While making this video I accidentally deleted all the original animation files and video files not once but TWO TIMES!! Set me back by three months! I almost gave up when it got deleted the second time, but I decided to complete the video at any cost. I knew it would be worth it in the end. Hence the late upload. Sorry about that. I choose quality over quantity. My next video will be mind-blowing, I promise!
Outstanding work! I would suggest you use software like TimeMachine(Mac), BackInTime(Linux) or any equivalent if you are using Windows. It is literally a lifesaver. It helps not only if you accidentally delete your files, but also if anything gets corrupted or in case you make an irreversible change to your work you would like to revert.
@@sygdesignworks And that's the right thing to do! The kind of software I'm suggesting you, though, is not a replacement for your backup scheme. It's used on your main disk (which contains the files you are currently working on) and enables you to revert from changes you have made to a specific time. For example, if you are currently working on an animation and you make a change you don't like, you can make your files as they were right before you made that change 2 hours or 2 days before, for example. This is also handy if you accidentally delete a file. You can immediately find it in your "data history". No need to revert to the last time you manually made a backup (which would be probably outdated). Trust me. You should definitely give it a try. Keep up the good work! Cheers
In order to tilt the rotor disk forward, the swash plate is tilted to the left. Not forward. Gyroscopic phenomenon. And so on for the other tilts. Backwards = swashplate tilt to the right Left = swashplate tilt backwards Right = swasthplate tilt forward (if the rotor is turning clockwise, in top down view. The oposite is true if the rotor is turning counter clockwise) 👍👍👍👍
@@jasonnhu3338 ...I'm not sure brother. I'm about 73.28% sure that is how things work in the real world, and another 5-6% that it's the same in the RC world, but I can't realy tell for sure. I'm not a mechanic. I just saw a couple of videos. Would be nice to find a video that explains it. 👍👍👍
@@mr_nice. whenever you see the linkage go straight up from swashplate to the main blade grip without phasing, then it will work just like in the video. Other case, if the linkage is 90 deg not directly from the swashplate, i.e., the linkage came up from the swashplate and then links to a mixing arm, then from the other end of the mixing arm links to the main grip 90 deg from the first start of the 'joint'.
All depends on what kind of servo setup you are using, yes in some applications you are correct but not in all "90 degrees one servo" or "CCPM 120 degrees" so you are half right. 👍
Fantastic Animation video so beautifully explained ....a complex flying machine such as a helicopter. One feature of precession may have been deliberately missed out. Maybe it is difficult to understand by a hobbyist. Hope to see many such videos in times to come. All the best in your remarkable venture.
That’s my align trex 450se v2! 😅 The first collective pitch RC helicopter I flue! I still have it! Still flybar, 3s but I’ve got 6s motor to upgrade it and then I will covert it to flybarless finally! 😅 Great job with the animation!
If you want to yaw the helicopter left and the main rotor blade is rotating clockwise then you would turn the lift off on the tail rotor. The torque is what yaws the helicopter to the left. If you want to yaw right then you add lift to the tail rotor to pull the tail to the left. You said that lift was applied in both directions to the tail rotor to control left and right yaw. I always thought the torque would yaw you in one direction and the tail rotor lift would yaw you in the other direction.
Amazing Video!!! Wish I knew all this earlier. I have a top of the line RC helicopter that I still haven’t flown. Any videos on the buttons on the remote? Thank you!!
The model being used in this video is a old skool "flybar" head, would really like to see one made on how a flybarless head works in hand with a gyro. 👍
You actually have to offset the swashplate actuators by 90° (gyroscopic precession) or it will never fly as intended. Also there are other differences with how a true chopper works, but I guess for those ones it's because it's a RC helicopter.
Correct. But that works when the control rods are going straight to the rotor blades. Here the the mixing lever is doing that 90 degree phasing. Thanks for watching.
There's a potentiometer in servos that controls the angle of the servos. The servos move depending on the input received from the wireless transmitter.
