Moving Day (for my blog)!

Well, I've been working this for a while because I want everything to go smoothly before I move.
I've moved my blog from blogspot to wordpress. Why? Well, there are a number of reasons, but mostly I like the access that I get from wordpress. So without further delay, please visit

http://mad-laboratory.com

Laminar Flow Fountain - Tangential Input

Ok, here is what I am planning for the tangential input. I have a small drill press in my laboratory that I used to drill the hole tangential to the interior wall.

Non-Newtonian Fluid Fun!

I saw this a while back and I thought it was really interesting. If you haven't played with cornstarch and water then you are missing out and you should drop what you are doing and go do it! DO IT!

Cornstarch and water looks like a liquid when you are moving it around, but when you touch, or poke it with your finger it act more like a solid. It's pretty fun!

Ok, now that you went and played with cornstarch you can watch this video.

Laminar Flow Fountain - Brass Nozzle Insert

So I finally was able to get into my little workshop and setup the machinary to insert the brass nozzle into the prototype laminar nozzle.

Just to recap for the rest of us. I had a manufacturing company that I know make this fabulous brass nozzle for me. I finally got the parts last week and have been itching to get to use them but life has gotten in the way. I've been working on this project for about 1.5 months and have had some pretty steady progress, but this nozzle really takes the design to the next level.

BEFORE

Here is the before pictures of the nozzle WITHOUT the brass nozzle insert.
Notice the water veins in it that are coming right out of the exit? They disappear as the water travels on, but it adds to the turbulence and if there is enough flow the water will begin to break up.

AFTER

Here are the pictures with the brass nozzle insert. This is a low flow rate, but it is comparable to the flow rate in the previous pictures.

This is my favorite picture notice the ASSESENCE of the water viens!!! Absolutely CRYSTAL CLEAR LAMINAR FLOW!

NEXT UP!

1. Work on building a tangential inlet.
   
1. It is my belief that if I add the tangential input I will be able to increase the range without the water breaking up to about 4 times greater than what it currently is.
   
2. Continue to work on the electronics to cut and light the nozzle
3. When parts arrive, assemble the 1st build.
1. 1st build includes (August 12th)
   
1. 1 Laminar flow nozzle
2. Cutter mechanism
3. Low Pass filter
4. Pump
5. LED Light source
6. Fiber Optics
   
4. Test 1st build
5. Evaluate and Redesign as needed
   

A Fountain of a Different Flavor

Couldn't resist thinking about engineering this decadent display at the Bellagio. Read about it here. The chef says it works just like a water fountain...hmmm...laminar chocolate anyone?

Laminar Flow Fountain by Mario

So, I've made some new friends on this journey to the laminar fountain! I am proud to introduce you to Mario the Magician. He really is a magician in more ways than one! First it really is his career in Switzerland, but more importantly he is a WIZARD with laminar flow fountains!

With his permission, I've uploaded a video of his fountain. He has done a remarkable job, and I just can't believe the quality of his fountain. The water doesn't have a imperfection in it!!! FLAWLESS COMPLETELY FLAWLESS!!!!!!

Ok, so he built a fountain that shoots out a prefectly clear stream of water without a flaw in it...SO WHAT!

Well, not only did he built the fountain, but he also built the electronics from stratch, and programmed it all from stratch all while learning everything he could about the fountains online!!!!!

I am continuously astounded by his ingenuity and BRILLIANCE.

This video shows the flow from the fountain and its different modes. I can't say enough about MARIO! Thanks for sharing Mario!

MARIO THE MAGICIAN

Brass Nozzle - Exit Orifice

I got my 0.5" Brass Nozzle from my manufacturer today. They look great! I'm very impressed with the quality. The internal diameter is 0.5" the external diameter is 1". The thickness is .177"

The internal edge is very sharp and could cut your finger. I'm sure that this will do perform well. I can't wait to test it, but I'm still waiting on some other parts.

PMMA Optical Fiber

I received my PMMA Optical Fiber yesterday. It only took 4 days to get halfway around the world to my secret laboratory!




The fiber optics is PMMA or plastic. It is 3mm thick with no PVC coating on it. I couldn't afford the PVC coating. I was surprised at how rigid the cable is, granted I understand that is it SOLID, but it still took me off guard. If I let go of the reel the 3 or 4 loops would spring off.

I can't wait to play with it!

