Make a bicycle powered generator in 9 steps

Intro and materials

credit: abemckay

Two guys, Abe and Jon, have allowed us to share their great project for making your own bicycle powered generator for charging your electronics with clean energy for every day or as an emergency power supply. Under the Instructables user name abemckay, they guys shared what you need to make your own generator in just nine steps.

Materials needed:
Bicycle Stand
Bicycle frame
24V DC scooter motor
DC-DC battery charger
A car battery, or something similar
DC-AC inverter
Wires for electrical connections and various bike parts and tools.

A multimeter might be useful to check various voltage differentials between different objects.

The specific hardware we used:
Motor: 24V 300W Scooter Motor
Battery: 12V 18 amp-hr lead-acid battery model 7448k51
Charger: Thunder 620 battery charger- 300 Watt 20 Amp
Inverter: 400 Watt inverter Model 6987k22

Bike stand

First you need something to hold your bike. You can either build your own bike stand or buy them. We used a bought stand for the back and made our own for the front.

Buy a stand: These stands are especially nice for the back wheel because some of them are adjustable from side to side (right and left to the rider). This variation makes aligning the connection to the motor easier.

Make a bike stand for the front wheel

For the front bike stand, we used a few blocks of wood. The base was created by a 4x4x24” wood block. Using two 2x4” planks, we created the bolt-holding blocks by making a ⅜” hole high enough to be comfortable when you ride. For us, this ended up being about 12 ½” from the ground, but this is variable depending on the size of your bike.

The support blocks sandwiching either side of the two high blocks were made by sawing about 4 inches off of the 2x4s. These support blocks were attached into the base block with 2.5” screws, allowing enough space in between the blocks to fit the tall bolt-holding blocks.

Finally, 3” screws were drilled in diagonally from each side at the support blocks, through the bolt holding blocks, and into the bottom block. We threaded the ⅜” bolt through the holes in both 2x4s to create a place where the front fork of the bike could be rested. A good idea when drilling screws is to pre-drill your intended location with a slightly smaller bit than your screw. This makes the process a lot easier.

This is for those who only have the bike frame. If you have a front wheel attached, don't worry about this!

Bike frame

Any bike frame will do, as long as the pedals spin the chain.

Bike to motor

Here you again face a choice: you can use the back wheel to spin the motor, or you can go more directly from the chain to the motor. Using the back wheel wastes some energy in friction and spinning a mass. But getting the correct gear ratio for the chain-to-motor strategy proves difficult.

This step is the most hands-on and difficult of the process. We recommend that you use the back wheel as the connection to the motor. However, if you want to have a more efficient connection, we also have a more complex option.

Why you need a motor: the motor converts movement of your legs into DC electricity.

Choosing a Motor: A stepper motor, car alternator, or an electric scooter motor will all work. We used a scooter motor. The motor produced voltage proportional to its RPM . The motor produces current based on the load attached.
For reference, a mountain bike tire going at 20 mph spins at 250 RPM. Additional RPMs for the motor come from the ratio of the wheel size to the frictional cylinder on the motor.

Back wheel option

Making a bike generator using the back wheel is the more common method. Find a motor that can mount a cylinder that can grip well to the back wheel of the bike. Using a hinge and various plates of aluminum, you can construct an adjustable mount for the motor that will allow you to vary the amount of contact between the cylinder and the wheel. You attach the motor to the upper plate, and adjust the position or angle of the plate with a bolt or screw.

The back wheel option will give you all the RPM that you need-the gear ratio between the wheel and the cylinder in the back creates plenty of RPM and thus more than enough voltage.

Additional RPMs for the motor come from the ratio of the wheel size to the frictional cylinder on the motor.

Chain to motor option

To attach the drivetrain of the bike directly to the motor, you will need a few changes of gear ratio.

Adjust the main chain from the largest chain ring in the front to the smallest gear in the back. If you have a de-railer (the thing hanging down that changes the back gears) you do not have to adjust the chain length. Otherwise, this instructable by carlo.urmy can tell you how to adjust the chain length.

