VISHAY PR01000104708JR500

PR01/02/03
Vishay BCcomponents
Power Metal Film Leaded Resistors
FEATURES
• High power in small packages (1 W/0207 size to
3 W/0617 size)
• Different lead materials for different applications
• Defined interruption behaviour
• Lead (Pb)-free solder contacts
DESCRIPTION
A homogeneous film of metal alloy is deposited on a high
grade ceramic body. After a helical groove has been cut in
the resistive layer, tinned connecting wires of electrolytic
copper or copper-clad iron are welded to the end-caps. The
resistors are coated with a red, non-flammable lacquer which
provides electrical, mechanical and climatic protection. This
coating is not resistant to aggressive fluxes. The
encapsulation is resistant to all cleaning solvents in
accordance with IEC 60068-2-45.
• Pure tin plating provides compatibility with lead (Pb)-free
and lead containing soldering processes
• Compliant to RoHS directive 2002/95/EC
APPLICATIONS
• All general purpose power applications
TECHNICAL SPECIFICATIONS
VALUE
PR02
DESCRIPTION
PR03
PR01
Resistance
0.22 Ω to 1 MΩ
Range (2)
Resistance Tolerance and Series
Cu-lead
FeCu-lead
Cu-lead
FeCu-lead
0.33 Ω to 1 MΩ
1 Ω to 1 MΩ
0.68 Ω to 1 MΩ
1 Ω to 1 MΩ
± 1 % (E24, E96 series); ± 5 % (E24 series)
(1)
Rated Dissipation, P70:
R<1Ω
0.6 W
1.2 W
-
1.6 W
-
1Ω≤R
1W
2W
1.3 W
3W
2.5 W
135 K/W
75 K/W
115 K/W
60 K/W
75 K/W
Thermal Resistance (Rth)
≤ ± 250 ppm/K
Temperature Coefficient
Maximum Permissible Voltage
(Umax. AC/DC)
350 V
Basic Specifications
500 V
750 V
IEC 60115-1
Climatic Category (IEC 60068-1)
55/155/56
Stability After:
Load (1000 h, P70)
ΔR max.: ± (5 % R + 0.1 Ω)
Long Term Damp Heat Test (56 Days)
ΔR max.: ± (3 % R + 0.1 Ω)
Soldering (10 s, 260 °C)
ΔR max.: ± (1 % R + 0.05 Ω)
Notes
(1) 1 % tolerance is available for R -range from 1 R upwards
n
(2) Ohmic values (other than resistance range) are available on request
• R value is measured with probe distance of 24 mm ± 1 mm using 4-terminal method
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Document Number: 28729
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PR01/02/03
Power Metal Film Leaded Resistors
Vishay BCcomponents
PART NUMBER AND PRODUCT DESCRIPTION
PART NUMBER: PR02000201001JA100
P
R
0
2
0
0
0
2
0
1
0
0
1
J
A
MODEL/SIZE
VARIANT
WIRE
TYPES
TCR/MATERIAL
VALUE
TOLERANCE
PR0100
PR0200
PR0300
0 = Neutral
Z = Value
overflow
(Special)
1 = Cu 0.6
2 = Cu 0.8
3 = FeCu 0.6
4 = FeCu 0.8
0 = Standard
3 digit value
1 digit multiplier
MULTIPLIER
F=±1%
J=±5%
7 = *10-3
8 = *10-2
9 = *10-1
0 = *100
1 = *101
1
0
PACKAGING (1)
N4
N3
A5
A1
AC
R5
2 = *102
3 = *103
4 = *104
5 = *105
R2
L1
DC
K1
B1
PC
0
SPECIAL
The 2 digits
are used for
all special
parts.
