Electromagnetic Field Theory: A Problem Solving Approach Part 40

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MagneticField Boundary Value Problems [- 365 2 in 0 = Const r + (')21] R Figure 5-25 Because the curl of H is zero, we can define a scalar magnetic potential H=Vx where we avoid the use of a negative sign as is used with the electric field since the potential X is only introduced as a mathematical convenience and has no physical significance. With B proportional to H or for uniform magnetization, the divergence of H is also zero so that the scalar magnetic potential obeys Laplace's equation in each region: V'x = 0 (7) We can then use the same techniques developed for the electric field in Section 4-4 by trying a scalar potential in each region as FAr cos 0, X=l i rR (Dr+C/r)COs0 f 366 The Magnetic Field The associated magnetic field is then H=VX =Ii,+ •xi. or 1 r 8e aX 4 r sin 0 a8 SA(i, 0-io sin 0) =Aiý, ) 2C/r ) cos i, - (D+ C/r sin Oi, (D - cos r R (9) For the three cases, the magnetic field far from the sphere must approach the uniform applied field: H(r =co) = Hoi, = Ho(i, cos 0-io sin 0)~D = Ho (10) The other constants, A and C, are found from the boundary conditions at r = R. The field within the sphere is uniform, in the same direction as the applied field. The solution outside the sphere is the imposed field plus a contribution as if there were a magnetic dipole at the center of the sphere with moment m, = 4vrC. (i) If the sphere has a different permeability from the surrounding region, both the tangential components of H and the normal components of B are continuous across the spherical surface: 3 He(r=R+)=He(r= R_)=A = D + C/R B,(r = R+)= B,(r = R-):,IH,(r = R+) = A 2 H,(r = R_) which yields solutions C= A = S+Ho, +2 2 +2 ~ 1 1 RSHo (12) M1 The magnetic field distribution is then 3p#lHo 92+ 2 (i, cos 0-ie sin0)= 1L,J+2,' H= Ho [1+ + 2 -H 1 -[1 3~& 1 Hoi. rm ( - l 21AIJ , rR NJsin oR3 The magnetic field lines are plotted in Figure 5-25a when IA2-*o. In this limit, H within the sphere is zero, so that the field lines incident on the sphere are purely radial. The field lines plotted are just lines of constant stream function 1, found in the same way as for the analogous electric field problem in Section 4-4-3b. 367 Magnetic Field Boundary Value Problems .(ii) If the sphere is perfectly conducting, the internal magnetic field is zero so that A = 0. The normal component of B right outside the sphere is then also zero: 3 H,(r = R+) = 0=C = HR /2 yielding the solution H=Ho[(1-) cosOi,-(l +r3)sin0io] R r )2r r>R , The interfacial surface current at r = R is obtained from the discontinuity in the tangential component of H: K, = He(r = R)= -~ Hsin0 The current flows in the negative 0 direction around the sphere. The right-hand rule, illustrated in Figure 5-25b, shows that the resulting field from the induced current acts in the direction opposite to the imposed field. This opposition results in the zero magnetic field inside the sphere. The field lines plotted in Figure 5-25b are purely tangential to the perfectly conducting sphere as required by (14). (iii) If both regions are uniformly magnetized, the boundary conditions are Ho(r = R+)=Ho(r = R_)= A = D + C/R3 B,(r = R+) = B,(r = R_) H,(r = R+)+ Mi cos 0 = H,(r=R_)+M 2 cosO (17) with solutions A = Ho + (MI - M C= 2) 3 R 3 (MI -M 2 ) so that the magnetic field is 1 [Ho+ - (Mi - M2 )][cos Oi, - sin 0io] 3 1 =[Ho+-(M 1 -M H= 3 , (H HoT 3 2R (M3 -H+3r3 2 )]i, rR Because the magnetization is uniform in each region, the curl of M is zero everywhere but at the surface of the sphere, 368 The Magnetic Field so that the volume magnetization current is zero with a surface magnetization current at r = R given by Km = nx (Mi - M 2 ) = i, x (MI - M 2 )i. = i, x (MI - M 2 )(ir cos 0 - sin Bio) = - (MI - M 2 ) sin 0ik 5-8 (20) MAGNETIC FIELDS AND FORCES 5-8-1 Magnetizable Media A magnetizable medium carrying a free current J1 is placed within a magnetic field B, which is a function of position. In addition to the Lorentz force, the medium feels the forces on all its magnetic dipoles. Focus attention on the rectangular magnetic dipole shown in Figure 5-26. The force on each current carrying leg is f = i dl x (Bxix + Bi, + Bjiý) >f(x) = - i Ay[- Bxi + Bix] f(x + Ax) = i Ay[ - Bxi + BzixlJ x+ax f(y) = i Ax[B,i, - Bji,] , f(y + Ay) = - i Ax[B,i, - Bi,]l ,+a, (1) so that the total force on the dipole is f = f(x) + f(x + Ax) + f(y) + f(y + Ay) =., + B (x , AxAY 1 + A x ) - B (x ) Ax , B.(y +Ay)-Bz(y) . B,(y +Ay)-B(y) AY y A Ay Ay B Y I• kx, yl t m = iA x Ayi, x Figure 5-26 Bx(x + Ax)- B(x). Ax A magnetic dipole in a magnetic field B. ] (2) (2) 369 Magnetic Fields and Forces In the limit of infinitesimal Ax and Ay the bracketed terms define partial derivatives while the coefficient is just the magnetic dipole moment m = i Ax Ay iý: -- lim f = m[LB A-.O ax xL x + B,, +-aB, (3) iy y Ampere's and Gauss's law for the magnetic field relate the field components as V -B = 0 = -x\ az + ax VxB=l°o(Jf+VxM)= LOJ • Oy (4) ay B ' =L0JT 8z aB. aB, 8z ax aB, aB, ax Ox which puts (3) in the form (Bx, = a y +B fm= M-'L ,+ az az I z PlJT. aB-= Oy -B (Jy , I--oUTi.I=,) (5) )) =(m.V)B +AomxJrT (6) where JT is the sum of free and magnetization currents. If there are N such dipoles per unit volume, the force density on the dipoles and on the free current is F=Nf= (M- V)B+ILoMXJT+JfxB = to(M *V)(H+M)+oM x (Jf + V XM) +LoJI = Ao(M X(H+M) - V)(H+M) + /oM x (V x M) +IoLJ 1 xH (7) Using the vector identity M x (V x M)= -(M V)M+ V(M - M) (8) (7) can be reduced to F= tLo(M • V)H +lToJf x H+ V( M.M (9) The total force on the body is just the volume integral of F: f= Iv F dV (10) 370 The Magnetic Field In particular, the last contribution in (9) can be converted to a surface integral using the gradient theorem, a corollary to the divergence theorem (see Problem 1-15a): J \2 M-(.M dV= ~ -M.MdS (11) Since this surface S surrounds the magnetizable medium, it is in a region where M= 0 so that the integrals in (11) are zero. For this reason the force density of (9) is written as F = lio(M * V)H + CoJf x H (12) It is the first term on the right-hand side in (12) that accounts for an iron object to be drawn towards a magnet. Magnetizable materials are attracted towards regions of higher H. 5-8-2 Force on a Current Loop (a) Lorentz Force Only Two parallel wires are connected together by a wire that is free to move, as shown in Figure 5-27a. A current I is imposed and the whole loop is placed in a uniform magnetic field Boi.. The Lorentz force on the moveable wire is f, = IBol (13) where we neglect the magnetic field generated by the current, assuming it to be much smaller than the imposed field B 0 . (b) Magnetization Force Only The sliding wire is now surrounded by an infinitely permeable hollow cylinder of iliner radius a and outer radius b, both being small compared to the wire's length 1, as in Figure 5-27b. For distances near the cylinder, the solution is approximately the same as if the wire were infinitely long. For r>0 there is no current, thus the magnetic field is curl and divergence free within each medium so that the magnetic scalar potential obeys Laplace's equation as in Section 5-7-2. In cylindrical geometry we use the results of Section 4-3 and try a scalar potential of the form x=(Ar+C)Cos (14) Magnetic Fields and Forces 371 x 6 gx Y- B p I = IBoliy of I Boix =Bo(icoso (b) Sisin ) Boix B i I 4i J= rb2 - f =IBoliy l t i=vb xrb2 Figure 5-27 (a) The Lorentz-force on a current carrying wire in a magnetic