Question:

Do anyone know how to polish the ends? Can I just use the buffing pad for my dremel?

In Circuit Serial Programming

So, I learned a very valuable lesson this week with the PIC microcontrollers from Microchip. In Circuit Serial Programming, or ICSP. I don't know if this is available with other uCs or not, but I'm sure that they would have something similar to this. Please comment and let me know otherwise!!!!!

ICSP is where you can install your chip into your circuit but still be able to program it by using 5 wires (2 wires actually program it, but 3 others support it, Power, Gnd, etc). It's really cool because you can put the uC in the circuit you are ACTUALLY going to use and work with it instead of working with a breadboard, prototyping board etc. Below is a picture of exactly all that is needed in order to program any PIC microcontroller.

SETUP

In this setup I am using the PICKIT 2 programmer. I am using the standard software that comes with the PICKIT 2 to load the hex file into the chip. The chip is the PIC16F690. I am writing code in the Proton+ Development Suite.

The wiring is really simple. You just need a pin 5 header, a PIC microcontroller, and a breadboard. The wiring is specific to this microcontroller, but probably will work for a number of different microcontrollers. See your specific datasheet for details on how to wire up your own microcontroller.

Wiring:
PICKIT2 - PIC16F690
Pin 1 - Pin 4
Pin 2 - Pin 1
Pin 3 - Pin 20
Pin 4 - Pin 19
Pin 5 - Pin 18

**IMPORTANT NOTE**
It took me a number of hours to realize that the pinout on the PICKIT2 starts pin 1 position on the right and goes to the left. In the picture above note the arrow. That designates pin 1.

Results

After hooking up the PIC16F690 correctly it was really simple to load the hex files onto the microchip.

Conclusion

Using the ICSP is really simple, once the wiring is hooked up properly. I plan on including ICSP in all of my own circuits in order to update the software without needing to remove the uC.

It has been suggested that if you are giong to use the specified pins for ICSP to not use them for any other purpose even though it is possible.

Off the Deep End/Underwater Exploration

I know this is my project blog, but this guy, Karl Stanley, is so amazing that I have to post about him. Karl Stanley IS a MAD GENIUS and therefore gets to be heard on today's blog. Karl has built his own personal submarine! He did it without any formal engineering school or training. That's definitely genius! He has also logged in over 1000 personal dives in his submarine, and he did it all for about $20,000 dollars.

That makes me want to build my own submarine! It's a pretty long article, but WELL worth the read!

Make Magazine

AS you can tell I love to make things! Projects are so fun and you get to learn so much. That's how I've learned all about electronics. Sure I had a course in college on electronics, but that essentially taught me one thing. V=IR Great, now you know as much as I do about electronics. Luckily you can learn a great deal of information from working on projects.

I've added some videos from Make Magazine to the side bar on the right. I love make magazine! It is sooooo informative and the projects are really fun! I love watching the videos because they teach you a lot about everything. They just aren't electronic projects, they have a wide range of project ranging from silk screening your own T-Shirts to building your own treubuchet.

So if you have a minute take a gander at some of the awesome weekend projects!

LED LIGHTING FOR LAMINAR NOZZLE

EVERY COLOR OF THE RAINBOW PART II

First off, I would like to welcome my new visitors frequent visitors! Please contact me! I'd love to talk with you about my project!

So this is part II because I needed to learn how to fade and mix the RED, GREEN, and BLUE so that I could pick the colors from the rainbow.

How I did it.

Objective:

To fade each of the Red, Blue, and Green colors individually in order to pick the colors of the rainbow.

Setup:

The setup isn't much different from the past post. I just added more to it. This schematic was given to me from Mario a friend in Switzerland! Awesome schematic! It's simple to build and it really makes sense once you study it out.

I used a PIC uC PIC16F690, and the PIC KIT2 starter kit to program the microcontroller. I also used Proton+ to program the chip. The three different signals from the uC went to three different channels, RED, GREEN, and BLUE. Each pin used PWM (Pulse Width Modulation) to control the mosfet.

**NOTE: In the picture above the schematic shows BUZ11, that was replaced with IRFD024 and the resistor R1 was replaced with a 10K ohm resistor. R2 was changed to a 1.8 ohm @ 2W resistor.