00 = Standard
PRODUCT DESCRIPTION: PR02 5 % A1 1K0
PR02
MODEL/SIZE
PR01
PR02
PR03
5%
A1
TOLERANCE
±1%
±5%
PACKAGING (1)
N4
N3
A5
A1
AC
R5
1K0
L1
DC
K1
B1
PC
R2
RESISTANCE VALUE
1K0 = 1 kΩ
4K75 = 4.75 kΩ
Notes
(1) Please refer to table PACKAGING for details
• The PART NUMBER is shown to facilitate the introduction of a unified part numbering system for ordering products
PACKAGING
AMMO PACK
MODEL
REEL
BULK, DOUBLE KINK
TAPING
PIECES
CODE
PIECES
CODE
5000
A5
5000
R5
1000
A1
4000
N4
PITCH
PIECES
CODE
17.8 mm
1000
L1
12.5 mm
1000
K1
17.8 mm
1000
L1
15.0 mm
1000
B1
25.4 mm
500
DC
20.0 mm
500
PC
Axial, 52 mm
PR01
Radial
Axial, 52 mm
PR02
1000
A1
5000
R5
3000
N3
2000
R2
Radial
Axial, 63 mm
PR03
500
AC
Radial
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PR01/02/03
Vishay BCcomponents
Power Metal Film Leaded Resistors
DIMENSIONS
L1
Ø d
ØD
L2
Type with straight leads
DIMENSIONS - Straight lead type and relevant physical dimensions; see straight leads outline
L1 max.
(mm)
Ø Dmax.
(mm)
TYPE
Ød
(mm)
L2 max.
(mm)
Cu
FeCu
PR01
2.5
6.5
8.0
0.58 ± 0.05
-
PR02
3.9
10.0
12.0
0.78 ± 0.05
0.58 ± 0.05
PR03
5.2
16.7
19.5
0.78 ± 0.05
0.58 ± 0.05
ØD
P1 ± 0.5
P1 ± 0.5
8+2
L1
L2
4.5 + 10
Ød
P2 ± 3
S
b1
b2
ØB
± 0.07
Dimensions in millimeters
Type with double kink
DIMENSIONS - Double kink lead type and relevant physical dimensions; see double kinked outline
TYPE
Ød
(mm)
LEAD STYLE
Double kink
large pitch
Cu
FeCu
0.58 ± 0.05
0.58 ± 0.05
b1
(mm)
b2
(mm)
1.10
+ 0.25/- 0.20
1.45
+ 0.25/- 0.20
Ø Dmax.
(mm)
P1
(mm)
P2
(mm)
Smax.
(mm)
ØB
(mm)
17.8
17.8
2
0.8
12.5
12.5
2
0.8
17.8
17.8
2
0.8
15.0
15.0
2
1.0
25.4
25.4
2
1.0
22.0
20.0
2
1.0
2.5
PR01
Double kink
small pitch
-
0.58 ± 0.05
1.10
+ 0.25/- 0.20
1.45
+ 0.25/- 0.20
Double kink
large pitch
0.78 ± 0.05
0.58 ± 0.05
1.10
+ 0.25/- 0.20
1.45
+ 0.25/- 0.20
PR02
3.9
Double kink
small pitch
-
0.78 ± 0.05
1.30
+ 0.25/- 0.20
1.65
+ 0.25/- 0.20
Double kink
large pitch
0.78 ± 0.05
0.58 ± 0.05
1.10
+ 0.25/- 0.20
1.65
+ 0.25/- 0.20
PR03
5.2
Double kink
small pitch
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-
0.78 ± 0.05
1.30
+ 0.25/- 0.20
2.15
+ 0.25/- 0.20
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Document Number: 28729
Revision: 14-Oct-09
PR01/02/03
Power Metal Film Leaded Resistors
Vishay BCcomponents
PRODUCTS WITH RADIAL LEADS (PR01, PR02)
P2
P
H1
H
H0
L
L1
W0
W
F
P0
P1
D0
DIMENSIONS - RADIAL TAPING
SYMBOL
PARAMETER
VALUE
TOLERANCE
UNIT
P
Pitch of components
12.7
± 1.0
mm
P0
Feed-hole pitch
12.7
± 0.2
mm
P1
Feed-hole centre to lead at topside at the tape
3.85
± 0.5
mm
P2
Feed-hole center to body center
6.35
± 1.0
mm
F
Lead-to-lead distance
4.8
+ 0.7/- 0
mm
W
Tape width
18.0
± 0.5
mm
W0
Minimum hold down tape width
5.5
-
mm
Component height PR01
29
Max.
