PWR06JTRC1A1000 [TOKEN]
Pulse Withstanding Chip Resistor;型号: | PWR06JTRC1A1000 |
厂家: | TOKEN ELECTRONICS INDUSTRY CO., LTD. |
描述: | Pulse Withstanding Chip Resistor |
文件: | 总14页 (文件大小:1464K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Version:
September 20, 2017
(PWR)
Pulse Withstanding
Chip Resistor
Token Electronics Industry Co., Ltd.
Web: www.token.com.tw
mailto:rfq@token.com.tw
Taiwan: No.137, Sec. 1, Zhongxing Rd., Wugu District,
New Taipei City, Taiwan, R.O.C. 24872
Tel: +886 2981 0109
Fax: +886 2988 7487
China: 12F, Zhong Xing Industry Bld., Chuang Ye Road,
Nan Shan District, Shen Zhen City,
Guang Dong, China 518054
Tel: +86 755 26055363; Fax: +86 755 26055365
Product Introduction
Token (PWR) pulse withstanding chip resistors provide
50 percent increase in power dissipation.
Features :
High Power Rating
Applications :
Power Supplies, Diagnostic Equipment
Industrial Controls, LCD Video Monitors
Portable Battery Chargers, Medical Devices
Motor Controls and Line-Powered Equipment
Metering (Testing/Measurement), Circuit
Protection Devices
Tolerance from ±0.5% ~ ±5%
Improved Working Voltage Ratings
Standard Package sizes 0603 ~ 2512
Excellent Pulse Withstanding Performance
As electronic design engineers have increased the power
density of their equipment, the demand for smaller surface
mount single-chip circuit protection resistors has also
increased. Token developed the PWR Series resistors to
provide an economical alternative to bulky molded
wire-wound components or multi-chip solutions while saving
both PC board space and manufacturing costs.
To meet the increased demand for the PWR Series resistors,
Token has developed a series of pulse withstanding chip
resistors with improved power ratings in reduced surface
mounted sizes. Designated the PWR Series, the SMD resistors deliver up to 50 percent higher power
ratings than conventional surface mount resistors - up to 1.5W in a standard 2512 size chip.
Token is able to boost this power rating up to 50 percent through a combination of proprietary power
film materials and advanced manufacturing processes. The PWR Series Resistors are available in four
standard sizes (0603, 0805, 1206, 1210, 2010 and 2512) with power ratings from 0.125W to 1.5W, and
maximum operating voltage ratings for 100V to 500V. Resistance range is from 10 Ω to 20 MΩ, with
tolerance tight to 0.5 percent. The PWR meets restriction of hazardous substances RoHS directive and
RoHS compliance.
Along with the increased power ratings, the PWR Series resistors also feature high surge and high
voltage ratings, making them extremely stable in demanding surge and pulse environments. The PWR
Series chip resistors are specified for use in power supplies, circuit protection devices, portable battery
chargers, motor controls and line-powered equipment.
Token will also produce devices outside these specifications to meet specific customer requirements,
please contact our sales or link to Token official website " Chip Resistors "for more information.
