to do
any kind of photos but here's the parts list except for the power converter. It's the best
I can do for now.

Basic Sonic Screwdriver Circuit

B1 9v battery
IC! XR2206 function generator IC
IC2 CD4046 phase lock loop

C1 10uF tantalum cap
C2 22uF tantalum [bullet] cap
C3 .00F uf paper cap
C4 10 uF tantalum cap

Q1,Q2 2N3053 NPN power transistors

R1, R2 5.6K, 1/8 w (or smaller)
R3 15K, 1/8w
R4 150 ohm, 1/8 w
R5 100K miniature pot
R6, R7 2.2K, 1/4w
R8 22 Meg, 1/4w
R9 1K, 1/8w
R10 ? select value to get desired sweep frequency range (13 kHz to 15 kHz)

T1 8ohm: 1K CT miniature audio transformer (Radio Shack)

Notes: R8 & C4 values can be adjusted to give personal sweep values/sonic screwdriver effect

2. Ti can be a custom round transformer with an "I" core and a special turns ratio to get
maximum drive voltage to the piezo elements. Anything from 20:1 to 100:1 step-up ratios
can work well. One might be able to gut a taser for the step-up xformer.

3. The Screwdriver is basically three parts: 1) the XR2206 sine wave generator adjusted
from 0 Hz to 100 Hz or thereabouts-- nothing critical. 2) The 4046 is a simple voltage controlled oscillator with R8/C4 chosen to give a variable sweep delay. These two parts are connected to pin 9 and the other end to ground. The signal from pin 2 of the XR2206 is sent
into pin 9 by way of the 1K resistor. And 3) Very simple push-pull amplifier composed of two NPN power transistors with 2.2k base resistors and transformer connected to each collector
(emitters to ground). The 4046 can produce two out of phase outputs so one transistor is on while the other is off. There are better ways to do this-- such as amplifier chips-- but
all of this can be uilt on a narrow strip of perf-board and crammed into a small aluminun tube pretty easily.

'Doc
 
  • #90
acron said:
I'm building a casing for a sonic and I really need a brain for it (ie. the schematics/parts list)
It'll be a mix of Tennant and Smith screwdriver
:)

That screwdriver does everyting but make coffee! Mine only turns screws-- and the occasional dinner plates... :-)

'Doc
 
  • #91
Doc Orion said:
That screwdriver does everyting but make coffee! Mine only turns screws-- and the occasional dinner plates... :-)

'Doc

Do you have a circuit layout or schematic of how everything goes together?
 
  • #92
acron said:
Do you have a circuit layout or schematic of how everything goes together?


Start with the XR2206 sub-circuit:

http://www.google.com/imgres?imgurl...&sa=X&ei=2wwoTqnRAdKDsAKg-a07&ved=0CFYQ9QEwCA

or just Google "XR2206 circuits" to get the thre images for XR2206 circuits. The third circuit is the basic sine wave generator but there's a couple of differences in the screwdriver--
replace that .01uf cap with a 10 uF tantaum cap (even a 1 uF tantalum cap will do) and that 200 ohm resistor will be 150 ohms. Lastly replace that 50K pot on pin 3 with a 15K resistor. As I say, with this circuit, nothing is critical but you want to get a nice sine wave from 0 to 100 Hz. This circuit is actually a lot more simple than it looks; it took me about 20 minutes or less to knock it together.

Keep in mind, all of these sub-circuits will join together on a narrow piece of perf-board about 1/4" wide--- that's standard Radio Shack perf-board, four holes across-- so it takes some creative wiring to make all the parts fit; they will fit though. The three resistors are mounted behind the 2206 while the main cap (19uF tantalum) and th 150 ohm resistors are
mounted directly on top of the XR2206. The pot that controls the frequency is of course connected by wires and go to the back end of the screwdriver so the modulation frequency can be controlled manually. And since there'sonly room for on pot, that's the only one.

I might replace that pot with a rotary switch and fixed values but you may never know
if you might need a particularly frequency you don't have, so that pot provides flexibility ven if it's a bit awkward to tune all the time.

'Doc


Stay tuned for the 4046 VCO sub-circuit, no pun intended heh heh...
 
  • #93
I'm going to give the link to the VCO, then go to bed; it's now 5:00 am so it's past my nappy time.