Component height PR02
29
± 3.0
H0
Lead wire clinch height
16.5
± 0.5
mm
H
Height of component from tape center
19.5
±1
mm
D0
Feed-hole diameter
4.0
± 0.2
mm
L
Maximum length of snipped lead
11.0
-
mm
L1
Minimum lead wire (tape portion) shortest lead
2.5
-
mm
H1
mm
Note
• Please refer document number 28721 “Packaging” for more detail
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Vishay BCcomponents
Power Metal Film Leaded Resistors
MOUNTING
MASS PER UNIT
The resistors are suitable for processing on automatic
insertion equipment and cutting and bending machines.
MASS
(mg)
212
207
504
455
496
1192
1079
1185
TYPE
PR01 Cu 0.6 mm
PR01 FeCu 0.6 mm
PR02 Cu 0.8 mm
PR02 FeCu 0.6 mm
PR02 FeCu 0.8 mm
PR03 Cu 0.8 mm
PR03 FeCu 0.6 mm
PR03 FeCu 0.8 mm
MOUNTING PITCH
TYPE
LEAD STYLE
Straight leads
PR01
PR02
PR03
e
5 (1)
Radial taped
4.8
2
17.8
7
Double kink small pitch
12.5
5
Straight leads
15.0 (1)
6 (1)
Radial taped
4.8
2
Double kink large pitch
17.8
7
Double kink small pitch
15.0
6
Straight leads
23.0 (1)
9 (1)
Double kink large pitch
25.4
10
Double kink small pitch
20.0
8
OUTLINES
The length of the body (L1) is measured by inserting the
leads into holes of two identical gauge plates and moving
these plates parallel to each other until the resistor body is
clamped without deformation (IEC 60294).
mm
12.5 (1)
Double kink large pitch
MARKING
The nominal resistance and tolerance are marked on the
resistor using four or five colored bands in accordance with
IEC 60062, marking codes for resistors and capacitors.
PITCH
Note
(1) Recommended minimum value
FUNCTIONAL DESCRIPTION
PRODUCT CHARACTERIZATION
Standard values of nominal resistance are taken from the E96/E24 series for resistors with a tolerance of ± 1 % or ± 5 %.
The values of the E96/E24 series are in accordance with IEC 60063.
FUNCTIONAL PERFORMANCE
P
(W)
Tamb = 40 °C
1.00
70 °C
P
(W)
100 °C
0.75
Tamb = 40 °C
3.00
100 °C
125 °C
2.25
125 °C
155 °C
1.50
0.50
70 °C
155 °C
0.75
0.25
Tm (°C)
00
h
00
T m (°C)
h
250 °C
<1
≤ 5 kΩ
1 k
Ω
>5
1 k
Ω
0h
00
10 0 h
0
10
>3
h
0
0
10
0
00
10
10
<
< 3 1 kΩ
0k
Ω
0k
Ω
h
0
00
0
10
205 °C
10
5.0
2.0
0.5
1.0
0.2 0.1 % ΔR
10
P
(W)
Tamb = 40 °C
2.00
5.0
2.0
1.0
0.5
0.2 0.1 % ΔR
PR03 Drift nomogram
PR01 Drift nomogram
70 °C
100 °C
1.50
125 °C
Note
• The maximum permissible hot-spot temperature is 205 °C for
PR01, 220 °C for PR02 and 250 °C for PR03
1.00
155 °C
0.50
0
0
h
Tm (°C)
00
10
0
10
<
< 3 1 kΩ
9
> 3 kΩ
9k
Ω
h
00
00
h
10
10
5.0
2.0
1.0
220 °C
0.5
0.2 0.1 % ΔR
PR02 Drift nomogram
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PR01/02/03
Power Metal Film Leaded Resistors
Vishay BCcomponents
The power that the resistor can dissipate depends on the operating temperature.