@@sygdesignworks onu biliyorum izlediğim başka videolarda da kumandadan verilen komutla 3 servo motor aynı anda ve kumandanın başka dugmesiyle verilen komutla ayrı ayrı hareket ediyor bunun bir sistemi varmı
@@kasifyldrm1981 Yes. They are called "mixing". In the transmitter, there is an option to mix controls. The mixing will make your servos move simultaneously as well as individually depending upon what you are controlling. You can even make them move opposite to each other.You can find plenty of videos about transmitter channel mixing.
In this model, due to the specific arrangement of the control rods and the mixing lever, there will be no phase shift. Therefore no gyroscopic precession.
in you explanation you ignored gyroscopic force completely. everythings act 90 dagree after you applied the force. to pitch forward you need move down swashplate in the right.
The gyroscopic precession doesn't work on this model, because of the way the control rods are connected to the blades. There is no 90 degree phasing when the rods go from the mixing lever, therefore the gyroscopic precession is absent. Thanks for watching.
YOU HAVE AN ERROR there, tilting swash plate forward NEVER tilt rotor disc fowrard. THERE IS ALWAYS 90° DELAY. At least at real helicopters. Look at UH-60 swash plate control and at what angle the pitch horns are mounted on blades.
In this model, the placement of the mixing lever against Swashplate with the control rod will cancel the phase-shift. In UH-60, the control rods goes straight from the swashplate to the rotor blades directly. Here the control rods go from swashplate to mixing lever and then to the blades.
The explanation of rolling is totally wrong. The action of a helicopter involves the gyro effect that make the any action output delay 1/4 cycle. For example, if you need the helicopter rolls forward, actually you are giving positive pitch on right side (when the blade is rotating clockwise)
Not wrong at all bro. Take a look at how linkage goes straight to the blade grip from the swashplate. The gyroscopic precession occurs only when there is a phase shift of 90 degrees.
@@sygdesignworksThe gyroscopic precession always exists (it's physics) but your model automatically applies a 90 deg phase shift between swashplate and blades. Your animation is correct (swash forward will pitch forward), but the explanation is wrong. Pitching the swashplate forward increases / decreases pitch at 90 degrees in your model, resulting in lift asymmetry on the roll axis. Due to precession this results in pitching of the heli.
While making this video I accidentally deleted all the original animation files and video files not once but TWO TIMES!! Set me back by three months! I almost gave up when it got deleted the second time, but I decided to complete the video at any cost. I knew it would be worth it in the end. Hence the late upload. Sorry about that. I choose quality over quantity. My next video will be mind-blowing, I promise!
Outstanding work! I would suggest you use software like TimeMachine(Mac), BackInTime(Linux) or any equivalent if you are using Windows. It is literally a lifesaver. It helps not only if you accidentally delete your files, but also if anything gets corrupted or in case you make an irreversible change to your work you would like to revert.
@@dimitris2521 @dimitris2521 Thanks a lot! I now save my files in different devices as backup. Thanks for the suggestion.
@@sygdesignworks And that's the right thing to do! The kind of software I'm suggesting you, though, is not a replacement for your backup scheme. It's used on your main disk (which contains the files you are currently working on) and enables you to revert from changes you have made to a specific time. For example, if you are currently working on an animation and you make a change you don't like, you can make your files as they were right before you made that change 2 hours or 2 days before, for example. This is also handy if you accidentally delete a file. You can immediately find it in your "data history". No need to revert to the last time you manually made a backup (which would be probably outdated). Trust me. You should definitely give it a try.
Keep up the good work! Cheers
@@dimitris2521 Thanks a lot!
That's more than 👍 ok! You are human!! I loved the technical details in your video!👍 loved it, thanks!
Thank you for this amazing video Sir❤️. Very nicely explained and animated👍. Love from India🇮🇳❤️
Thanks a lot! Thank you for watching!
Thank you soo much brother. I understood 100% about helicopters.
Thanks a lot!
No words to describe this beautiful video.
Thanks a lot!
In order to tilt the rotor disk forward, the swash plate is tilted to the left. Not forward. Gyroscopic phenomenon.
And so on for the other tilts.