The VCO circuit can be found here:

http://books.google.com/books?id=ST...resnum=10&ved=0CHEQ6AEwCQ#v=onepage&q&f=false

The siren ciruit is the one I use in the screwdriver but instead of gating it with a square wave, the circuit is modulated with a sine wave. At pin 9 and the other end to ground I use two large value parts that can be adjusted for personal taste such as 22Meg and 10uF or 15 Meg and 1 uF, etc. These parts determine how fast-- or how slow-- the screwdriver will sweep from one end of the frequency range to another. The frequency cap used is .001 uF so the VCO will work in the near ultrasound. I lost my notes so one will have to pop in resistor values to get it to work no higher than 20 kHz and probably less at 15 kHz upper limit. The screwdriver will however work extremely well at lower audible frequencies producing as much as 143 dB (but we always try for more) of sound, and this will make family & friends hate you as well as upset nearby neighbors so keep the frequencies above 12 kHz-- most humans can't hear that high anyways. But sound of such intensity can cause pain, headaches, and deafness with continued exposure even at ultrasound frequencies.

same as with the first part: the .001 cap on top of the 4046 but the frequncy resistor & cap are mounted in front. The 1K resistor that connects from pin 2 of the XR2206 to pin 9 of the CD4046 is wired below the two ICs on the bottom of the circuit board but make sure the wire is protected with tape or heat shrink tubing so the wires won't short any of the IC pins. That could ruin a lot of nice work very quickly. Still, feel free to experiment with the values; each screwdriver always needs some tweaking for proper operation.


'Doc
 
  • #94
I can't find a schematic for the last sub-circuit but it is one of the easiest push-pull amplifiers:

1. One 2. 2K resistor goes from CD4046 output pin 2 to the base of Q1. The other 2.2K resistor goes from output pins 3 & 4 to the base of Q2.

2. The collector of Q1 is connected to one end of step-up transforner T1 and the collector of Q2 is connected to the other side of T1. The center tap of T1 is connected to the positive (+ 9v) rail.

3. Both emitters go to ground.

Or at least I am reasonably sure how that goes; I don't know where my files and notes
went to. There aren't a whole ot of ways the collectors can be wired or the 'former connected to the power rails so yeah, the primary of T1 shoud likely be center-tapped.

So the basic screwdriver is the sine wave generator-- the VCO-- and the power amplifier. Not a very complicated affair but it all has to fit on a 5 x 1/2 inch perf board (I made a mistake earlier; I meant 1/2 inch).

This doesn't include the power converter which is another beast all-together. That converter boosts a single 1.25 volt nicad battery up to 9 volts. The converter allows the screwdriver to be pocket-sized, running on a single sub-c nicad cell (or two) instead of a standard rectangular 9 volt battery.

'Doc
 
  • #95
Is it possible for you to draw this info up and post it. As I can't see it in my mind even if you draw it on a cocktail napkin as long as we can see it.
 
  • #96
Considring all the mayhem that's going on in my life right now you are really lucky I managed to take the time to lay the screwdriver out in sections like this.
 
  • #97
Thanks for doing this Doc
 
  • #98
hey brennanshaw would it be possible for a diagram and stuff and since I am only a beginner in science would you be able to describe the technical terms you use for me please thank you it would be most appretiated :)
 
  • #99
would it be also possible to make a video of how to make one please id rather it be small and compacted as possible and have loads more uses but like i said I am a beginner as in starting college for it in a year or so I am not very advanced but I am good at tinkering hahaha :) if anyone wants to talk to me email me on [e-mail address removed] please all is appretiated :) love to talk to you all about this stuff and learn much much more than i am going to learn :)
 
Last edited by a moderator:
  • #100
@ qbit, I commend, appreciate and applaud that and how you have presented your reports, findings, methods, even the details of the materials used. The fact that you have also added your personal reviews/opinions to them is great especially where you said it would be difficult to use on wood and I would like to point out the many times in Doctor Who, the Doctor has stated and repeated "It doesn't work on wood" and what you have stated could be that very reason. The reason for the nut/washer "jumping" as you said and moving as described would be due to the way and direction the vibrations are acting on the screw/bolt and that it would not work well on wood because would has even been used as a vibration dampener in the past. and it could work on metal frames and such because metal can be used to magnify vibration.

An example of the use of differing vibration used to rotate a screw in opposite directions is the magic toy shown in the attached pic. If you have never used one of these, the way it works is you hold the little wood rod with your thumb and fore-finger pressing perpendicular to the ends and rub it along the grooves with your thumb against the main shaft. Alternating your grip so your finger rubs the shaft makes the fan spin in the opposite direction.
 