Pmax.
(% Prated)
100
50
0
- 55
0
50
70
100
Tamb (°C)
155
Maximum dissipation (Pmax.) in percentage of rated power as a function of the ambient temperature (Tamb)
Derating
103
Pmax.
(W)
102
t p /t i = 1000
500
200
100
50
20
10
5
10
2
1
10-1
10-6
10-5
10-4
10-3
10-2
10-1
ti (s)
1
PR01 Pulse on a regular basis; maximum permissible peak pulse power (Pmax.) as a function of pulse duration (ti)
1200
Umax.
(V)
1000
800
600
400
200
0
10-6
10-5
10-4
10-3
10-2
10-1
t i (s)
1
PR01 Pulse on a regular basis; maximum permissible peak pulse voltage (Umax.) as a function of pulse duration (ti)
Pulse Loading Capabilities
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PR01/02/03
Vishay BCcomponents
Power Metal Film Leaded Resistors
103
Pmax.
t p/ t i = 1000
500
200
100
50
20
10
5
(W)
102
10
2
1
10-1
10-6
10-5
10-4
10-3
10-2
10-1
ti (s)
1
PR02 Pulse on a regular basis; maximum permissible peak pulse power (Pmax.) as a function of pulse duration (ti)
1700
Umax.
(V)
1500
1300
1100
900
700
500
10-6
10-5
10-4
10-3
10-2
10-1
1
t i (s)
PR02 Pulse on a regular basis; maximum permissible peak pulse voltage (Umax.) as a function of pulse duration (ti)
104
Pmax.
(W)
103
t p/ t i = 1000
500 200
100
50
102
20
10
5
10
2
1
10-6
10-5
10-4
10-3
10-2
10-1
t i (s)
1
PR03 Pulse on a regular basis; maximum permissible peak pulse power (Pmax.) as a function of pulse duration (ti)
Pulse Loading Capabilities
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Power Metal Film Leaded Resistors
Vishay BCcomponents
2400
Umax.
(V)
2000
1600
1200
800
400
0
10-6
10-5
10-4
10-3
10-2
10-1
1
t i (s)
PR03 Pulse on a regular basis; maximum permissible peak pulse voltage (Umax.) as a function of pulse duration (ti)
Pulse Loading Capabilities
10 2
10 2
t
(s)
t
(s)
10
10
1
1
10 -1
0
10
20
30
40
Poverload (W)
50
PR01 Time to interruption as a function of overload power
for range: 0 R 22 ≤ Rn < 1 R
This graph is based on measured data under constant voltage
conditions; the data may deviate according to the applications.
10 2
10-1
0
20
10
30
40
Poverload (W)
50
PR01 Time to interruption as a function of overload power
for range: 16 R ≤ Rn ≤ 560 R
This graph is based on measured data under constant voltage
conditions; the data may deviate according to the applications.
10 2
t
(s)
t
(s)
10
10
1
1
10 - 1
0
10
20
30
40
Poverload (W)
50
PR01 Time to interruption as a function of overload power
for range: 1 R ≤ Rn ≤ 15 R
This graph is based on measured data under constant voltage
conditions; the data may deviate according to the applications.
10 -1
0
20
40
60
80
100
120
Poverload (W)
PR02 Time to interruption as a function of overload power
for range: 0.33 R ≤ Rn < 5 R
This graph is based on measured data under constant voltage
conditions; the data may deviate according to the applications.
Interruption Characteristics
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Power Metal Film Leaded Resistors
Vishay BCcomponents
10 2
10 2
t
(s)
t
(s)
10
10
1
1
10-1
0
20
40
60
80
10 -1
100
120
20
0
40
PR02 Time to interruption as a function of overload power
for range: 5 R ≤ Rn < 68 R
This graph is based on measured data under constant voltage
conditions; the data may deviate according to the applications.