The PIC16F690 was hooked up to the mosfet via a resistor (10K). The K2 Star LED was hooked up to power from the LM317 which was hooked up in a constant current circuit constantly outputing 700mA actually something like 705mA if you want to be exact. Essentially how this circuit works is the mosfet is blocking the path of electricty to ground.



Every time the uC would output a high voltage the mosfet would allow the LED to connect to ground and LED would turn on. The voltage would vary, because of the PWM, and allow different level of intensity for each LED. Using this circuit three times over (once for each color) I was able to control the light output for each LED allowing me to mix the color to obtain a maximum of 256*256*256 colors! Well ok, maybe not that much, but it's at least more than.....5! In the picture above you can see three aluminum heatsinks. Each one of those heatsinks has the LM317 attached to it providing power for each LED. =)

Results:


As you can see the results are pretty spectacular! These are just a few of the colors. I was having difficulty with my camera and so most of the photos didn't turn out. But it gives you an idea of what it will look like when you get yours finished!

I'm uploading a video of it changing colors. Once it is done, I will come back and post it.

Every Color of the Rainbow

I've made some significant progress this weekend! I extended the Glowy Green LED's to Blue and Red. I also soldered up a circuit to power the LED's instead of just hooking up each part individually. That got pretty crazy really quick with all the alligator clips all over the place. I'll explain more later.

The next part is to use the mosfets to allow the microcontroller to control the brightness of the LED's. This will allow me to change the color and mix them as I desire.

BRIGHTER THAN ALPHA CENTAURI

So, I've always been fascinated with mood lamps, green and blue glowy lights. I have, in the past, tried to make my own mood lamps. There is just something about the way that is changes color seamlessly from one color to the next.

So, I'm trying it again. What's going to make this time different and what does it have to do with a laminar nozzle? Both very good questions, I'm glad you asked. The lights are going to be for the fountain. I've always wanted a fountain, and I've always loved mood lights so why not combine them! The fountain is going to have some LED's and some fiber optics which will port the light right up the center to the water. When the water shoots out the light will be able to travel right through the water just like fiber optics.

I have a friend in Switzerland who is doing the same thing as I am doing. We share information back and forth. He has come up with a brilliant way to make the LED glow, and glow bright. Not to mention an easy way to the control the brightness of the light. Thanks to him I KNOW I cannot fail at this task.

Currently I am just working with 1 Green 5W K2 star from Luxeon. This light is soooooo bright. The one light can light up the entire room as shown below.
Just to give you an idea of how bright it is, a regular LED (like the one on your DVD player) uses 20mA of current. The K2 star is capable of using up to 1000mA. That's 50 times more current!!!!!!!




Because it uses so much current you can't turn it on without it being properly heat sinked. That's what that hugh chunk of Aluminum is. The heatsink helps draw the heat away from the LED and a fan blow over the aluminum and cools it down.

Just so you know this is only 1 LED. I'm planning on have at least 3 more if not 7 more. I will also need to purchase some fiber optics in order to port the light into the fountain. This will be a challenging but really rewarding task once it is completed.

THE NOZZLE

Ok, so here is how the nozzle will look. I will post more later.

Now it's later and I have a minute. This is the nozzle that I am designing. The principle is basic. The water will enter into the tube tangentially into the nozzle chamber where it will swirl around until it gets to the sponge (not shown in picture above). The sponge will break up the flow and disorganized the flow. The sponge is juxtaposition to the straws, so the water will flow through the straws (shown as red in picture above). Once it exists the straws the water will be moving at the same speed. It will gather together in an open chamber before shooting through the brass exit nozzle. Once it leaves the brass exit nozzle it will be clear and beautiful. Then if the cutter mechanism is open the water will exit the top. If the water is being cut, the flow will continue through the side of the nozzle and back into the water system.

It's simple in theory! =) Now I just need to build it and make the water behave like I think it should behave.

A SPECIAL THANKS TO MARIO AND ZACHARY FOR HELPING ME WITH THE CRUCIAL SECTIONS OF THE DESIGN.

Underwater Tests

So a very smart friend of mine brought up the point of the mechanism working underwater. I didn't know. So I had to find out.

Test
Cutter Mechanism Underwater test

Objective:

To observe whether the mechanism will work in an underwater environment.

Introduction:

The cutter mechanism is going to be used in order to deflect the water from the air to the underwater piping system giving humans the illusion that the water is jumping. Each nozzle will be timed in such a way that the water will appear to be jumping or leaping from place to place.

