Anything which propels air downwards with sufficient force to counteract your own weight under gravity will do the job. Essentially what you're asking about is a downward-ducted jet engine:Alternatively, you have a helicopter:Or a bunch of rockets (this is an artist's conception of the Curiosity lander):A "reverse vacuum cleaner effect" is really just a "blower".  There are a few practical problems:A vacuum cleaner uses an electric motor, powered at 120 v and about 12 amps.   When free falling, where does your power source come from? A vacuum cleaner motor and blower doesn't put out much thrust.  If it did, it would blow itself across the room.  That's not enough thrust to support even it's own weight, let alone yours.You need enough thrust to support your weight, the weight of your vaccum cleaner, the weight of your power source, and to overcome all the energy gained during free fall of the aforementioned.Honestly, I can't think of any electrical power source that is sufficiently lightweight and has a high enough power density to be able to power an electric blower that is powerful enough to stop a free fall descent of a human and the accompanying equipment.vacuum cleaner

For a pet project I am doing (trying to fly a kite using my computer) I need to move and reverse an electro motor to my liking (I took the motor from an old hand-held vacuum cleaner). I need to control this movement from a Raspberry Pi. From what I understand there are 3 basic types of electro motors: DC, Single phase AC and 3 phase AC. From these three only the DC motor reverses when you switch polarity (which I guess means switching positive and negative). On this page however, I read that "for a DC motor which has a wound field winding instead of a permanent magnet you have to reverse the connections either to the field winding or to the armature.". And here I'm lost. So I thought to simply try it out: I hooked up the + of the battery to the - of the motor and vice versa. The motor did in fact move, but still in the same direction and a lot slower. Unfortunately, after a few seconds it smelled like something was burning. So I quickly took the load of the motor. Luckily it still works..

The things I now wonder about are: What kind of motor do I have (see pics below)? How do I reverse this motor? Can I reverse this motor from the Raspberry Pi using the Gertboard's on board motorcontroller (as far as I understand the motorcontroller on the Gertboard simply reverses the positive and negative when it wants to reverse the motor)? If this motor cannot be reversed using the Gertboard, where would I be able to get a motor that can actually be reversed using the Gertboard (preferably by getting it from an old home appliance)? All tips are welcome! The components on the back of the motor are three capacitors to suppress the contacts, and a diode to protect whatever switched it from a back-emf. If you reverse the polarity without removing the diode, then you will just put the current through the diode not the motor, and possibly either destroy it or damage your power supply, or both. So you need to remove the diode, and if you are using a simple transistor to switch the motor, provide some other protection.

If you're using an h-bridge with diodes, then you're ok (I'd imaging the gert-board does, but don't know for certain). You also need to remove the larger black capacitor - it is polarised, so will be damaged and possibly explode if you connect it the wrong way round. bagless vacuum cleaners pricesPreviously the diode prevented the current going through it when you did that. sam club vacuum cleanerIf the motor generates lots of electrical noise when you run it without the capacitor - interfering with radios and so on - then you will need to add a similar value of non-polarised capacitor to suppress that.cleaning henry vacuum cleaner Also check that board you're using can supply the motor's required current.

In addition to Pete's answer (which is completely correct): You have a permanent magnet DC motor,most likely with carbon brushes. This would normally be reversible simply by reversing its supply connections, as you first tried (after removing or reversing the diode and big capacitor as Pete recommends. However it is likely that the motor is tuned to run in one direction only. This is done in a brushed motor by rotating the brushes in the direction of rotation (a little bit like advancing the ignition on an IC engine) so that the magnetic field builds up in time to do the most good. It also reduces sparking when the brushes break contact. Looking at the motor, there is a slot through which you can observe the brushes : check for visible sparking both ways round. It may also be possible to adjust the brush position through this slot with a suitable tool, if you are brave enough. However, even if the motor will run backwards well enough, it is driving a ducted fan.

The curved blades will stall when reversed, and deliver a fraction of the expected thrust, possibly consuming higher than normal current. Check the current on the bench. The reduced thrust may or may not be a problem in your application... If you can't do what you need by reversing the motor, mount the whole ducted fan in gimbals and rotate it 180 degrees. The motor in the question has an electrolytic, polarized capacitor, and a diode, across its leads - this in itself clearly says that the motor was not supposed to be driven with reversed polarity. The capacitor in question is the black can. The burning smell was either the short-circuit through the diode frying your wiring, or if the diode had already failed, the capacitor getting extremely upset at being connected to an inverted polarity. You may have been fortunate in that electrocaps tend to explosively express unhappiness at being connected the wrong way around. The white strip on the capacitor casing, seen at the left edge of the capacitor in the last photo, indicates the negative voltage connection.

That the motor moved at all in reverse seems to indicate that the diode had already blown, and the power the motor was receiving was whatever was left over after leakage across the reversed capacitor - not much. That may explain the slow reverse rotation. Do not use that motor even with the correct polarity before replacing that capacitor and the diode. Further, check if the motor can run acceptably in reverse at all, as the other answers have pointed out. For operating a DC motor in either direction, use a H-bridge circuit: Instead of discrete MOSFETs or transistors, you can also use a H-Bridge IC such as the Freescale Semiconductor 5 Ampere H-bridge MC33887 or Texas Instruments DRV8837, so long as the voltage and current requirements of your motor are met by the IC selected. Also, replace the capacitor with an unpolarized one (for electromagnetic noise suppression, if this is necessary), remove the diode from the motor leads and use 4 suppression diodes at the H-bridge terminals, as shown in the above diagram.