Backwards = swashplate tilt to the right
Left = swashplate tilt backwards
Right = swasthplate tilt forward
(if the rotor is turning clockwise, in top down view. The oposite is true if the rotor is turning counter clockwise)
👍👍👍👍
That only works when you phasing the rotor 90 deg from the swashplate
@@jasonnhu3338 ...I'm not sure brother. I'm about 73.28% sure that is how things work in the real world, and another 5-6% that it's the same in the RC world, but I can't realy tell for sure. I'm not a mechanic. I just saw a couple of videos. Would be nice to find a video that explains it. 👍👍👍
@@mr_nice. whenever you see the linkage go straight up from swashplate to the main blade grip without phasing, then it will work just like in the video. Other case, if the linkage is 90 deg not directly from the swashplate, i.e., the linkage came up from the swashplate and then links to a mixing arm, then from the other end of the mixing arm links to the main grip 90 deg from the first start of the 'joint'.
@@jasonnhu3338 ......you lost me after the mixing arm 😂😂😂
All depends on what kind of servo setup you are using, yes in some applications you are correct but not in all "90 degrees one servo" or "CCPM 120 degrees" so you are half right. 👍
Good job! Thank you for video
Thanks a lot!
Fantastic Animation video so beautifully explained ....a complex flying machine such as a helicopter. One feature of precession may have been deliberately missed out. Maybe it is difficult to understand by a hobbyist. Hope to see many such videos in times to come. All the best in your remarkable venture.
Thank you very much! Thanks for watching.
Very informative. It explained a lot. I’ll probably watch it several times
Thanks for watching!
FANTASTIC GOD BLESS YOU
Thanks a lot! Thank you for watching.
That’s my align trex 450se v2! 😅 The first collective pitch RC helicopter I flue! I still have it! Still flybar, 3s but I’ve got 6s motor to upgrade it and then I will covert it to flybarless finally! 😅
Great job with the animation!
Thanks for watching!
Great animation. Things become to be clear ..... Thank you so mcuh for this great job.
Thanks a lot! Thanks for watching!
thank you this was very easy to understand
Thanks for watching!
The front two servos need to be rotated 180 to allow the linkages to be perpendicular to the main shaft
I love flying rc planes and helis, very nice video!
Thanks for watching!
nice animation, a few mistakes but still very informative
I like it ,it looks very beautiful, and I went to learn how to fix it
brilliant
Thank you!
Great work keep it up!
Thanks a lot! Thanks for watching!
Very detailed if you're thinking of building one especially 3d printing parts
Thanks for watching!
As a fan of both RC and CG, this was truly spectacular! However, next one, please nix the Ninja Star tail rotors for some realistic ones :)
Thanks for watching!
Bro thats was lit reallly enjoyed it Just feels like professional documentary and the bg music though💙
Thanks a lot!
@@sygdesignworks can you mention back ground music name
@@ONI-CHA I've mentioned all of them in the description.
If you want to yaw the helicopter left and the main rotor blade is rotating clockwise then you would turn the lift off on the tail rotor. The torque is what yaws the helicopter to the left. If you want to yaw right then you add lift to the tail rotor to pull the tail to the left.
You said that lift was applied in both directions to the tail rotor to control left and right yaw. I always thought the torque would yaw you in one direction and the tail rotor lift would yaw you in the other direction.
Amazing 😍😍😍😍😍 video
Thanks a lot!
the way the swashplate linkages would make flying really difficult
Nice
Thanks for watching!
I watched thia specifically for the workings of a flybar. No such luck 😢
Stunning graphics though
Thanks for watching!
Amazing Video!!! Wish I knew all this earlier. I have a top of the line RC helicopter that I still haven’t flown. Any videos on the buttons on the remote?
Thank you!!
I'll make another video on Quadrotors, I'll explain the transmitter in that video. Thanks for watching!
@@sygdesignworks thanks a million Times!!! Your vidéo is at another level and never seen such clear explanations.
@@actionman67 Thanks a lot! You might like my F-35 video :)
Parabéns pelo trabalho☆
Thanks a lot!
Great Job... i want radio control 6 channel Schmetic diagram please.
I downloaded it from some website. I uploaded this video almost an year ago, so I don't remember the name of the website. Thanks for watching.