In order to cut the water the Cutter mechanism will push and pull a plate in from of the orifice in order to deflect.

We must be certain that water will not affect the mechanism. The mechanism must be able to cutter the water in either a partially or fully submerged environment. This test is designed to find out if the water will cause any problems. We are particularly concern with the solenoids and how they will perform.

Setup
The setup for the cutter mechanism is the same as the setup in other cutter mechanism tests with the small addition on waterproofing. I applied a liberal amount of hot glue to the connections and any point that might have a leak.

I filled a 5 gallon bucket with a small amount of water just enough to cover the mechanism.

Results

The cutter mechanism was suciffiently waterproofed and I was able to contain the magic smoke. The cutter operated as designed.

The video below show the results.



Conclusion

The cutter mechanism performed well underwater. The proof of concept was succesful and the mechanism will be introduced into the design.

The mechanism was observed to be a bit slow moving from position to position, but has not be confirmed. However, the majority of the drag is probably due to the vertical plate. The Laminar Nozzle will have a significantly reduced drag since, the cutter mechanism will have a U-channel instead of an L-bracket. This should alleviate any drag induced problems.

Jumping Laminar Jets

So a special thanks to my friends who listened to me to help me put together this spreadsheet with all the information about the Jumping Laminar Jets. A special mention to Will for building the spreadsheet for me! For those who aren't fluent in geekspeak what this spreadsheet tells us that it doesn't tell you is how height and far the jumping laminar jets will go based on a number of key numbers.

First column
Flow Rate: This means how much water will flow through an area in a certain amount of time. This is measured in Gallons/Min. It's like how fast you would be going if you were a liquid.

Second column
Flow Rate: Same as above but just converted into different units.

Third column
Angle: This is an important one! Once we build this water fountain we will mount the nozzles at these angles

Fourth and Fifth column
Diameter and Area: The diameter is the diameter of the outlet for the water. Subsequently, the area is the calculated area for the water outlet.

Sixth column
This one is important too. This is the amount of nozzles you can have.

Seventh, Eighth, and Ninth
Velocities. The Seventh column is the total velocity, and the Eighth and Ninth are the component velocities (velocity in the horizontal and vertical directions).

Tenth, Eleventh and Twelfth
Time in the air, Height, and Distance. Pretty self explanatory.

Geekspeak:

It is all based on two principles. First, is flow in must be equal to flow out, Qin = Qout. This obviously simple equation in fact states a lot. From this equation we are able to get the exit velocity of the water because we know what the area is from whence the water is leaving. =)

Simply.

Q=v*A

solving for v

v=Q/A (Eq 1)

so Eq 1 gives us the velocity of the water leaving the nozzle. From there we can treat this like a particle motion problem. Or

h = 1/2*g*t^2 +vy*t+ho (Eq 2)

Since we are going to be putting these nozzles on an angle the velocity that we obtained from Eq 1 isn't the velocity in vo. We need to adjust the velocity for the different angles. So we need to compute the vy (velocity in the y or vertical direction).

vy = vo sin (theta)

knowing that we can calculate the total time the water is in the air. Using Eq 2 we know that the water starts from ground and ends up at the same level (ground). So h=ho = 0. Rearranging Eq 2 and solving for t you get.

t = 2*vy/g Eq 3

Using the answer from Eq 3 and subsituting it back into Eq 2 we can find the height the water will travel.

To find the distance we need one other equation. Distance = Rate * Time

or

D = vx * t

where vx = vo cos(theta) or the velocity in the horizontal direction.

Again, thanks to those who helped me with this!

Cutter Mechanism Design

Ok, it's pretty late and I need to get to bed so that I can get up for work tomorrow, but I thought I would as least throw these images up. I'll edit this post tomorrow, and give a full description..

My Desires for the Final Product

Solenoid Cutter Mechanism Video

Solenoid Cutter Mechanism

Since I have my solenoids working properly I started working on the cutter mechanism. Solenoids are really neat mechanisms and if it weren't for them generating A LOT of heat I wouldn't even have to design a mechanism. But they do, so I will!

The purpose of this mechanism is to allow me to keep the cutter open or closed for ANY amount of time. I started thinking of all these neat mechanisms that would allow me to latch the solenoid. These were pretty complex but eventually it got more and more simple. Eventually it came down to this design.