If you want, you can remove the back rim from the axle by cutting the spokes, but spokes are tough.

Get a second chain and adjust it to go from a large back gear to your gearbox (more on this soon). Your back gears will now have two chains on it. If you make slots instead of hole when you attach the gearbox to the stand, you can slide the gearbox up and down to adjust the tension on this chain.

Even with the double chain, you will probably still only be producing 3-6 volts but the pedaling will be very easy. The scooter motor produces voltage proportional to the RPMs (revolutions per minute) of the motor shaft.

Gearbox Strategy: To get more rpms spins, we added a gearbox with a 1 to 8 ratio. A gearbox or transmission just takes the spins of an input shaft and turns an output shaft some faster or slower. Our gearbox was an old dual-shaft motor AC motor. We added a coupler to the output shaft of the gearbox and input shaft of our motor. With the extra rpms, the bicyclist had no problem generating the voltage. However, our gearbox also had a feature that slowed the rpms when too much torque was applied. Unfortunately, this feature made our motor only produce .7 amps when the battery was engaged.

Chain-ring on the back gear: We also bolted a large chain ring (gear) to the back gears to get a larger ratio. With this strategy we could produce 12-15V.

Motor Choice: Another way to adjust for the rpms is in your choice of motor. Our motor was rated at 24V when turning at 2800RPMs
rpms. Motors with lower rated rpms will be harder to turn but will produce higher voltage per turn.

Regardless of how you get extra rpms, you will need to spin a shaft with the bicycle chain. We took a small gear off of a cassette and welded it to a metal sleeve. Then we drilled and tapped a hole, and screwed in a bolt to secure the gear to the shaft. Couplers are also available for sale.

Motor to charger

Why you need a charger:
To charge, batteries need a voltage slightly higher than their output voltage. Putting in too high a voltage can damage the internal circuitry of the battery, reducing its lifetime. Usually, circuits trickle a little bit of current in a battery. But with a bicycle cranking out watts, you want to put whole amps. Battery chargers hold the voltage steady at the appropriate point, and then increase the current allowing higher than normal transmission of power.

Picking a Charger:
Remember that the voltage of your motor will be varying with the speed of your pedaling. The charger we used takes anywhere from 12- 24V. Though chargers may brag outputs of 10s to 20s of amps, batteries cannot stand such current. For example, the battery we used has a maximum charging current of 5.4 amps. Check that the current of your charger matches the limit of your battery.

Connecting:
With a multimeter, measure the voltage coming out of your motor. Connect the positive output of the motor to the positive input of the charger and vice versa with the ground wire. Depending on the direction you spin the motor, the positive wire may not be the red wire; the motor works both directions but gives inverse voltage. If you can adjust the output current. As you may expect, larger current charges the battery faster but makes pedaling harder.

A word of warning: Do not overload the charger! Depending on your gear system, it can be very easy to put out more than 24V. Doing so will break your charger. If you will not be the only one using the system, consider adding zener diodes in case of excess voltage.

Some numbers for thought:
An iPhone 5 battery has a capacity of about 1440 mAh. Let's say you output 2 Amps from the bicycle into the 12V battery, and use a socket on the inverter to charge your phone. Then it would take 40 minutes of pedaling to create enough energy to charge your iPhone from nothing to full capacity. Likewise, at 4 amps, only 20 minutes.

To charge the entire battery, it would take about 9 hours when outputting 2 amps.

Charger to battery

Why you need a Battery:
Charging your laptop could take a few hours, but you probably do not want to be on your stationary bike for that long. The battery holds your generated watts to be doled out on an as-needed basis.

Choosing a Battery:
Traditional car batteries are called lead-acid batteries; you do not want lead-acid dripping from your battery if you tip it over. Furthermore, we heard that if a car battery is tipped over, it can short circuit and explode.

Marine batteries or sealed batteries can withstand the tipping of a tumultuous world. Make sure your battery is rechargeable. And finally, choose the capacity of the battery to match your needs. We chose a 18 Amp-h battery because it holds about three laptops worth of energy.