60
80
100
120
Poverload (W)
Poverload (W)
PR02 Time to interruption as a function of overload power
for range: 68 R ≤ Rn ≤ 560 R
This graph is based on measured data under constant voltage
conditions; the data may deviate according to the applications.
Interruption Characteristics
200
10 2
∆T
(K)
t
(s)
160
10
120
80
1
40
10 -1
0
0
50
100
150
200
0
250
Poverload (W)
0.4
0.8
P (W)
1.2
Ø 0.6 mm Cu-leads
PR03 Time to interruption as a function of overload power
for range: 0.68 R ≤ Rn ≤ 560 R
This graph is based on measured data under constant voltage
conditions; the data may deviate according to the applications.
100
PR01 Hot-spot temperature rise (ΔT) as a function
of dissipated power.
200
∆T
(K)
∆T
(K)
80
160
60
120
15 mm
40
20 mm
25 mm
20
80
40
0
0
0
0.4
0.8
P (W)
1.2
Ø 0.6 mm Cu-leads
Minimum distance from resistor body to PCB = 1 mm
PR01 Temperature rise (ΔT) at the lead end (soldering point) as a
function of dissipated power at various lead lengths after mounting.
0
0.4
0.8
P (W)
1.2
Ø 0.6 mm FeCu-leads
PR01 Hot-spot temperature rise (ΔT) as a function
of dissipated power.
Application Information
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Power Metal Film Leaded Resistors
100
Vishay BCcomponents
200
∆T
(K)
∆T
(K)
80
160
60
120
15 mm
40
80
20 mm
25 mm
20
40
0
0
0
0.4
0.8
P (W) 1.2
Ø 0.6 mm FeCu-leads
Minimum distance from resistor body to PCB = 1 mm
PR01 Temperature rise (ΔT) at the lead end (soldering point) as a
function of dissipated power at various lead lengths after mounting.
0
0.8
1.6
P (W)
2.4
Ø 0.8 mm Cu-leads
PR02 Hot-spot temperature rise (ΔT) as a function
of dissipated power.
240
100
∆T
(K)
∆T
(K)
200
80
15 mm
160
60
20 mm
120
25 mm
40
80
20
40
0
0
1
0
2
P (W)
Ø 0.8 mm Cu-leads
Minimum distance from resistor body to PCB = 1 mm
0
0.8
1.6
P (W)
2.4
Ø 0.6 mm FeCu-leads
PR02 Temperature rise (ΔT) at the lead end (soldering point) as a
function of dissipated power at various lead lengths after mounting.
PR02 Hot-spot temperature rise (ΔT) as a function
of dissipated power.
240
100
∆T
(K)
∆T
(K)
200
80
160
60
15 mm
40
20 mm
120
80
25 mm
20
40
0
0
0
1
P (W)
2
Ø 0.6 mm FeCu-leads
Minimum distance from resistor body to PCB = 1 mm
PR02 Temperature rise (ΔT) at the lead end (soldering point) as a
function of dissipated power at various lead lengths after mounting.
0
1
P (W)
2
Ø 0.8 mm FeCu-leads
PR02 Hot-spot temperature rise (ΔT) as a function
of dissipated power.
Application Information
Document Number: 28729
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Power Metal Film Leaded Resistors
Vishay BCcomponents
200
100
∆T
(K)
∆T
(K)
160
80
15 mm
20 mm
60
120
25 mm
40
80
20
40
0
0
0
0.8
1.6
P (W)
0
2.4
1
2
P (W)
3
Ø 0.8 mm Cu-leads
Ø 0.8 mm FeCu-leads
Minimum distance from resistor body to PCB = 1 mm
PR02 Temperature rise (ΔT) at the lead end (soldering point) as a
function of dissipated power at various lead lengths after mounting.
100
PR03 Hot-spot temperature rise (ΔT) as a function
of dissipated power.
