TYCO V23401-T2099-C502 V23401-T2099-C502 V23401-T2099-C502 V23401-T2099-C502

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V23401-T2014-E209

V23401-T2099-C502

V23401-T1009-B122 

V23401-H1009-B122
V23401-T1009-B101

V23401-H1009-B101

V23401-T1009-B102 

V23401-H1009-B102
V23401-T2001-B214

V23401-H2001-B214

V23401-T2001-B222 

V23401-H2001-B222
V23401-T2001-B201

V23401-H2001-B201

V23401-T2001-B202 

V23401-H2001-B202
V23401-T2009-B214

V23401-H2009-B214

V23401-T2009-B222 

V23401-H2009-B222
V23401-T2009-B201

V23401-H2009-B201

V23401-T2009-B202 

V23401-H2009-B202
V23401-T2010-B214

V23401-H2010-B214

V23401-T2010-B222 

V23401-H2010-B222
V23401-T2010-B201

V23401-H2010-B201

V23401-T2010-B202 

V23401-H2010-B202
V23401-T2014-B214

V23401-H2014-B214

V23401-T2014-B222 

V23401-H2014-B222
V23401-T2014-B201

V23401-H2014-B202

V23401-T2014-B202

Function
VS1-S3 = +rT · VR1-R2 · cos(p · á)
VS2-S4 = +rT · VR1-R2 · sin(p · á)
p = pairs of poles
This function applies to the clockwise rotation
of the rotor when looking at the (grooveless)
transformer component from the top.

High-voltage test
Windings to housing 500 VAC, 50 Hz
Windings to each other 250 VAC, 50 Hz
Insulation resistance
Windings to housing and Rinsulation > 50 MΩ at 500 VDC
windings to each other
Operating temperature range –55 °C ... +150 °C
Electrical and thermal limits

Momentum of inertia of the rotor approx. 200 g · cm2
Maximum rational speed 20000 rpm
Maximum angular acceleration 64000 rad/s2
Torsional strength of rotor components 1 Nm
Shock resistance (11 ms sine) 1000 m/s2
Vibration fatigue limit (0 ... 2 kHz) 200 m/s2
Permissible radial runout 0.075 mm
(see Dimensioned drawing: Note 1)
Permissible axial offset ± 0.5 mm
(see Dimensioned drawing: Note 2)

Transformation ratio rT
rT = VS1-S3 max / VR1-R2
rT = VS2-S4 max / VR1-R2
ü = 0.5 ± 10 % within 3 ... 20 kHz
= 0.5 ± 5 % at 5 kHz

Phase shift ø
VR1-R2(t) = VR1-R2 max · sin(2 · ð · f · t)
VS1-S3(t) = VS1-S3 max · sin(2 · ð · f · t - ø)
for –90° < á < +90°
Tolerance: ± 5°

When choosing the values of these parameters take into
account power dissipation, max. ambient temperature and
the heat dissipation. Including self heating a maximum
operating temperature of 150 °C must not be exceeded.
Generally a power dissipation of P ≤ 0.5 W is not critical.

Input current I
The adjacent figure applies to
VR1-R2 = 7 V.
For other input voltages, the input current
changes follows as:
I = I
Figure · VR1-R2 / 7 V

Power consumption P
The adjacent figure applies to
VR1-R2 = 7 V.
For other input voltages, the power
consumption changes follows as:
P = P
Figure · (VR1-R2 / 7 V)2

DC resistance
The ohmic resistance values are based on an RR1-R2 = 39 Ω
ambient temperature of 22 °C and change with RS1-S3 = RS2-S4 = 94 Ω
temperature by 0.39 % / K Tolerance: ± 10 %

When choosing the values of these parameters take into
account power dissipation, max. ambient temperature and
the heat dissipation. Including self heating a maximum
operating temperature of 150 °C must not be exceeded.
Generally a power dissipation of P ≤ 0.5 W is not critical.

Input current I
The adjacent figure applies to
VR1-R2 = 7 V.
For other input voltages, the input current
changes follows as:
I = I
Figure · VR1-R2 / 7 V

Power consumption P
The adjacent figure applies to
VR1-R2 = 7 V.
For other input voltages, the power
consumption changes follows as:
P = P
Figure · (VR1-R2 / 7 V)2

DC resistance
The ohmic resistance values are based on an
ambient temperature of 22 °C and change with
temperature by 0.39 % / K

ZRO ... Impedance between R1 and R2 with open outputs

RR1-R2 = 46 Ω
RS1-S3 = RS2-S4 = 63 Ω
Tolerance: ± 10 %

ZRS ... Impedance between R1 and R2 with short circuits
between S1 and S3 as well as between S2 and S4