Dear All,I am trying to run a sanity check on the motor size of the following World War 2 military "turntable" rail system:
Question: would 4x 13.5 hp have sufficed to “get the train going” and accelerate it to the nominal speed? How long might that have taken?Thanks in advanced!-- Fred
100 tonnes on 32 steel wheels... all we know is 100 tonnes on 8 wheels rolling at a constant 5 mph would take much less than 54 horsepower-- a tenth of that would likely suffice. So you can make a fair guess at the acceleration if you know the maximum tractive effort-- do you know that?
Thanks timz!
What I listed is about the only info that I have. Given the low speed, the part of the resistance/friction that depends on speed or speed-squared, might be negligible. That would leave primarily the friction of the old fashioned bearings.
Here are pictures of the locos:
Yeah, that's always a mystery with trains too-- what does it take to get a friction-bearing car moving before the oil has coated the bearing.
For more on thie FuSAn, go here..
Some information about required speed is here; note that acceleration to operating rotational speed iappears to be relatively unimportant. Continuous speed is for 12 deg/s, or a rotation in 30 sec (2rpm); that works out to a speed of about 8.3 km/h or 5.2 mph, so there's your HP basis...
Cool stuff there. Some time back, I was thinking of ways of making a large moonbounce array using circular 15" gauge track, though didn't have the land or financial resources to set up such a beast.
As far as power requirements... A conservative guess for rolling resistance would be 0.3% of applied weight, so for 100 tons that would work out to 600 pounds. At 5mph, 1HP would provide 75 pounds of tractive effort (375/5), so 600 pounds would the require 8 HP. The 600 lb figure DOES NOT include wind forces, though I would think that the designers would take care to have the aerodynamic forces somewhat balanced around the axis of rotation, doubling the HP might take care of that.
- Erik
Thanks Erik!
So, having 4 x 10 HP motors (somewhat less than 10 HP at the driven wheels due to gearing etc), would have been quite adequate to maintain speed.
Any guess if 4 x 10 HP motors would have sufficed to overcome resistance at stand-still?
Yes, the load is symmetrical about the axis of rotation of the turn-table, so that would balance the wind load.
- Fred
Series motors can produce a starting torque that is much higher than continuous running torque, so I wouldn't think there would be a problem with overcoming resistance at stand still.
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