A thermoelectric Peltier generator allows you to directly convert heat into electricity. This compact solid-state device can generate usable electrical power by exploiting a temperature difference between its two sides, without using any moving parts or complex electronics.
Whether you’re experimenting at home, building a DIY project, or looking for an off-grid power source, thermoelectric generators offer a fascinating and practical way to harvest heat and turn it into electricity.
Table of Contents
What is the Seebeck effect and how to generate electricity using a Peltier module
The Seebeck effect is the physical principle behind thermoelectric power generation. It occurs when two different conductive materials, such as copper and iron, are joined together and exposed to a temperature difference. As heat flows from the hot side to the cold side, charge carriers inside the material move, creating a voltage.
Modern thermoelectric generators use semiconductor materials rather than simple metals. Inside a Peltier module, many pairs of P-type and N-type semiconductor elements are electrically connected in series and thermally connected in parallel as a thermocouple. When one side of the module is heated and the other is cooled, a measurable electrical potential is produced.
In simple terms:
- Heat difference = voltage
- Larger temperature difference = more power
How to make a thermoelectric generator to convert heat into electricity
Generating electricity with a Peltier module is surprisingly straightforward. The key is maximizing the temperature difference between its two sides.
Check this Thermoelectric Peltier Generator on Amazon (SP1848-27145 TEG)
Basic thermoelectric generator DIY setup
A simple experimental setup could include:
- A heat source (candle, alcohol burner, camp stove, or fire)
- A heatsink or cooling method (water, ice, or a metal plate)
- A Peltier thermoelectric generator
- A multimeter to measure voltage and current
For example, you can place the hot side of the module on a thin metal plate heated by a candle, while the cold side is pressed against heatsink or a container filled with cold water. This simple configuration clearly demonstrates how the Seebeck effect can convert heat into electricity.
An important thing to keep in mind when experimenting with thermoelectric modules is their polarity. Before using these modules to generate electricity, you should first determine which side is the “hot” side and which one is the “cold”. To do this, you can follow these easy steps:
- Connect the TEG module to a voltmeter:
- Connect the red wire to the positive terminal of a voltmeter and the black wire to the negative terminal. Check my digital multimeter tutorial to see how to measure the voltage and current produced by the thermoelectric generator.
- Create a temperature difference by applying heat/cold:
- Place one side of the module on a cool surface like a metal plate.
- Apply a heat source on the other side like the palm of your hand or a container filled with warm water
- Read voltage:
- If the voltmeter shows a positive voltage, the side in contact with the heat source is the correct hot side for power generation (meaning heat naturally flows from the hot to the cold side, generating positive voltage at the red wire).
- If the voltmeter shows a negative voltage, the sides are reversed, and the side in contact with the cold surface is actually the “hot” side in terms of its internal wiring polarity.
Thermoelectric generators have several commercial applications, such as heat-powered wood stove fans, where they convert stove heat into electricity to power a small motor.
Choosing the right Peltier module: TEC vs TEG
Although thermoelectric Peltier modules may look nearly identical, they fall into two distinct categories with very different purposes: thermoelectric coolers (TEC) and thermoelectric generators (TEG).
Thermoelectric Coolers (TEC)
Thermoelectric coolers are designed to use electricity to create a temperature difference between the two sides of the module.
- Use electrical power to pump heat from one side to the other
- Designed primarily for cooling applications
- Not optimized for electricity generation
- Limited heat resistance
- Commonly used in mini-fridges, CPU coolers, and electronic temperature control
While TEC modules can generate electricity when exposed to a temperature difference, they are less efficient and less durable, especially when subjected to high temperatures. Check my previous post if you want to learn more about thermoelectric Peltier coolers.
Thermoelectric Generators (TEG)
Thermoelectric generators are specifically engineered to convert a temperature difference directly into electrical energy.
- Generate electricity from the temperature difference across the module
- Designed for power generation rather than cooling
- Heat-resistant (often rated up to 150°C or 300°F)
- Offer better efficiency and longer lifespan
- Suitable for use with flames, stoves, exhaust heat, and other high-temperature sources
For applications where the goal is to generate electricity from heat, TEG modules are strongly recommended over TEC modules due to their superior performance and thermal durability.
