A Basic Guide to Electric Flight
An under-powered model is a disaster waiting to happen, here is a rough guide to choosing the electric power train needed for various model types, bear in mind that over-powering is fine but the penalty is additional weight, and a good model is one that is balanced in terms of power, flying weight and build quality.
This guide is as the title says, a ROUGH guide and offers a basis from which to choose a power train for your model, it is not intended to be a definative guide but will help to get you into the air with performance that will make your introduction to electric flight enjoyable and reliable.
Motor Power Choice
(Based on recommended AUW, or flying weight of model choice)
Vintage types and many non-aerobatic indoor flyers | 50w~70w per 1lb |
Trainers, gliders and high wing scale | 70w~100w per 1lb |
Sport flyer with general aerobatic performance | 100w per 1lb |
Warbirds | 120w~150w per 1lb |
Multi engined models | 100w per 1lb (thrust from Multiple props gives in effect, more than 100w per 1lb performance) |
EDF Jets | 150w~200w per 1lb |
3D, F3A and high performance Models | 150w~200w per 1lb |
Lipoly Voltage Choice
Based on the above, we now need to work out what voltage we are going to need to use, generally, to keep Lipo's in good order, try and keep max amps to around 50~60% of the capacity/C rating of the Lipoly Pack, for example, if you purchase a 2200mAh 20c pack, then it is rated for 44A constant discharge, so keep the max amps at around 20A~25A IF possible, it isn't always! Choose the capacity of pack based on reccomendation for the model by model manufacturer and in conjunction with the size/weight data published with all our advertised Lipoly packs, for low powered models, choose 20c packs, for general flying choose 20c~25c packs, for high performance models 30c + packs.
Up to 50w | 1s~2s |
Up to 100w | 2s~3s |
100w Up to 500w | 3s (This is the practical upper limit for 3s Lipo's, so basically, models of 5lb AUW) |
500w up to 800w | 4s (This is the 0.40~0.46 glow equivalent range favoured by many club flyers) |
800w up to 1000w | 5s |
900w up to 1500w | 6s (this is the 0.60~0.90 ic equivalent range) |
8s~10s packs are for very large and generally specialised models. |
Motor Choice - KV or RPM per volt
Which actually means, what prop size! If you are used to IC, the simple analogy is to treat low kv motors as 4 stroke engine equivalents and mid-high kv motors as 2 stroke engine equivalents, if you are not used to IC then we can give you some examples of the approach to take, this is an important choice as you can literally choose how your model flies, however, their are practical considerations, the most obvious is ground clearance. Please refer to motors such as the NTM range, which give you prop data as well as power, dimension and weight data.
Example 1 | Trainer/Sport Model, 1lb AUW, we want 100w motor (3s 20c Lipoly) mid kv for general flying, probably around 1200kv~1400kv, so around 8" prop |
Example 2 | 3D/F3A Model, 1lb AUW, we want 150w motor (3s 20c~30c Lipoly) low kv, 1000kv or under, spinning 10~11" prop, highly efficient at low throttle openings giving lot's of prop wash over control surfaces at all times, high thrust for low rpm and low amps draw at higher throttle openings. |
Example 3 | Warbird/scale Model, 1lb AUW 120w motor, kv choice, either of the above, it is personal choice |
Example 4 | High Speed Delta type model, 1lb AUW, 200w motor (3s 25c~30c Lipoly) 2200kv~3200kv motor, 5"~6" Prop, high speed/low torque, low thrust at low throttle openings, high speed from high rpm at full throttle. |
Finally, ESC Choice
You have decided on your motor, so look at the MAX AMPS figure given by the motor manufacturer in the data section and generally add 25% headroom, so, if a motor is rated to 15A, then choose at least an 18A ESC, better still a 20A and so on. Next make sure that the ESC voltage is compatible, in other words, if you are using a 4s Lipo, that the ESC is rated for 4s voltage. Next, check if it has functions you desire, if you are flying a glider for instance, you will want a brake facillity so that the prop stops when soaring un-powered, allowing the prop to fold by not windmilling, we strongly advise purchasing a programme card to make programming the ESC easier.
Also look at BEC rating, the BEC supplies radio reciever power for servo's without the need for a seperate reciever battery, however, the can be limited in the number of servo's they are capable of powering, if the servo count is over 4, as it is on many models these days, then consider purchasing an ESC with a high AMP rated SBEC, or a seperate UBEC, OPTO type ESC's (they have no BEC, keeping the ESC seperate from RX suply) are reccomended for large models that require a seperate reciever power supply, they are also safer in high powered, large models as they will not arm until the RX is switched on.
This document is a work-in-progress. Check back regularly as we expand this document.
TURNIGY® Batteries Explained | |
---|---|
Zippy | Great value for money. Average Cycle Life* (100+) and minimal voltage sag under load. |
TURNIGY Standard | Excellent value, Longer Cycle life* (160+) and very low voltage sag under load. |
TUNIGY nano-tech | Unbeatable performance, Longest Cycle Life* (250+) and almost 0 voltage sag under load. |
*Cycle Life results from discharging at full C rate to 3v. End of life when battery has 80% capacity.