Arduheater is a full open source intelligent heat strip controller for astronomy usage.
Controlling dew is a big thing if you really intent to do astronomy all year around. This project will allow you to build a four channel intelligent heat strip contoller for less than 10€.
This was a very important part of the design, most heat controllers, specially the DIY ones, rely on the PWM signal for each channel being manually adjusted by means of a potentiometer. This either requires the user to be near the device tweeking it or to set it to a temperature that may be higher than the one really needed thus completely trashing efficiency. Arduheater uses a serial connection so you can use any USB-Serial-TTL dongle to adjust it's settings either you're 2 or 2000 meters away.
Manual adjusted heater will either require the user to be tweeking it or they will wast more energy than necessary due to the general tendency to use a higher that required setpoint, this is valid for any PWM or bang-bang style controllers. Arduheater uses a temperature sensor (DHT22) to measure basic environmental properties such as temperature and humidity, knowing them both makes the calculation of the dew point[1] possible. Arduheater also has a temperature sensor (NTC) for each heating strip, allowing the micro-controller to have a rough estimation of the temperature the equipment is at; it will be a rough estimation because we are really interested on the lenses surface temperature but we are actually measuring the heat strip temperature, to mitigate this, Arduheater allows the user to set specific offsets per heating strip.
Arduheater uses a PID controller[2] to efficiently manage the energy so only the required amount of energy to maintain a temperature setpoint is delivered to the heating strip. This is possible due the usage of a PWM signal while driving the outputs; the delta between the environmental dew point (plus offset, i.e. setpoint) and the heating strip temperature will make the micro-controller output a PID-calculated PWM signal until this delta reaches zero. In practical terms if a 12V heating strip full on consumes 12W of power (1A) it may be possible for it to use only 1W or even less to keep the equipment above dewpoint and the power usage will be automatically updated during the night as conditions vary, so the system will be always using the least amount of power to keep the dew away.
[1] Dew point is that dreadful threshold at which water condensation starts to happen on the lenses/equipment.
[2] A proportional–integral–derivative controller (PID controller) is a control loop feedback mechanism (controller) commonly used in industrial control systems.
Using off-the-shelf components such as the Arduino Nano and easily available parts Arduheater is aimed to be build by anyone with a soldering iron and some patience, no degree in electronics required.
Each of the four outputs have independent controls such as offset, min and max output power and of course the three main properties of the PID controller (Kp, Ki and Kd).
It was built on top of a standard ATmega 328 Arduino such as UNO, Pro or Nano; currently it does not support the Mega or any other ARM based board.
| Qty | Value | Device | Size | Package |
|---|---|---|---|---|
| 1 | Nano 328P | Arduino | ||
| 1 | 10uF | Capacitor Polarized | "Ø5x11 | THT |
| 1 | AM2320 | Probe | THT | |
| 4 | 100nF | Capacitor Ceramic | 3216 | SMD |
| 4 | 1K | Resistor | 3216 | SMD |
| 4 | 1N4004 | Diode | DO41 | |
| 4 | IRF3205 | N-MOSFET | TO220 | |
| 4 | EL817 | Optocoupler | DIP4 | |
| 4 | Red | LED 3mm | THT | |
| 4 | 10K | NTC | THT | |
| 4 | M+F kit | XLR | 12mm | GX12 |
| 5 | 2P | Screw Terminal | 5mm | THT |
| 8 | 220R | Resistor | 3216 | SMD |
| 9 | 10K | Resistor | 3216 | SMD |
Note: It is very important to have a inline fuse on the 12V feed line.
To download and print instructions for the 3D printed parts have a look at the Thing #2614341.
For the complete Eagle files have a look at the PCB folder, as an alternative you may perfer to build the Preforated Board version.