The figure below show the solenoids in the starting position. You can see that the solenoid plungers don't have any magnets attached to them or anything. The magnets are on the brackets at the end. The solenoid at the top is in the on postion, meaning the current is running through it to attract the plunger and retract it. The bottom solenoid is in the off position. I don't have a representation of a hole in this experiment but imagine that the hole is just to the right of the bracket in the middle.

In order to cutter the water the bottom solenoid will turn on, but just for a moment (200 ms). Once the cutter mechanism has moved to the "closed position" (see figure below) the upper solenoid engages the magnets and the valve is now closed and all current is off.


In order to move the cutter mechanism basck to the start the top solenoid is turned on and the entire process starts over again.

I can't say that this is the exact design that I am going to use yet. I still have a few other ideas that I have before I commit to one design, but so far I am pleased with these results. So I only run current through it to move the mechanism once it arrives at its destination the current turns off and remains in the position until the next solenoid is turned on. That means no excess heat, and remember HEAT is the enemy in electronics.

Coolest service ever!

I realized that the design for the Laminar Flow Nozzle is starting to get a little complex, and by complex I mean things that I can’t manufacture with my little drill press. However, if you need a small hole drilled into something I'm your guy! My previous experiences with manufacturing companies went well. I just called them up, emailed them some documents. They gave me a quote and we went on our way. I never did much shopping around since I only knew a handful of companies.

I was headed down that road again. I emailed 2 companies that I knew could make the part that I needed, but days went by and they never emailed me back. A long time ago a friend of mine told me about this great website MFG.COM. Essentially is an eBay of sort but for manufactures who want jobs. So people and companies submit an idea/documents for something to be manufactured. The manufacturing companies look at the design and submit a bid to make your desired product. I guess it’s more like a silent auction.

So I signed up! It was really easy to sign up and submit a RFQ (Request for Quote). The next morning I looked at my RFQ and there were 20 bids for my parts. They ranged from $4 to $256 for a quantity of 8. WOW! The lowest bids came from over shores. I’m not sure I want to venture out that far just yet so I’m going to go with a company in California.

So they are going to make my parts for me. I will have them in a little over a month.

Solenoid Tests

I won’t detail the setup exactly in this post, but I just received my solenoids from Goldmine Electronics and they are awesome. Thanks to Zachary for pointing me in the right direction on that one. I’ve never played around with solenoids, and they are very basic, but what can you expect when you only pay $0.99 for each solenoid. How do solenoids work? Well, when you run current through a wire you get a magnet field. This magnetic field circles around the wire. When you wrap the wire in a coil you get a stronger magnetic field! Wrap it enough times and run enough current through it you can get a large enough field to attract an iron core plunger. When the current turns on the plunger is attracted and retracts. When the current turns off a spring returns the plunger back to its original position. That’s the basics of a solenoid.

Drawbacks:

Solenoids need a large current to run through it in order to create a large enough magnetic field. Since nothing is a 100% efficient you get a lot of HEAT. Heat is the enemy in electronics. If things get too hot things burn up and solenoids are no exception. So you can only run them for about 25% of the time and they have to rest for 75%. That is going to make it difficult for the cutter mechanism. Since I want to be able to keep everything open or cut the water at ANY given time, I will have to think of a clever mechanism that will hold the cutter in its proper place one the solenoid have moved it to its desired position.

Servo Tests

I thought I would check out Servo motor to make the mechanical cutoff valve for the laminar nozzle. I picked up the cheapest one I could find at a regular old hobby shop. The long and the short of it is I am very impressed with servo motors. They are very simple to use and need little to no extra components to run them. I was quickly able to get it to turn to the desired location.

Setup:

The setup is really quite simple. I have a PIC Microcontroller 16F690. In order to program the PIC I am using Proton Development Suite. The code is fed to the microcontroller via a programmer by Microchip, PICKIT(TM) 2. I have a board that came with the PICKIT 2 that contains the microcontroller and some LED's and other peripherals. The servo is hooked to GND, +V, and Pin 12 (RC2). The servo has a PUSH/PULL rod which enables the cutter lever (a drilled out CD) to open and close the nozzle. The cutter lever is attached to the nozzle.

Note: For those of you following along at home there is NO water in this test. The code is very simple due to the wonderful software that I am using.

Results: The servo performed exactly how it should. I was able to get it to move to several different positions. I recorded some of the results. Just so you know, it's really hard to record and talk at the same time. I can do calculus, but I can't talk in front of a camera!

