Today we are going to tear down another automatic room deodoriser. Why?
Well the first attempt beat me, so it was time to even the score and try again with another type. The supermarket had the following units for $7.99, which seemed a little too cheap:
The “satisfaction guarantee” gave me a chuckle, the thought of writing to SC Johnson complaining that their products were not that hackable would be interesting. But would it be hackable at all? Let’s find out. The packaging promises a squirt of scent when the unit detects motion, then holds out for 30 minutes until the next release. The word motion hints that there would be a PIR inside the unit. However the instructions mention that the unit does not work that well in dark or bright rooms – which is odd, as PIRs usually work in the dark. Hmm. This unit is somewhat smaller than the previous attempt, yet still offers us a pair of alkaline AA cells:
Moving on, time to start the disassembly process. The rear shows four screws, easily removed:
revealing the fun things:
The motor drive is reduced twice, which then has a geared arm which causes the vertical motion to pressure the cylinder to release the scent. The whole mess of gears was lubricated generously, the whole lot literally came out with the touch of a finger. Removing the gears and goop reveals the motor and control boards, which clipped out easily:
Interesting – a labelled motor. Very good, what looks like to be a 3V DC motor. The control board is made up of two PCBs, a smaller module that holds a control IC of some sort, and the larger, lesser-densely populated board with the button, status LED and “motion detector”. Let’s have a close-up of that PCB:
So we have the button, which causes the motor to run; a yellow LED which blinks once every five seconds; and out motion detector in the black casing. The motion detector seemed rather familiar, so I removed the black housing around it with some pliers, which revealed this:
Huh – that looks just like an LED. The metal object inside the clear casing was even identical to what you would see inside an LED. However, foolishly I broke it off the PCB when removing the housing, so could not get any voltage to it. From reading the instructions earlier on – that mention the light/dark issue, causes me to ponder if this is some sort of light-dependent sensor? Does anyone know about these? If so, please leave a comment at the bottom of this article and we can discuss it. Or it’s just an LED and a scam!
However the motor was definitely not a scam, quite the opposite in fact. Curious to see what is driving it, I hooked up Mr Fluke to see what happens:
Click here to see the video (Youtube seems to be malfunctioning today)
No surprises there, almost three volts DC forward voltage. After applying forward current the circuit applies a quick reverse current to release, thereby causing the gears and arm to ‘squeeze’ down on the scent cylinder. So now we have a circuit board that runs on 3V, which can output 3V for a few seconds every 30 minutes – or at the press of a button.
With regards to current, another measurement was taken:
Click here to see the video
When free-running, the motor draws around 45 milliamps – and the stall current (that is, the current drawn when I force the spindle to stop) is around 675 milliamps. That is quite a strong little motor, and worth the effort. In general, this has been a good tear down, we scored some AA cells, a good motor and gears, some stink spray, and a timing circuit that could have uses elsewhere. So overall a win – the score has evened with the deodoriser world!
If you have any questions about the processes or details in this article, please ask in our Google Group – dedicated to the projects and related items on this website. Sign up – it’s free, there is the odd competition or give-away – and we can all learn something.
High resolution photos available on flickr.
Otherwise, have fun, stay safe, be good to each other – and make something!
– John Boxall, tronixstuff.com