I've built a stand comprised of four screw jacks ganged together. (Teach me not to wander from the electrical reservation!)
[unloaded]
I did meticulous empirical testing to discover how much force needed on a specific moment arm was required for one of these jacks to lift X pounds.
I rounded everything up and used the next size up of everything.
It is driven by a gear drive motor @ 60Hz that is rated at 10.15Nm @ 158RPM (250W)
[motor plate]
It goes up and down 'just great' taking about 2 minutes... Unless the design load is on it! The load is 3,000lbs.
My test load is 1.60 tons(3,200lbs) accurately measured on commercial scales.
[loaded]
The motor starts very, (very), hard then continues raising the load up the 18in distance while drawing 550W. Near the top ~15 inches it really starts bogging. Hitting 900W and and pulling 8+amps into the 120V voltage-doubling VFD just before stalling entirely.
First thought was that the four jacks are binding up tight and just bringing everything to screeching halt. A plan was hatched to test this theory. A sprocket had a nut welded to it and a bending-bar torque wrench was used to continue lifting after a stalling point with the motor was reached. The nut/sprocket was mounted onto the motor's shaft.
You can just see the nut/sprocket on the end of the motor shaft - the second sprocket.
[oblique]
[Larger image]
No hard binding was detected. It just takes 19.5~20.0ft-lbs to continue raising the load. It continues up smoothly with no hitches at the 20ft-lbs. By hand, slow or fast, the 20 is constant.
This looks to me like (20 x 158)/5252 = 0.6hp ~ 450W which is pretty much being shown by what I'm seeing.
Presently the gear train includes the motor and its gear box. This is followed with a 19T sprocket driving a 60T sprocket. Using two other 60T sprockets the power is transmitted to the opposite side.
Their is no hurry as the system takes about 2 minutes to raise unloaded, five minutes presents no operational issues. My thought is to increase the ratio further.
[above gear train]
I'm looking for suggestions. Something that will fit the present geometry without major surgery. Something like 3:1 maybe. I'm seeing no suitable way without a bunch of changes.
Keith Cress
kcress -
[unloaded]
I did meticulous empirical testing to discover how much force needed on a specific moment arm was required for one of these jacks to lift X pounds.
I rounded everything up and used the next size up of everything.
It is driven by a gear drive motor @ 60Hz that is rated at 10.15Nm @ 158RPM (250W)
[motor plate]
It goes up and down 'just great' taking about 2 minutes... Unless the design load is on it! The load is 3,000lbs.
My test load is 1.60 tons(3,200lbs) accurately measured on commercial scales.
[loaded]
The motor starts very, (very), hard then continues raising the load up the 18in distance while drawing 550W. Near the top ~15 inches it really starts bogging. Hitting 900W and and pulling 8+amps into the 120V voltage-doubling VFD just before stalling entirely.
First thought was that the four jacks are binding up tight and just bringing everything to screeching halt. A plan was hatched to test this theory. A sprocket had a nut welded to it and a bending-bar torque wrench was used to continue lifting after a stalling point with the motor was reached. The nut/sprocket was mounted onto the motor's shaft.
You can just see the nut/sprocket on the end of the motor shaft - the second sprocket.
[oblique]
[Larger image]
No hard binding was detected. It just takes 19.5~20.0ft-lbs to continue raising the load. It continues up smoothly with no hitches at the 20ft-lbs. By hand, slow or fast, the 20 is constant.
This looks to me like (20 x 158)/5252 = 0.6hp ~ 450W which is pretty much being shown by what I'm seeing.
Presently the gear train includes the motor and its gear box. This is followed with a 19T sprocket driving a 60T sprocket. Using two other 60T sprockets the power is transmitted to the opposite side.
Their is no hurry as the system takes about 2 minutes to raise unloaded, five minutes presents no operational issues. My thought is to increase the ratio further.
[above gear train]
I'm looking for suggestions. Something that will fit the present geometry without major surgery. Something like 3:1 maybe. I'm seeing no suitable way without a bunch of changes.
Keith Cress
kcress -