240
∆T
(K)
∆T
(K)
80
15 mm
200
20 mm
160
60
120
25 mm
40
80
20
40
0
0
1
2
P (W)
0
3
Ø 0.8 mm Cu-leads
Minimum distance from resistor body to PCB = 1 mm
0
1
2
P (W)
3
Ø 0.6 mm FeCu-leads
PR03 Temperature rise (ΔT) at the lead end (soldering point) as a
function of dissipated power at various lead lengths after mounting.
100
PR03 Hot-spot temperature rise (ΔT) as a function
of dissipated power.
240
∆T
(K)
∆T
(K)
200
80
10 mm
160
60
15 mm
120
20 mm
40
80
25 mm
20
40
0
0
0
1
2
P (W)
3
Ø 0.6 mm FeCu-leads
Minimum distance from resistor body to PCB = 1 mm
PR03 Temperature rise (ΔT) at the lead end (soldering point) as a
function of dissipated power at various lead lengths after mounting.
0
1
2
P (W)
3
Ø 0.8 mm FeCu-leads
PR03 Hot-spot temperature rise (ΔT) as a function
of dissipated power.
Application Information
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PR01/02/03
Power Metal Film Leaded Resistors
Vishay BCcomponents
100
∆T
(K)
80
15 mm
60
20 mm
40
20
0
0
0.8
1.6
2.4
P (W) 3.2
Ø 0.8 mm FeCu-leads
Minimum distance from resistor body to PCB = 1 mm
PR03 Temperature rise (ΔT) at the lead end (soldering point) as a function
of dissipated power at various lead lengths after mounting.
10 2
Z
R
Rn = 1 Ω
10
R n = 24 Ω
1
Rn = 12 kΩ
10 -1
10 -2
Rn = 100 kΩ
10 -1
1
10
10 2
f (MHz)
10 3
PR01 Impedance as a function of applied frequency
10 2
Z
R
R n = 1.2 Ω
10
R n = 10 Ω
1
Rn = 22 kΩ
10 -1
Rn = 124 kΩ
10 -2
10 -1
1
10
10 2
f (MHz)
10 3
PR02 Impedance as a function of applied frequency
Application Information
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Power Metal Film Leaded Resistors
10 2
Z
R
Rn = 1.5 Ω
10
R n = 18 Ω
1
Rn = 1.3 kΩ
10 -1
Rn = 20 kΩ
R n = 100 kΩ
10 -2
1
10 2
10
f (MHz)
10 3
PR03 Impedance as a function of applied frequency
Application Information
TESTS AND REQUIREMENTS
Essentially all tests are carried out in accordance with
IEC 60115-1 specification, category LCT/UCT/56 (rated
temperature range: Lower Category Temperature, Upper
Category Temperature; damp heat, long term, 56 days).
The tests are carried out in accordance with IEC 60068-2-xx
Test Method under standard atmospheric conditions
according to IEC 60068-1, 5.3.
In the Test Procedures and Requirements table, tests
and requirements are listed with reference to the relevant
clauses of IEC 60115-1 and IEC 60068-2-xx test methods. A
short description of the test procedure is also given. In some
instances deviations from the IEC recommendations were
necessary for our method of specifying.
All soldering tests are performed with mildly activated flux.