Connecting: Use the same caution as you do when jumping your car. Connect the positive terminal first for added safety. The voltage across your battery will be different when you are charging, when it is sitting, and when it is discharging; they will be about 14V, 12.5V, and 11 V respectively. The spec sheet for our battery warned to stop charging when the voltage reached 14.4 V.

Check your battery’s spec sheet for its max voltage point.

Battery to inverter

Why you need an inverter:
The AC inverter converts the DC voltage from the battery into AC voltage, which is what comes out of most electrical wall sockets. You’ll often see inverters on a small scale in car adaptors, where they take the power from the cigarette lighter (which is hooked up to the car’s battery). Most general purpose AC inverters are Modified Sine Wave inverters. If you want to know more about how these inverters work, here is a good reference source.

Choosing an inverter:
When shopping for inverters, you want to look for a few features. First, make sure that the output AC voltage is at the level of wall plugs. Wall sockets usually put out about 120V, but it isn’t absolutely necessary to have your voltage match that; anything from 110-130 Volts AC will be fine. Be sure that the frequency of the output is at 60 Hz, which is standard in the United States.

Another thing to consider is the watts that the inverter can output. The power needed from the AC inverter will depend on the type of electronic appliance you are trying to use. For some reference, cell phone recharging takes less than 5 watts, while a microwave will consume 1500 watts! Since price goes up with the power output, you will need to make some decisions on how much you want to spend and what appliances you expect to power.

Another important feature to have is an inverter that can take a range of voltages. Many general purpose inverters will only take in a 12 V DC input. Since the actual output of a standard recharging battery can vary from less than twelve to just over 14, it is important to find an inverter that will be able to take that range of voltage inputs.

Finally, to protect your appliances it would be important to keep the inverter in an open location. Transforming DC to AC will create some heat, and circulation is important to keep the inverter functional.

As for our choice of inverters, we decided to go with the Wagan 400W converter with two additional 5V USB ports, from McMaster-Carr (model 6987K22) . We knew that we weren’t going to be attaching high power appliances to our generator, yet we needed enough to power something like a desktop computer and monitor, which combines to about 250 watts of power. This inverter will recognize if there is an overload of input voltage and shut off, protecting your appliances from surges. It also came conveniently with battery clips, which we used to hook up the battery to the inverter.

How to hook it up:
Using the battery clips, hook up the positive and negative leads to the matching leads on the battery. When attaching the second clip, expect a small spark as the circuit completes. Make sure that you’re holding the rubber ends of the clips when hooking up the battery.

Build a hidden Qi wireless phone charger!

Build a hidden Qi wireless phone charger!

Phone docks are expensive and platform-specific. Charging cables are annoying and unsightly. Wireless chargers alleviate some of these inconveniences, but still leave a lot of polish to be desired. I set out to eliminate all of these complaints, and in building a wireless charger into a nightstand or desk, I am now able to plop my phone down on my nightstand and watch as the battery fills up - like magic.

For this Instructable, I will be demonstrating the process of building a wireless Qi charger into a desk or nightstand. The results are polished, convenient, and impressive. Done right, you'll make your phone-charging experience seamless and attractive.

Step 1:

In terms of supplies for the project, you'll need the following parts and tools ready to use. You may have to hunt around to find a MakerSpace with a ShopBot CNC Router, but you could (in theory) chisel out your wood surface instead.

• PowerBot Qi standard induction charger (any color!)
  • I chose the red model knowing that I wanted to use one of the rubber rings to indicate where my charging pad is hidden.
  • This model comes with a USB cable long enough to use for this project!
• Any 5v AC - USB power adapter, 1.5A output or greater works best
  
  • You can use any 5v USB adapter, including the one that came with your phone. A higher output adapter will charge your phone faster.
• Small phillips screwdriver
• Small flathead screwdriver
• Hot glue gun
• Router (CNC or manual)
  • I used a ShopBot, see if your MakerSpace has one!