Setting up the servo was really easy. All it required was to hook it up via the header pins (I think that's what they are called let me know if you know). It was simple to get it to the proper position all that was required was to send the proper pulse which the software took care of and the servo moved to the desired position.

The simulation could have been better. Holding the servo by hand was difficult and as a result the cutter lever was never positioned over the opening. Conclusions I don't know if the servo will be fast enough, but I think with some tweaking I'll be able to get it to work. I'd like to use servos because the additional electronics involved are minimal. However, servos are slower than solenoids.

A very special thanks to my wife for believing in me and helping me get started on this journey!

Understanding Transistors Demostration Video

So here it is in all it glory. The video is pretty boring and I don't do a good job of explaining everything or anything for that matter. Perhaps you can glean some information from it anyway.

So why do we even care about the transistor and the fact that it can turn the DC motor on and off? Well, the simple answer is...you don't care. The more involved answer is that the DC motor won't be in the application, but it is in place of the solenoid. The solenoid will actuate the cutter valve that is yet to be determined. I have a couple of ideas of how to make it work, but I will spare you the details....for now.

Other concerns:

Drainage: I don't know exactly how or where to drain the water. I need to either have a very robust drainage system or a water return system and pump. The water return system is better since there wouldn't be any flooding, but it is clearly a lot more complex.

Water pressure: Since I will essentially running 8 nozzles constantly I am worried about the ability to keep all the nozzles pressurized in order to make all of them work properly. I think that if I can figure out how many gallon/minute my sprinkler system puts out I can figure out what the water pressure will be as the flow rate and how high they will be able to jump.

Solenoid/Servo: I've been playing with a servo motors as well. **That will be my next post** I like servos because of their simplicity, but I'm not sure that they will be quick enough in order to give a proper cut. Solenoids have the tendency to burnout if run to long. The solenoid that I am working with will (from what I've read) can only be on 25% and has to be off 75% of the time otherwise it will "burnout. If I can water proof the solenoid then maybe I could have water cooling them off, and then I wouldn't have to worry about burnout.

Manufacturing: Seeing as I only have a drill press manufacturing these can be difficult. I have to find a company that will be willing to take on my small little project. If anybody is interesting in me making some of these nozzles for you let me know now because it will be cheaper for all of us!
There are going to be 2 parts that I can't manufacturer at my house. Those are the brass nozzles and the clear plastic (lexan) to hold it in place. In previous post where I show some of the results from the nozzle I was just using the plastic cap as my nozzle. I believe the reason that I was getting those, "veins" or "rifling" in my water is because of the slight (and I mean slight) inperfections in the orifice. The plastic can't hold a sharp enough edge in order to get that brilliantly clear stream. Since I am making a special brass nozzle I need something to hold the nozzle in its place. I will post some picture of the entire nozzle once I get a model made up.

Tasks:
1. Find the Flow rate!
2. Test solenoids (when they get here.)
3. Find a manufacturer for the brass nozzle, and lexan pieces.

Understanding Transistors

So what does electronics have to do with Laminar flow fountain nozzles? EVERYTHING! I think I have the nozzle design pretty much nailed down. There are still a few question that I need to answer but those will come in time. I have to wait on some manufacturers to give me some quotes on making my brass nozzle orfice before I can make more progress on the nozzle. So my attention has been turned to the cutter valve. I've been doing a lot of research on this and I've found out that they don't cut the water before the nozzle they cut it after it leaves the nozzle. Why? My suspisions are that they have to in order to make it look clean and cut. If you have a valve that shuts off the water before hand then it won't have a clean cut to it and most likely will slowly die down. Likewise, when you open the valve it would take a second for it to start back up again.

So I've been researching motors, solenoids, and servos (which I guess technically they fit under the motor category, but it sounds more impressive if I have more categories). I started with solenoids because solenoids are CHEAP. I found some on a website for $0.99. WOW! I never knew that, but I guess that makes sense. It's just a couple of windings around an iron core. I have 8 on their way, and I should have ordered more since they were so cheap.

So a solenoid is just a push/pull type of motor. Actually it just pushes or pulls but not both. There is a spring that helps the shaft return back to its orginal position. My microcontroller that I am going to use to open and close the cutter valves can only output 5V and 40mA. So I need a way to get the voltage and the current up so that I can actuate the solenoid.

