How to find torque on planet carrier

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SUMMARY

The discussion focuses on calculating the torque on a planet carrier in an epicyclic gear train with specified angular speeds and torques. Given the angular speeds of the ring (1500 rpm) and sun (3200 rpm), along with their respective torques (190 Nm and 50 Nm), the power balance method is employed to derive the torque on the carrier. Two potential torque values for the carrier are calculated: 231.169 Nm using the sum of powers and 64.93 Nm using the difference of powers. The direction of the torques remains a critical factor in determining the correct value.

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  • Understanding of epicyclic gear trains
  • Basic principles of torque and power calculations
  • Familiarity with angular speed and its units (rpm)
  • Knowledge of energy flow in mechanical systems
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csiddharthn
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I have the following data in an epicyclic gear train:

Angular speed on ring = 1500 rpm, teeth on ring = 30
Angular speed on sun = 3200 rpm, teeth on sun = 10
Angular speed on carrier = 1925 rpm, teeth on planets = 10

(The ratios of teeth are for simple calculation assumed 3: 1: 1 among ring, sun and carrier.)

Now,

torque on ring = 190 Nm
torque on sun = 50 Nm

How do I find the torque on the planet carrier?
 
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Hi Csidd,

A question for you; when you mention that there are torques on the ring and sun gears, does this mean that they are the two inputs to the system and that the carrier is the output? If so I think you can use a power balance. Ideally, power out = power in. Not ideally, power out = efficiency*power in. Also, can you specify the directions of the rotations?
 
I have not checked your gear ratios and relative RPMs.
Analyse the energy flow per minute.
power = rpm * torque

Wsun = 3200 * 50 = 160 k
Wring = 1500 * 190 = 285 k

The problem is that we do not know the direction of the torque.

There are two possible solutions.
The sum = 445 k
445 k / 1925 = 231. 169 Nm

The difference = 125 k
125 k / 1925 = 64.93 Nm
 

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