You'll also need the obvious:

• A desk or nightstand that you're comfortable taking apart and manipulating
  • I used a board of walnut to illustrate my project since my desk is made of glass and my nightstand is ugly.
• A phone that supports induction charging via the Qi standard
• iPhones are not supported
• Most Samsung Galaxy phones are supported with a special back cover
  • Example: Samsung Galaxy S4 Qi Battery Cover
• Many recent Windows Phones and Android Phones support Qi
• Phones with MicroUSB charging ports that do NOT natively support Qi can use the following adapter to add Qi charging capability using the MicroUSB port
• MicroUSB Qi Charging Film

• Step 2: Disassemble the PowerBot

• 
  
  
• 
• 
  
• Dig in! Peel away what you can of the plastic housing with your flathead screwdriver, then pry the rest off. The PowerBot casing is in two halves, you'll need to separate the two. With the PCB exposed (it's screwed into the top half of the casing), use your phillips screwdriver to remove the guts of the PowerBot. What you see in my final picture here is where the magic happens - that's an induction coil you're looking at! Your Qi compatible phone has a similar coil inside it, to receive the electromagnetic field produced by the PowerBot.
  The induction charging system can only work within a limited distance. The coil in your phone can't be too far away from the coil from the PowerBot, so removing the PowerBot's casing reduces unnecessary obstruction between the two coils. This will come into play in the next step...

 Step 3: Find the maximum charging distance

As you can see in these pictures, I've confirmed that the naked PowerBot is working with my phone, and I've confirmed that the PowerBot continues to charge my phone when the phone is raised above the induction coil. I estimate from this test that it will continue to charge up until around 0.3 inches. If you have a case on your phone, this may be a little tight - you'll definitely need to use a CNC router for better precision. If you keep your phone case-free, you may be able to get away with a hand router (or even a chisel!).

Remember - GREEN means it's charging. RED means there's no connection

Step 4: Fit and attach naked PowerBot

 your naked PowerBot will fit in just about perfectly! You shouldn't have to use any excessive force sliding the naked PowerBot into the hole, and the MicroUSB cable should fit happily, too. Make sure the MicroUSB cable is plugged in BEFORE sliding the naked PowerBot into place.

After confirming that the naked PowerBot fits and still functions (red light means "Ready to Charge!" in the second picture), use your hot glue gun to (CAREFULLY) glue the naked PowerBot into place. This is key - you don't want your hidden charger falling fate to gravity. I glued in/around the existing screw holes, and my naked PowerBot is held snugly in place. Keep your MicroUSB cable ATTACHED throughout this process, but keep your 5v AC/USB adapter UNPLUGGED from the wall.

Step 5: Flip your surface over and test!

Success! I drop my phone onto my hidden charger, and immediately it begins to charge. I also hot-glued the red rubber ring from the first step to the top of the surface (desk or table) to indicate where the charger is. You can now reassemble your desk or table, and enjoy your hidden charger!

Intro and Materials

This fun project comes from Instructables user Roy02. With a few materials and a little bit of time, he shows us how to put together a working battery made from water. This project, which is part of the Instructables Green Design Contest, could be used to add a little charge to your smartphone or be a fun way to introduce battery chemistry to kids.

Roy02 says, "The concept behind it is to make a galvanic cell that works on either a saltbridge or a sourbridge. In this case it's a saltbridge, but you could try using plants or wine (sourbridge) to create the same effect."

Things you'll need:

- copper sulphate
- zinc sulphate
- water
- led lights low voltage (testing)
- clamp cables
- 6 plastic bottles (1L)
- 6 pieces of copper
- 6 pieces of zinc

How to make a water battery

Get started

The first step is filling the bottles with water. I recommend using six (6) 1L bottles.

Put the bottles in a wooden frame so you can move them around more easily.

Cut the copper and zinc into 6 pieces each that you can clamp and put into the bottle neck.