The model being used in this video is a old skool "flybar" head, would really like to see one made on how a flybarless head works in hand with a gyro. 👍
Great idea! I wanted to make a video on flybarless one too. Thanks for watching!
You actually have to offset the swashplate actuators by 90° (gyroscopic precession) or it will never fly as intended.
Also there are other differences with how a true chopper works, but I guess for those ones it's because it's a RC helicopter.
Correct. But that works when the control rods are going straight to the rotor blades. Here the the mixing lever is doing that 90 degree phasing. Thanks for watching.
You forgot the guroscopic precession, blades tils 90 degrees earlier in every position.
Not in this model. Observe The mixer arm arrangement. It will counter the gyroscopic precession.
Would it be possible to do a similar simulation about a Coaxial Helicopter, please?
Sure! I'll make one on Coax heli. Thanks for watching!
😊😊😊
Thanks for watching!
kỳ diệu
Thanks a lot!
Is there any code needed in this totally about to take this on as a engineering challenge
Nope. No coding needed to build an RC Helicopter. But, coding is needed if you are making your own transmitter - Receiver and flight controller.
How can I afford it
No Idea. Thanks for watching!
Merhaba kolay gelsin 3 adet servo motoru ayni anda hareket ettirmek için ve sonra ayrı ayrı hareket etmesini için nasıl bir sistem kullanılıyor
There's a potentiometer in servos that controls the angle of the servos. The servos move depending on the input received from the wireless transmitter.
@@sygdesignworks onu biliyorum izlediğim başka videolarda da kumandadan verilen komutla 3 servo motor aynı anda ve kumandanın başka dugmesiyle verilen komutla ayrı ayrı hareket ediyor bunun bir sistemi varmı
@@kasifyldrm1981 Yes. They are called "mixing". In the transmitter, there is an option to mix controls. The mixing will make your servos move simultaneously as well as individually depending upon what you are controlling. You can even make them move opposite to each other.You can find plenty of videos about transmitter channel mixing.
You didn't use the concept of gyroscopic precession.
In this model, due to the specific arrangement of the control rods and the mixing lever, there will be no phase shift. Therefore no gyroscopic precession.
in you explanation you ignored gyroscopic force completely. everythings act 90 dagree after you applied the force. to pitch forward you need move down swashplate in the right.
The gyroscopic precession doesn't work on this model, because of the way the control rods are connected to the blades. There is no 90 degree phasing when the rods go from the mixing lever, therefore the gyroscopic precession is absent. Thanks for watching.
YOU HAVE AN ERROR there, tilting swash plate forward NEVER tilt rotor disc fowrard. THERE IS ALWAYS 90° DELAY. At least at real helicopters. Look at UH-60 swash plate control and at what angle the pitch horns are mounted on blades.
In this model, the placement of the mixing lever against Swashplate with the control rod will cancel the phase-shift. In UH-60, the control rods goes straight from the swashplate to the rotor blades directly. Here the control rods go from swashplate to mixing lever and then to the blades.
COMMENT ON FAIR SAI IMAGES LA CEST LE 3DMAYA
Sorry I don't use Maya. Thanks for watching!
🇧🇩🇧🇩🇧🇩🇧🇩🇧🇩❤❤❤❤❤
Thanks for watching!
Hills of steel😂
The explanation of rolling is totally wrong. The action of a helicopter involves the gyro effect that make the any action output delay 1/4 cycle. For example, if you need the helicopter rolls forward, actually you are giving positive pitch on right side (when the blade is rotating clockwise)
Not wrong at all bro. Take a look at how linkage goes straight to the blade grip from the swashplate. The gyroscopic precession occurs only when there is a phase shift of 90 degrees.
@@sygdesignworksThe gyroscopic precession always exists (it's physics) but your model automatically applies a 90 deg phase shift between swashplate and blades.
Your animation is correct (swash forward will pitch forward), but the explanation is wrong. Pitching the swashplate forward increases / decreases pitch at 90 degrees in your model, resulting in lift asymmetry on the roll axis. Due to precession this results in pitching of the heli.
Nice
Thanks for watching.