TEST PROCEDURES AND REQUIREMENTS
IEC
60115-1
CLAUSE
IEC
60068-2TEST
METHOD
TEST
4.4.1
Visual examination
4.4.2
Dimensions (outline)
PROCEDURE
REQUIREMENTS
No holes; clean surface; no damage
Gauge (mm)
See Straight and Kinked Dimensions tables
Applied voltage (+ 0 %/- 10 %):
R < 10 Ω: 0.1 V
10 Ω ≤ R < 100 Ω: 0.3 V
Resistance
(refer note on first
page for measuring
distance)
4.5
100 Ω ≤ R < 1 kΩ: 1 V
1 kΩ ≤ R < 10 kΩ: 3 V
R - Rnom: max. ± 5 %
10 kΩ ≤ R < 100 kΩ: 10 V
100 kΩ ≤ R < 1 MΩ: 25 V
R = 1 MΩ: 50 V
4.18
20 (Tb)
Resistance to
soldering heat
Thermal shock: 10 s; 260 °C; 3 mm from body
ΔR max.: ± (1 % R + 0.05 Ω)
4.29
45 (Xa)
Component solvent
resistance
Isopropyl alcohol or H2O
followed by brushing
No visual damage
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For technical questions, contact: [email protected]
Document Number: 28729
Revision: 14-Oct-09
PR01/02/03
Power Metal Film Leaded Resistors
Vishay BCcomponents
TEST PROCEDURES AND REQUIREMENTS
IEC
60068-2TEST
METHOD
TEST
PROCEDURE
REQUIREMENTS
20 (Ta)
Solderability
2 s; 235 °C; Solder bath method; SnPb40
3 s; 245 °C; Solder bath method; SnAg3Cu0.5
Good tinning (≥ 95 % covered);
no damage
Solderability
(after ageing)
8 h steam or 16 h 155 °C;
leads immersed 6 mm:
for 2 s at 235 °C; solder bath (SnPb40)
for 3 s at 245 °C; solder bath (SnAg3Cu0.5)
Good tinning (≥ 95 % covered);
no damage
4.7
Voltage proof on
insulation
Maximum voltage URMS = 500 V
during 1 min; metal block method
No breakdown or flashover
4.16
Robustness of
terminations:
IEC
60115-1
CLAUSE
4.17
4.16.2
21 (Ua1)
Tensile all samples
Load 10 N; 10 s
Number of failures: < 1 x 10-6
4.16.3
21 (Ub)
Bending half
number of samples
Load 5 N; 4 x 90°
Number of failures: < 1 x 10-6
4.16.4
21 (Uc)
Torsion other half
of samples
3 x 360° in opposite directions
No damage ΔR max.: ± (0.5 % R + 0.05 Ω)
4.20
29 (Eb)
Bump
3 x 1500 bumps in three directions; 40 g
No damage ΔR max.: ± (0.5 % R + 0.05 Ω)
4.22
6 (Fc)
Vibration
Frequency 10 Hz to 500 Hz;
displacement 1.5 mm or
acceleration 10 g; three directions; total 6 h
(3 x 2 h)
No damage
ΔR max.: ± (0.5 % R + 0.05 Ω)
4.19
14 (Na)
Rapid change of
temperature
30 min at LCT and
30 min at UCT; 5 cycles
No visual damage
PR01: ΔR max.: ± (1 % R + 0.05 Ω)
PR02: ΔR max.: ± (1 % R + 0.05 Ω)
PR03: ΔR max.: ± (2 % R + 0.05 Ω)
4.23
Climatic sequence:
4.23.2
2 (Ba)
4.23.3
30 (Db)
Damp heat
(accelerated)
1st cycle
24 h; 55 °C; 90 % to 100 % RH
4.23.4
1 (Aa)
Cold
2 h; - 55 °C
4.23.5
13 (M)
Low air pressure
2 h; 8.5 kPa; 15 °C to 35 °C
4.23.6
30 (Db)
Damp heat
(accelerated)
remaining cycles
5 days; 55 °C; 95 % to 100 % RH
Rins min.: 103 MΩ
ΔR max.: ± (1.5 % R + 0.1 Ω)
4.24
78 (Cab)
Damp heat
(steady state)
56 days; 40 °C; 90 % to 95 % RH;
loaded with 0.01 P70 (Steps: 0 V to 100 V)
Rins min.: 1000 MΩ
ΔR max.: ± (3 % R + 0.1 Ω)
Endurance
(at 70 °C)
1000 h; loaded with P70 or Umax.;
1.5 h ON and 0.5 h OFF
ΔR max.: ± (5 % R + 0.1 Ω)
Temperature
coefficient
Between - 55 °C and + 155 °C
≤ ± 250 ppm/K
Insulation resistance
Maximum voltage (DC) after 1 min; metal block
method
Rins min.: 104 MΩ
4.25.1
4.8
4.6.1.1
Document Number: 28729