How to make a water battery

Make the battery

Fill the bottles and connect the anodes en cathodes:

left bottle above: add 20 gr of copper sulphate
left bottle below: add 20 gr of zinc sulphate
center bottle above: add 20 gr of zinc sulphate
center bottle below: add 20 gr of copper sulphate
right bottle above: add 20 gr of copper sulphate
right bottle below: add 20 gr of zinc sulphate

Each bottle will produce around 2 volts.

When you have this prepared, connect the copper to the red wire, with zinc on the other side so you will have a + and - side. Put zinc to the dark wire and on the other end copper. Start in the first bottle with copper and the end in the next bottle (zinc) in the second bottle you start again with a red wire that will end in the next bottle and there you start again with a black wire. This will create the electric circuit.

(Make sure the clamp cables do not touch the water.)

Close bottles and test voltage

When you're finished filling the bottles and connecting the cables, you'll end up with a red + and a black - wire from the first and last bottle.

Make sure you cover the bottle necks with plastic or rubber so that you minimize evaporation.

Measure the voltage using a voltmeter. You can also test it by using a LED that is close to the average volt that is produced.

The picture shows a 12 volt LED burning.

Finished

By using the clamps, you could connect the battery to a charging wire. This makes it possible to charge a low-powered gadget or possibly even a cellphone like in the 3D concept.

A Whole Computer Inside an Altoids Tin

Granted, there seems to be no end to the cool things we can create from Altoids tins - cameras, emergency kits, solar powered gadget chargers. But an entire computer?! Yep, someone pulled it off. Time for famously portable netbooks to step aside? Check out this video and decide. Red Ferret points us to this eeeetty bitty computer stashed inside an Altoids tin. And it's really functional, built with an 8-core 80MHz CPU, a (whopping) 32K RAM, Ethernet port, video out, infrared controller sensor and speaker.

Best of all - it's a kit. You can actually make one yourself in an afternoon if you want, thanks to Think Geek. However, it would be extra cool, extra geeky, and extra green if you figure out how to do this from recycled computer parts.

Sure, you could use it to write code for a fun new game...or you could write the next climate science program that saves the world!

Build a Solar Charger For iPhones In 30 Minutes

Images via Joshua Zimmerman of BrownDogGadgets

Earlier this year, Joshua Zimmerman brought us the super easy DIY solar charger made from an Altoids tin. We loved the project, however, he noted that "Apple doesn't let its products play nice with generic USB chargers." So, he has created a new project that works specifically with iPhones and iPods.
This new Instructable is made specifically for those of us who want to charge our Apple gadgets, and it can be made for under $20 -- and it can be done in as little as 30 minutes (or 60 if you're less experienced with putting these little chargers together).

The parts include:
Charging Circuit
2x AA Battery Holder
2x Rechargeable Batteries
1N914 Blocking Diode
Solar Cell greater than 4V
Stranded Wire
Tape
And of course, the trusty Altoids Tin that is the mark of all things small, gadgety and DIY.

You can get an entire kit of all these parts at BrownDogGadgets, Joshua's website. It's the quick and easy way to get everything you need if you don't have parts laying around in the garage or workroom.

The steps are straightforward. First, you need to get the charging circuit right. Joshua notes, "Apple decided to have its newer iDevices not follow USB standards. When an iDevice is plugged in, it checks the data tabs on the USB to see what it's plugged into. Depending on what it finds it sucks more or less power, which makes sense but is annoying because NOTHING ELSE DOES THIS. Thus no charger out there has any power flowing to the data tabs. So the key is to find one that works for your newer iPod or iPhone. If you have an older iPod or iPhone when you don't really need to worry all that much."

After the charging circuit comes the batteries.

"We need to use rechargeable batteries for this project. I prefer NiMh AAs over everything else because they're easy to find, cheap, and reliable. You probably even have a few at home. Since we're using two AAs in this project our charger will have 2000 - 3000 mAh of current. You could even have two sets of AAs in parallel and boost that capacity to 4000 - 6000 mAh."

And of course, we need the solar panel component. Joshua reminds us that while a bigger panel would give us more power, we're limited in space since we want it to fit nicely inside an Altoids tin. There are 4V panels that fit perfectly in the tins (I've seen these for sale at Maker Faire and they're perfect for these projects).