How much power can a thermoelectric generator produce and what is its efficiency
The power output of a thermoelectric generator depends on several factors:
- Temperature difference (ΔT)
- Quality of thermal contact
- Internal resistance
- Electrical load
Using the popular SP1848-27145 thermoelectric module as a reference, manufacturer data typically shows:
| Temperature Difference | Voltage | Current |
|---|---|---|
| 20°C | ~1.0 V | ~225 mA |
| 40°C | ~1.8 V | ~368 mA |
| 60°C | ~2.4 V | ~469 mA |
| 80°C | ~3.6 V | ~558 mA |
| 100°C | ~4.8 V | ~669 mA |
Actual results will vary depending on your setup, wiring, cooling efficiency, and electrical load.
Improving efficiency
To maximize power output:
- Use thermal paste on both sides of the module
- Ensure flat, even contact surfaces
- Improve cooling with ice cold water or large heat sinks
Poor thermal contact is one of the most common reasons for low output.
Wiring multiple thermoelectric generators in series and parallel to get more power
Using multiple thermoelectric generators (TEGs) is a simple way to increase usable power from a heat source, but how you wire them will impact the overall output.
When TEGs are wired in series, their voltages add up while the current stays the same. This is ideal when a single module doesn’t produce enough voltage to run your device or charge a battery. Series wiring is common for low-temperature setups where each TEG only generates a small voltage.
On the other hand, the current adds up when TEGs are wired in parallel, while the voltage stays the same. This configuration is great when you already have sufficient voltage but need more current to deliver higher power to a load.
In practice, using multiple TEGs usually means combining both approaches: series wiring to reach the required voltage, then parallel wiring to increase current. For optimal results, all TEGs should be exposed to a large temperature differences.
Check the following video to see an example with several TEGs wired in series:
Using TEGs with a step-up converter to generate a specific voltage
Thermoelectric generators typically produce low and fluctuating voltages. If you need a stable output, such as 3.3 V or 5 V, you can use a DC-DC step-up (boost) converter. This makes thermoelectric generators far more practical, and enable their use to power small electronic devices.
A step-up (boost) converter:
- Increases voltage
- Reduces current proportionally (amperage)
- Allows you to power small electronic devices such as LEDs, sensors, small motors, or USB devices
In some applications, thermoelectric generators are used without voltage regulation, such as in heat-powered wood stove fans, where the fan speed naturally adjusts to the available temperature difference. In other setups, TEGs are paired with power banks or rechargeable batteries, allowing energy to be stored gradually and used later when a stable power source is required.
BioLite CampStove: a portable thermoelectric generator for camping
The BioLite CampStove 2 is a great example of commercial products that uses thermoelectric technology to generate electricity from heat. Designed for outdoor enthusiasts, it combines a wood-burning camping stove with a built-in thermoelectric generator, allowing you to cook meals while simultaneously producing usable electrical power. The BioLite CampStove 2 is designed with portability in mind. Its compact form factor makes it easy to pack for camping or hiking.
Check the BioLite CampStove 2+ Thermoelectric Generator for Camping with USB Charging
Unlike simple Peltier setups, the BioLite CampStove 2 features an integrated system that includes a thermoelectric generator, internal fan, and power management electronics. As the fire burns, heat is converted into electricity, which powers the fan to improve combustion efficiency and generates excess energy for charging devices via USB.
Power output and charging capabilities
The thermoelectric generator inside the BioLite CampStove 2 can produce enough electricity to:
- Charge smartphones, GPS units, and small electronics via USB
- Power the internal fan for cleaner, hotter combustion
- Store excess energy in the integrated battery for short-term use
While it won’t replace a high-capacity solar panel or battery bank, the CampStove 2 provides a reliable off-grid power source as long as fuel or biomass is available.
Performance in cold conditions
As with all thermoelectric generators, performance improves with a greater temperature difference. The BioLite CampStove 2 benefits from cold ambient temperatures, making it especially effective for winter camping or cool-weather trips. Proper airflow and dry fuel further enhance power generation and cooking efficiency.
A practical example of thermoelectric power in action
The BioLite CampStove 2 is an excellent demonstration of how thermoelectric generators can be used beyond simple experiments. By combining cooking, heat recovery, and electricity generation into one device, it showcases the practical advantages of thermoelectric technology for outdoors and off-grid use.
Final thoughts about thermoelectric Peltier generators
Thermoelectric Peltier generators offer a simple, reliable, and fascinating way to convert heat into electricity. While their efficiency is lower than traditional generators, they excel in applications where:
- Residual heat is readily available
- Reliability and simplicity matter
- Moving parts are undesirable
From DIY experiments and educational projects to camping equipment and wood stove fans, thermoelectric generators are effective at converting heat into electricity thanks to the Seebeck effect.