That's were the Transistor comes in. I read about them in the past, but never understood them. This time had to be different. So I went to radio shack and picked up a couple of different transistor based on my research. Since I don't have my solenoids I subsituted a DC motor that operates at 12V. I put everything together like I read. And it WORKED, kind of.....it worked but slowly. This wasn't good enough because I knew that the solenoid would need to draw more current than was being supplied to the DC motor. So it was back to the drawing boards. I looked over and over again trying to figure out what was wrong. As it turns out I'm not exactly sure what I was doing wrong, but I must have been hooking it up wrong or something. What I ended up doing was ripping everything out of my breadboard and started hooking things back up. When I turned it on everything was working just fine! I don't get it. I SWEAR I was hooking it up properly before! Oh well, at least now I have a working example to work from. I made sure to document everything I did so I can reproduce it in the future.

I ended up still using the TIP31 or TIP31A (I can't remember which one). I hooked the 12V to the motor and then the motor to the collector. The emitter was hooked directly to ground. The uC was hooked to the base via a 2K resistor. I made sure that the ground used for the uC was connected to the 12V ground so that I had a common ground.

Laminar Flow Leapfrog Fountain

I went to Disney World when I was 15 years old with my family. While we were there we visited the Epcot center. We were walking around looking at the attractions when we came across this very unique fountain. This fountain would shoot a jet of water about 4 feet long and where it landed another jet would shoot another jet of water making it appear as the water was jumping around. I was fascinated with the fountain and probably played with it for an hour.

Ever since I saw that fountain I always wanted one. Now I'm in the position where I can make my own. I thought that it would be easy. I thought I could tie it into my sprinkler system and use sprinkler valves to make it jump. NOOOOOOOO, DISNEY would never make it that simple. As I started to look into the fountain and how I would build it I came across some very interesting information. The nozzles that they used weren't your typical nozzle that just shoots water. They are special nozzles. These nozzles take the turbulent flow and turns it into a laminar flow. For those that don't speak geekspeak, the nozzle takes the water and organizes it puts it back together so that the water is all traveling at the same speed! This "organization" produces a crystal clear stream throughout the entire arc. If you are good enough you can't even tell that the water is moving because the entire arc looks the same.

So I've done my research and read through a dozen different patents on the laminar flow nozzles. I've been working on a way to make your own laminar nozzle. So the black thing in the picture that is shooting out the water is my laminar nozzle. I've been working on this for about 2 weeks now, and have had some pretty good results. Nothing perfect but good results. This is the second test. The first test I didn't record! WHAT KIND OF MAD SCIENTIST DOESN'T RECORD HIS TEST RESULTS?!?!

TEST 1

Setup:
The lamiar nozzle is attached to a garden hose #1. The nozzle was setup with an incline. The valve is fully open.

The Laminar nozzle setup includes the coffee straws, and a .5 countersink hole in the cap.

Results:
The flow wasn't entirely laminar, in fact I suspect that it was more in the transitional flow. At the orfice the flow was semi-organized and clear but with "veins" that looked like rifling. As the stream progressed the water became more and more broken-up. The arc was about 4' wide.

TEST 2
Setup:
The lamiar nozzle is attached to a garden hose #1. The nozzle was setup with an incline. The valve is fully open.

The Laminar nozzle setup includes the coffee straws, and a .5 countersink hole in the cap, and a 3" thick sponge that was cut into 4" diameter circle to fit inside the nozzle right by the inlet.

Results:
As you can see the results are much more clear and focused. There are still issues with the water at the outlet. It appears that the water has a "rifling" look to it. The water doesn't break up at all throughout the entire stream.

Mab Laboratory

I always wanted to be an evil genius. I have TWO main problems with that:

First, I'm not very mad. I'm not mad in either sense of the word. I'm not an angry person, nor am I crazy. At least, I don't consider myself mad.

Second, I'm not a genius. That's the real bummer. =( I keep trying to come up with something really creative, that everyone wants, that takes no money to start, and let the royality checks come rolling in, but that hasn't happened yet.

I am, however, very passionate about engineering, building, creating, and being creative, and as such this leads me to one of my favorite things to do PROJECTS! This blog will be a tribute to both success and failure of my projects. Hopefully there will be more of the former and less of the latter.

Welcome and enjoy your stay. Please comment on anything you like or make suggestions that you have for billion dollar ideas.