Ummmm...second attempt->
Hello all.
This question is not directly related to RE, but more to magnetic circuit theory in general.
I have simulated an eddy current device in FEMM- a simple twin stator axial flux permanent magnet device with a 10mm aluminum plate passing between the stators. This is fine, the result shows around 0.7T in the air gap, which I think is reasonable. Predicting braking force using FEMM is beyond me at the minute- I am using the air gap flux density and the equation at the bottom of page 3 of this paper to calculate braking force
www.thompsonrd.com/OSEE-brakes.pdf .
Qualitative results pic:
In the model, I have selected M-19 steel as the material of the stator back plates. What I would like to use is a basic mild (carbon) steel. Does anyone have a source for a BH curve for standard mild steel materials?
Not wanting to simply trust FEMM blindly, I would like to calculate the approximate air gap flux density by hand. To this end, I am attempting this by two techniques:
1. Using the magnetic equivalent of ohms law, mmf = Phi
R and an equivalent magentic circuit of my device.
R, the combined reluctance of each component is simple. Phi is what I am trying to find, as I can divide this by the magnet face area to get an approximate flux density. I find mmf for a PM magnet using magnetic field intensity of a N40 NdFeB magnet, H = 900 kA/m (roughly) and the magnet's 'height', l. mmf = Hl. Eventually, this gives a fairly similar answer to FEMM of about 0.7T. Great!
2. Following the numerical example given in Axial Flux Permanent Magnet Brushless Machines, page 19 - 20, Numerical Example 1.1 (Faraday's disc).
This can be found here
http://www.scribd.com/doc/25388810/Axial-Flux-Permanent-Magnet-Brushless-Machines, by keying in '31' to the page number box in grey at the bottom of the page.
I realise this is somewhat different to the problem I am looking at, but the technique is what Im interested in. The first part of the example is the calculation of the air gap flux density, though not by method 1 mentioned above. Instead, they find the 'relative recoil permeability', the 'saturation factor', and then use these in 'Kirchhoff's magnetic voltage law'. My questions on this are as follows:
a. Is the second method more accurate? I cannot see that it takes into account fringing effects or other effects that are neglected in the first method.
b. What is recoil permeability, and why is this used rather than regular permeability?
c. Kirchhoff's magnetic voltage law- is this that the sum of mmf around a circuit = zero?
d. I realise this is a lot to ask, but perhaps other people will be interested- in the numerical example I think there is a mistake in the final line of part (a), where they have introduced incorrect terms in to the equation. This leads to a low estimate of Bg.
I hope that is understandable!
Cheers
Matt
