electricpete
Electrical
This is the oil reservoir on a vertical motor.
A figure is on page 1 here:
The oil reservoir is sealed from atmosphere (although not expected to deviate significantly from atmosphere due to many different joints that may not be airtight). Connected below the oil level is a tap for a sightglass that is vented to atmosphere.
We have experienced oscillation of the oil level visible in the sightglass (we can't see what the reservoir is doing).
I vaguely remember seeing some textbook problem about a manometer or something similar where natural frequency could be calculated.
I tried to lay out the problem as a SDOF mass/spring system and solve on pages 2 and 3.
Since the reservoir cross sectional area is so much larger than the sightglass area, I focused on the oil in the reservoir. If level goes up by a small distance detlah, the trapped air is compressed which tends to push it down. I neglected any effects of the attached sightglass. I also assumed the relevant mass was the mass of oil in the reservoir above the sightglass tap. That makes some intuitive sense to me, but I can' articulate a firm basis for doing that.
I have neglected effects of the small portion of oil around the standpipe and inside the bearing which may be subject to a different pressure (the pressure associated with rotor suction).
Any comments on the model? Is it correct for the simplified system that I am trying to model?
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Eng-tips forums: The best place on the web for engineering discussions.
A figure is on page 1 here:
The oil reservoir is sealed from atmosphere (although not expected to deviate significantly from atmosphere due to many different joints that may not be airtight). Connected below the oil level is a tap for a sightglass that is vented to atmosphere.
We have experienced oscillation of the oil level visible in the sightglass (we can't see what the reservoir is doing).
I vaguely remember seeing some textbook problem about a manometer or something similar where natural frequency could be calculated.
I tried to lay out the problem as a SDOF mass/spring system and solve on pages 2 and 3.
Since the reservoir cross sectional area is so much larger than the sightglass area, I focused on the oil in the reservoir. If level goes up by a small distance detlah, the trapped air is compressed which tends to push it down. I neglected any effects of the attached sightglass. I also assumed the relevant mass was the mass of oil in the reservoir above the sightglass tap. That makes some intuitive sense to me, but I can' articulate a firm basis for doing that.
I have neglected effects of the small portion of oil around the standpipe and inside the bearing which may be subject to a different pressure (the pressure associated with rotor suction).
Any comments on the model? Is it correct for the simplified system that I am trying to model?
=====================================
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