  • #101
Found a kick *** pre made body for the sonic screwdriver. Found it in an auto shop here in Australia here's the pic of it in the top black rubber section is the power button (press and hold to operate/ release to stop). it should be easy enough to remove the insides and replace with your circuit board and battery only other thing to remove is the spinning shaft of the driving motor for the screwdriver. i think its a mix of the 11th and classic sonic personally but i might be crazy who knows. (hahaha who knows get it?)
 

Attachments

  • Image064.jpg
    Image064.jpg
    16.7 KB · Views: 499
  • #102
what if u made it using heat? the heat from it could widen a lock?
 
  • #103
After being homeless for several long and painful months, I finally have a place and will be settled in sometime by next month. I managed to keep my screwdriver files with me, though not much else, so if anybody still wants to see pictures of the circuitry I'll probably have them posted between now and the end of March. Hopefully they will come out okay. We'll see... :smile:


Doc
 
  • #104
When things settle down a bit I'll post the schematics for the Screwdriver, but there may be a problem: the XR2206 chip has been discontinued! that IC is the sweep modulator and critical to the design. I thought it would be around forever-- but what do I know? :redface:

Doc
 
  • #105
I've read the entirety of this thread at this point. I must say that it is really quite fascinating. I know nothing about Physics (though have been starting to read alot) or anything at all about acoustics. I would be interested in attempting some of the experiments and ideas that have been put forth so far. For me this just puts the cake on something that has been a mild interest for me for awhile now. Keep it up I look forward to the reading to come.
 
<h2>1. How does a real sonic screwdriver work?</h2><p>A real sonic screwdriver would work similarly to a regular screwdriver, but instead of using physical force to turn a screw, it would use sound waves to vibrate the screw and loosen it.</p><h2>2. Can a real sonic screwdriver open any type of lock?</h2><p>It would depend on the specific design and capabilities of the sonic screwdriver. Some may be able to open a wide range of locks, while others may only work on certain types.</p><h2>3. Is it possible to create a real sonic screwdriver with current technology?</h2><p>At this time, it is not possible to create a sonic screwdriver with the same capabilities as the one in the Doctor Who series. However, scientists are constantly researching and developing new technologies, so it may be possible in the future.</p><h2>4. What materials would be needed to make a real sonic screwdriver?</h2><p>The materials needed would vary depending on the design, but some possible components could include a power source, a sound generator, and a mechanism for amplifying and directing the sound waves.</p><h2>5. How would a real sonic screwdriver differ from a regular screwdriver?</h2><p>A real sonic screwdriver would not require physical force to turn a screw, making it potentially more efficient and precise. It may also have additional features, such as the ability to scan and analyze objects or create force fields.</p>

1. How does a real sonic screwdriver work?

A real sonic screwdriver would work similarly to a regular screwdriver, but instead of using physical force to turn a screw, it would use sound waves to vibrate the screw and loosen it.

2. Can a real sonic screwdriver open any type of lock?

It would depend on the specific design and capabilities of the sonic screwdriver. Some may be able to open a wide range of locks, while others may only work on certain types.

3. Is it possible to create a real sonic screwdriver with current technology?

At this time, it is not possible to create a sonic screwdriver with the same capabilities as the one in the Doctor Who series. However, scientists are constantly researching and developing new technologies, so it may be possible in the future.

4. What materials would be needed to make a real sonic screwdriver?

The materials needed would vary depending on the design, but some possible components could include a power source, a sound generator, and a mechanism for amplifying and directing the sound waves.

5. How would a real sonic screwdriver differ from a regular screwdriver?

A real sonic screwdriver would not require physical force to turn a screw, making it potentially more efficient and precise. It may also have additional features, such as the ability to scan and analyze objects or create force fields.

Similar threads

  • General Engineering
Replies
7
Views
2K
  • Electrical Engineering
Replies
2
Views
660
  • Mechanical Engineering
Replies
3
Views
1K
  • General Engineering
4
Replies
136
Views
14K
Replies
8
Views
1K
  • General Engineering
Replies
12
Views
2K
  • Mechanics
Replies
8
Views
1K
Replies
25
Views
4K
  • Mechanical Engineering
Replies
22
Views
1K
Replies
1
Views
2K
Back
Top