field. (b) If the current-carrying wire is surrounded by an infinitely permeable hollow cylinder, there is no Lorentz force as the imposed magnetic field is zero where the current is. However, the magnetization force on the cylinder is the same as in (a). (c) The total force on a current-carrying magnetically permeable wire is also unchanged. in each region, where B= VX because V x B= 0. The constants are evaluated by requiring that the magnetic field approach the imposed field Boix at r = o and be normally incident onto the infinitely permeable cylinder at r =a and r = b. In addition, we must add the magnetic field generated by the line current. The magnetic field in each region is then The Magnetic Field (see Problem 32a): AOI. i2rO, Ob Note the infinite flux density in the iron (IA-* o) due to the line current that sets up the finite H field. However, we see that none of the imposed magnetic field is incident upon the current carrying wire because it is shielded by the infinitely permeable cylindrical shell so that the Lorentz force contribution on the wire is zero. There is, however, a magnetization force on the cylindrical shell where the internal magnetic field H is entirely due to the line current, H, = I/27rr because with i- - oo, the contribution due to Bo is negligibly small: o(M - V)H F= ( Ma. a M,(H ar )+ (16) (H r aw Within the infinitely permeable shell the magnetization and H fields are I H 2wr mo 2B0b2 (1 _a2 0oMr= Br-- lor' b2_ 2- oMo = B - /oH = ~ 2 2Bob 2 (b -a)\ -) (17) cOS a2 + r sn + (G -0 o)I 21rr Although Hs only depends on r, the unit vector io depends on i, = (-sin 4i, +cos Oi,) so that the force density of (16) becomes F= BI i2rr ---- (B. - oH#)I d (4 , 2rr d4 . 14+ - I = i [-B,(-sin i. +cos~i,) + (B,- joH#)(- cos 4i. - sin Oi,)] ·_.____ · · II__ ·· (18) Magnetic Fields and Forces I i2r r2 2Bob 2 b2 • 373 2 1--= r -(1 +~) sin O(cos COS 0(-sin Oi. +cos Oi,) i.+ sin fi,)] + (/ -•rO•)I (cos Oi,+sin Oil)) + (- o) I(cos bi. +sin 4i,)] (19) The total force on the cylinder is obtained by integrating (19) over r and 4: 2w f= b JorFl rdrd (20) All the trigonometric terms in (19) integrate to zero over 0 so that the total force is 2B b 2 i 2 fb a 2 Bob 2I a b (b 2_a2) r = IB1o (21) The force on the cylinder is the same as that of an unshielded current-carrying wire given by (13). If the iron core has a finite permeability, the total force on the wire (Lorentz force) and on the cylinder (magnetization force) is again equal to (13). This fact is used in rotating machinery where currentcarrying wires are placed in slots surrounded by highly permeable iron material. Most of the force on the whole assembly is on the iron and not on the wire so that very little restraining force is necessary to hold the wire in place. The force on a current-carrying wire surrounded by iron is often calculated using only the Lorentz force, neglecting the presence of the iron. The correct answer is obtained but for the wrong reasons. Actually there is very little B field near the wire as it is almost surrounded by the high permeability iron so that the Lorentz force on the wire is very small. The force is actually on the iron core. 374 The Magnetic Field (c) Lorentz and Magnetization Forces If the wire itself is highly permeable with a uniformly distributed current, as in Figure 5-27c, the magnetic field is (see Problem 32a) 2Bo2Bo(i, cos 4 - is sin A,+•A = Ir ) + Ir 2~rb I 2Bo 1,+-y (-yix+xi,), rb +2'r ' o It is convenient to write the fields within the cylinder in Cartesian coordinates using (18) as then the force density given by (12) is F = Ao(M - V)H + ~oJf X H = (A - Ao)(H - V)H + CLoI 2L x H rrb2 =( - o)H. +H, )(H.• +H,i,)+ (Hi,- Hi.) (23) Since within the cylinder (r
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