Revision: 14-Oct-09
Dry heat
16 h; 155 °C
For technical questions, contact: [email protected]
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123
PR01/02/03
Power Metal Film Leaded Resistors
Vishay BCcomponents
12NC INFORMATION FOR HISTORICAL
CODING REFERENCE
Last Digit of 12NC Indicating Resistance Decade
RESISTANCE DECADE
LAST DIGIT
0.22 to 0.91 Ω
7
For 5 % tolerance:
1 to 9.76 Ω
8
• The next 7 digits indicate the resistor type and packing
10 to 97.6 Ω
9
100 to 976 Ω
1
1 to 9.76 kΩ
2
10 to 97.6 kΩ
3
100 to 976 kΩ
4
1 MΩ
5
The resistors have a 12-digit numeric code starting with 23
• The remaining 3 digits indicate the resistance value:
- The first 2 digits indicate the resistance value
- The last digit indicates the resistance decade
For 1 % tolerance:
• The next 6 digits indicate the resistor type and packing
12NC Example
The 12NC for resistor type PR02 with Cu leads and a value
of 750 Ω with 5 % tolerance, supplied on a bandolier of
1000 units in ammopack, is: 2306 198 53751.
• The remaining 4 digits indicate the resistance value:
- The first 3 digits indicate the resistance value
- The last digit indicates the resistance decade
12NC - Resistor Type and Packaging (1)
23.. ... ..... (BANDOLIER)
AMMOPACK
TYPE
LEAD Ø
mm
TOL
(%)
RADIAL TAPED
4000 units
PR01
PR02
Cu 0.6
Cu 0.8
FeCu 0.6
PR03
Cu 0.8
FeCu 0.6
3000 units
REEL
STRAIGHT LEADS
RADIAL TAPED
52 mm
52 mm
63 mm
52 mm
5000 units
1000 units
500 units
5000 units
2000 units
-
1
-
-
22 196 1....
06 191 2....
-
06 191 5....
5
06 197 03...
-
22 193 14...
06 197 53...
-
06 197 23...
-
1
-
22 197 2....
-
22 197 1....
-
06 192 5....
2322 197 5....
5
-
06 198 03...
-
06 198 53...
-
06 198 23...
2322 198 04...
5
-
-
-
22 194 54...
-
-
-
5
-
-
-
-
22 195 14...
-
-
1
-
-
-
-
06 199 6...
-
-
5
-
-
-
-
22 195 54...
-
-
Notes
(1) Other packaging versions are available on request
• Preferred types in bold
12NC - Resistor Type and Packaging
23.. ... ..... (LOOSE IN BOX)
TYPE
PR01
PR02
PR03
DOUBLE KINK
LEAD Ø
mm
TOL
(%)
PITCH = 17.8 mm
PITCH = 25.4 mm
1000 units
500 units
1000 units
500 units
Cu 0.6
5
22 193 03...
-
-
-
FeCu 0.6
5
22 193 43...
-
22 193 53... (2)
-
Cu 0.8
5
22 194 23...
-
-
-
FeCu 0.6
5
22 194 83...
-
-
-
FeCu 0.8
5
-
-
22 194 63... (3)
-
PITCH (2)(3)(4)
Cu 0.8
5
-
22 195 23...
-
FeCu 0.6
5
-
22 195 83...
-
-
FeCu 0.8
5
-
-
-
22 195 63... (4)
Notes
(2) PR01 pitch 12.5 mm
(3) PR02 pitch 15.0 mm
(4) PR03 pitch 20.0 mm, with reversed kinking direction as opposed to the drawing for the type with double kink figure
• Preferred types in bold
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For technical questions, contact: [email protected]
Document Number: 28729
Revision: 14-Oct-09
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Please note that some Vishay documentation may still make reference to RoHS Directive 2002/95/EC. We confirm that
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requirements as per JEDEC JS709A standards. Please note that some Vishay documentation may still make reference
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Revision: 02-Oct-12
1
Document Number: 91000