Joshua's Instrucable gives the detailed step-by-step, but the short of it is first stripping the ends of your wires, and wrapping them around and soldering them to your solar cell:

Next comes wrapping the free ends of the positive and negative wires together, and soldering the wrapped wires to the circuite board (this is the trickiest part of the project):

And finally, covering everything in tape and gluing it to the inside of the Altoids tin:

And Voila! Done.

Joshua has some good tips for getting started with the charger to ensure it works with your iPhone or iPod, and you're good to go. A cheap, easy, and fun solar charger for your Apple gadgets!

Conceptual plant lab allows you to harvest 'enriched' air to breathe in

From their medicinal, culinary and aesthetic qualities, to their amazing air-purifyingabilities, plants are amazing organisms that play a huge role in life on this planet. But beyond the general breathing in of oxygen produced by plants, or the ingestion of them, might we possibly tweak this symbiotic relationship further? Eindhoven Design Academy graduate Sarah Daher believes so. Her conceptual Air Culture project harvests the "enriched" air produced by certain plants by offering a controlled environment that optimizes plant growth and its production of certain therapeutic compounds.

Over on Dezeen, Daher explains that the interdisciplinary project "question[s] the value of air, [proposing] a more amplified vision of plants in a future scenario where their volatile emissions become part of our daily lives." The idea is provide the user with tools such as a glass plant chamber, water pump and air pump, allowing them to manage the various conditions of plant cultivation, thus optimizing the plants' release of certain chemicals. These beneficial molecules are then captured with bags or "air cutlery" to be breathed in.

While researching those compounds I found out that most of them have high pharmaceutical value due to their chemical properties and an impact on our health. We usually harvest the plants to extract those compounds. Plants will start to synthesize those compounds under specific circumstances as a response to environmental stimuli. If the environment changes, plants' chemistry will also change.

Daher sees a future where this "enriched" air will be experienced and consumed like food and drink, and believes that it could be scaled up to encompass the interiors of whole buildings, where occupants could breathe in fresh, fortified air. Air Culture reminds me of a safer, green version of mood-altering wearable tech gadgets, minus the potential privacy issues. In any case, the underlying concept makes sense, as we've been using plants medicinally for thousands of years, and it's tantalizing to think we might scale it up for whole buildings or perhaps whole neighbourhoods or "vegetal" cities. More over at Dezeen.

Rs.300 Emergency Solar-Powered Radio Made With an Altoids Tin

Joshua Zimmerman has a great project up on Instructables for turning an Altoids tin into a compact solar radio. All said, the entire project cost a whole $3. It seems like a project coming at a time when everyone is ultra aware of emergency situations, so it is both a fun and practical weekend tinkering project. It even comes complete with plug-in headphones.
Joshua writes, "In honor of all my good friends still over in Japan I've decided to create an Instructable for a $3 Emergency Solar Radio. It's a great thing in case of tsunami, nuclear melt down, or zombie invasion. Plus it's really cute when put into an Altoids tin."

And he's right. I have a soft spot for Altoids tin projects. Everything looks better in them.

With a project time of just under an hour, it's ideal for testing out your DIY skills on a weekend. The tools and materials look simple enough:

Joshua lists parts and tools as:
an FM Radio, two Solar Garden Lights, 1 Diode ($1 for 100 of them online, or take one out of any random junk pile), and a few basic tools like a soldering iron, drill, some wire and wire strippers, a headset or the speakers from a set of earbuds, and of course, the Altoids tin.

The full instructions are on Instructables, so you can get the details for putting this together yourself -- the steps don't look daunting, and it's a great learning project.

Here is a beefed up version Joshua created that he says still only cost about $6 to complete.

Joshua runs a site called Brown Dog Gadgets and he has a bunch of different solar cells and various you can use for creating this tiny radio yourself -- or a few completed radios (so you can just buy them and say you made it yourself). It's a great site for gadget geeks so definitely check it out for parts and supplies.