Check also my other post to learn about ultrasonic essential oil diffusion and its use in aromatherapy or to see how to convert Celsius to Fahrenheit.
I use a small chainsaw with a rechargeable battery in the bush to cut invasive shrubs, and the shrubs need to be burned. I would like to have a simple burning chamber with a teg that could recharge the chainsaw battery. What do I need to set this up? Thanks
Hi,
Battery-powered chainsaws usually use relatively high voltage and amperage. On the other hand, thermoelectric generators have relatively low output voltage and current. For example, the BioLite Campstove generates 3W. This is sufficient for small electronic devices such as a phone. However, let’s say the your chainsaw uses 40V and 4A, that means that it needs roughly 160W power (W=VxA). Charging a chainsaw battery with that kind of equipment would probably take too long to be a practical alternative.
pretty sure if you place like 10 40w 2×2 inch “output should be around 380 400 watts” peltier cells connected in series around source of heat you’ll get a good amount of electricity coming out and as long as the heat source keeps high temperature the electricity will come out as much as you want for as long as you feed the burner..
practical and simple to build using propane gas to burn,a metal bucket with lid on top,drill 2 holes one for each side of the bucket 2 3 inch from the bottom “depends on how much tall is the metal bucket/container”,on each side of the bucket insert 1 torch tip “so the flame burn inside the bucket…
half way from bucket bottom glue to the wall with thermal paste the peltier cell and connect all the cells in series “first red wire has to be free the black wire has to be connected with the red wire of the next peltier cell so on forth,until all cells around the circumference of the bucket are conneccted the last wire that will be black”. light up the torch burners at minimum so you can put in the wood branches or what ever you wanna burn,once the bucket is full place the lid on the bucket with a hole on the lid for the fumes to come out.
open the valves of the burner to have a higher and hotter flame.
use a multimeter to test what kind of output of electricity you have,and verify if it actually produce electricity.
for the charging side i cannot help since the electricity produced will be DC.
to remember the side with the writings “letters and numbers” should be the side that create cold and that side has to be glued to the wall of the bucket.
another thing to remember the side without writings should be the side that generate heat and you should place on each cell a heat sink better if you place fan 2×2 inch size to keep the temperature lower and allow the cell to generate more electricity.
personal suggestion on youtube do a search for the following DIY generate electricity with peltier cells .
you will find plenty of results and also you may find a way to make it easier and faster your burner/electricity generator…
of course i would suggest you to use hydrogen coz burns hotter about 2700 F degrees,but you would have to build yourself an hydrogen generator,and even do there are easy and quick ways to build one it would still take some time…to find stainless steel,plastic container with lid that seal the container,wires,power source,distilled water and salt to mix together,and assemble everything..
coz never works out as you planned…
I have a school project where I am making a TEG that powers a head torch and if you keep wearing the head torch, it charges over time. I am planning to use a Peltier module as the generator and then custom shape them to be curved so they fit like a ring around the head. Could anyone tell me what the TEG is made of or how I can get my hands on one? If you answer with the latter, I’d rather if the place I could get them from be in Australia.
Hi Ben, the TEG is usually sandwiched by two ceramic plates and is therefore not flexible. You could try to find smaller TEGs to solve this problem or you could also try to apply them to surface that is more flat, like your chest, back or arms. Pleas also keep in mind that these modules don’t produce a lot of power, and that you will need a power bank or charger of some kind to avoid power fluctuation. That being said, it would probably make a super interesting project. Good luck!
Is there a reference showing which combination of 2 metals give the best output?
Hi, I think that this wikipedia page might help you. It talks about the various combinations of materials that are used to make thermoelectric generators and their properties:
https://en.wikipedia.org/wiki/Thermoelectric_materials
For more detailed information, I also found this paper (Table 1 shows the physical parameters of different thermoelectric materials:
https://www.researchgate.net/publication/329361970_Resistance_Temperature_Detective_materials_As_Thermo_Power_Generation_Elements
Hope it helps!
Great thanks.
Can hot air be used to generate electricity through peltire module?If yes then the min temperature of air will?
Hi, Hot air can be used to generate electricity with the Peltier module, although it would be less efficient. The minimal temperature needs to be higher than the “cold” side. You could also generate more power by increasing the temperature of the hot air.