MEP_FOC.ppt

Field-Oriented Control of Induction Machine

• IM is superior to DC machine with respect to size, weight, inertia, cost, speed

Why FOC ?

• DC motor is superior to IM with respect to ease of control– High performance with simple control due de-coupling

component of torque and flux

• FOC transforms the dynamics of IM to become similar to the DC motor’s – decoupling the torque and flux components

Basic Principles DC machine

Current in

Current out

a

f

By keeping flux constant, torque can be controlled by controlling armature current

Te = k If Ia

Basic Principles of IM

a

b

b’c’

c

Stator current produce stator flux

s r

Interaction between stator and rotor fluxes produces torque

Space angle between stator and rotor fluxes varies with load, and speed

Stator flux induces rotor current produces rotor flux

FOC of IM drive

Torque equation :

sse i2

p

2

3T

srr

me i

L

L

2

p

2

3T

In d-q axis :

)ii(LL

2p

23

T sdrqsqrdr

me

FOC of IM drive

In d-q axis :

)ii(LL

2p

23

T sdrqsqrdr

me

Choose a frame such that:

rrdr

0r

rq

FOC of IM drive

Choose a frame such that:

rrdr

0r

rq

FOC of IM drive

)ii(LL

2p

23

T sdrqsqrdr

me

Choose a frame such that:

rrdr

0r

rq

qs

ds

si

r

sqi

rq

sdi rd

As seen by stator reference frame:

FOC of IM drive

rsqr

r

me i

LL

2p

23

T

si

Choose a frame such that:

rrdr

0r

rq

qs

ds

r dr

qr

rsdi

rsqi

)ii(LL

2p

23

T sdrqsqrdr

me

Rotating reference frame:

FOC of IM driveTo implement rotor flux FOC need to know rotor flux position:

(i) Indirect FOC

grrg

grg

sr

rmgr

r

r )(jdtd

iLRL

LR

0

rsliprr

sqr

sdr

rmr

r

r )(jdtd

jiiLRL

LR

0

Synchronous speed obtain by adding slip speed and rotor speed

Rotor voltage equation:

grrg

grg

rr )(jdt

diR0

gsm

grr

gr iLiL

Rotor flux equation:

FOC of IM drive - indirect

dtd

iLRL

LR

0 rrsd

r

rmr

r

r

d component

rslipr

sqr

rm )(iLRL

0

q component

rsliprr

sqr

sdr

rmr

r

r )(jdtd

jiiLRL

LR

0

FOC of IM drive - indirect

dtd

iLRL

LR

0 rrsd

r

rmr

r

r

d component

rslipr

sqr

rm )(iLRL

0

q component

rsliprr

sqr

sdr

rmr

r

r )(jdtd

jiiLRL

LR

0

m

*r

sd L*i r

r

sqr

*r

rmslip i

LRL

)(

m

r

r

*e

sq LL

p3T4

*i r

FOC of IM drive - indirect

T*

*

2/3

1/s

irsq*

irsd*

isq*

isd*

ia*

ib*

ic*

CCVSI

slip r

+ +

Rotating frame Stationary frame

m

*r

sd L*i r

m

r

r

*e

sq LL

p3T4

*i r

rsq

r*r

rmslip i

LRL

)(

ej

FOC of IM drive

grr

rs

r

rmr

r

r jdt

di

L

RL

L

R0

(ii) Direct FOC

Rotor flux can be estimated by:

Rotor flux estimated from motor’s terminal variables

srr

me i

LL

2p

23

T

Express in stationary frame

FOC of IM drive

grr

rs

r

rmr

r

r jdtd

iLRL

LR

0

(ii) Direct FOC

)j(jdt

)j(di)jii(

LRL

)j(LR

0 rqrdrrqrd

sqsdr

rmrqrd

r

r

dti

LRL

LR

rqrsdr

rmrd

r

rrd

dti

LRL

LR

rdrsqr

rmrq

r

rrq

d q

rd

rq

2rq

2rdr

FOC of IM drive - direct

T*

r*2/3

isq*

isd*

ia*

ib*

ic*

CCVSI

TC

FC

irsq*

irsd*

ej

Te

r

srr

me i

LL

2p

23

T

grr

rs

r

rmr

r

r jdt

di

L

RL

L

R0

Rotating frame Stationary frame