Page: 1/13
Dimensions
Dimensions (Unit: mm) (PWR)
L
W
T
D1
(Unit: mm)
D2
(Unit: mm)
Weight
(g)/1000pcs
Codes
(Unit: mm)
1.60±0.10
2.00±0.10
3.10±0.10
3.10±0.10
5.00±0.10
6.35±0.10
(Unit: mm)
0.80±0.10
1.25±0.10
1.55±0.10
2.60±0.15
2.50±0.15
3.10±0.15
(Unit: mm)
0.45±0.10
0.50±0.10
0.55±0.10
0.55±0.10
0.55±0.10
0.55±0.10
0.30±0.20
0.35±0.20
0.50±0.25
0.50±0.25
0.60±0.25
0.60±0.25
0.30±0.20
0.40±0.25
0.50±0.20
0.50±0.20
0.50±0.20
0.50±0.20
2,042
4,368
PWR03 (0603)
PWR05 (0805)
PWR06 (1206)
PWR13 (1210)
PWR10 (2010)
PWR12 (2512)
8,947
15,959
24,241
39,448
Dimensions (Unit: mm) (PWR)
Pulse Withstanding Chips (PWR) Construction
Recommend Land Pattern (Unit: mm) (PWR)
Codes
A (mm)
B (mm)
0.60
C (mm)
0.90
0.90
PWR03 (0603)
PWR05 (0805)
PWR06 (1206)
PWR13 (1210)
PWR10 (2010)
PWR12 (2512)
1.20
0.70
1.30
2.00
0.90
1.60
2.00
0.90
2.80
3.80
0.90
2.80
3.80
1.60
3.50
Recommend Land Pattern (PWR)
Page: 2/13
Electrical Spec.
Standard Electrical Specifications (PWR)
Power
Rating
at 70℃
Max
Max
Resistance
Range
(Ω)
TCR
PPM/℃
Operating
Temp. Range
Resistance Tolerance
(%)
Type
Operating Overloading
Voltage
Voltage
±0.5%
10~294
1~294
±200
±200
±100
±200
±200
±100
±200
±200
±100
±200
±200
±100
±200
±200
±100
±200
±200
±100
PWR03
(0603)
1/10W
1/8W
1/3W
1/2W
3/4W
1.5W
-55 ~ +155℃ 50V
-55 ~ +155℃ 150V
-55 ~ +155℃ 200V
-55 ~ +155℃ 200V
100V
±1%, ±5%
±0.5%, ±1%, ±5%
±0.5%
300~1M
10~294
1~294
PWR05
(0805)
300V
400V
400V
800V
1000V
±1%, ±5%
±0.5%, ±1%, ±5%
±0.5%
300~20M
10~20
PWR06
(1206)
±1%, ±5%
1~20
±0.5%, ±1%, ±5%
±0.5%
20.5~20M
10~20
PWR13
(1210)
±1%, ±5%
1~20
±0.5%, ±1%, ±5%
±0.5%
20.5~20M
10~20
PWR10
(2010)
-55 ~ +155℃
400V
±1%, ±5%
1~20
±0.5%, ±1%, ±5%
±0.5%
20.5~20M
10~20
PWR12
(2512)
-55 ~ +155℃ 500V
±1%, ±5%
1~20
±0.5%, ±1%, ±5%
20.5~20M
Lower Resistance :(1~10)Ω.
Operating Voltage = ( 퐏 ∗ 퐑 ) , or Max. Operating Voltage listed in above table whichever is lower.
√
Overloading Voltage = 2.5* ( 퐏 ∗ 퐑 ) , or Max. Overloading Voltage listed in above table whichever is lower.
√
Optional specifications can be required.
Page: 3/13
High Power Rating Electrical Specifications (PWR)
Power
Rating
at 70℃
Operating
Temp.
Range
Max
Operating
Voltage
Max
Overloading
Voltage
Resistance
Range
(Ω)
TCR
PPM/℃
Resistance Tolerance
(%)
Type
±0.5%
10~294
1~294
±200
±200
±100
±200
±200
±100
±200
±200
±100
±200
±200
±100
PWR03
(0603)
1/8W, 1/5W -55 ~ +155℃ 50V
100V
300V
400V
800V
±1%, ±5%
±0.5%, ±1%, ±5%
±0.5%
300~1M
10~294
1~294
PWR05
(0805)
-55 ~ +155℃
1/4W
1/2W
1W
150V
±1%, ±5%
±0.5%, ±1%, ±5%
±0.5%
300~20M
10~20
PWR06
(1206)
-55 ~ +155℃ 200V
-55 ~ +155℃ 400V
±1%, ±5%
1~20
±0.5%, ±1%, ±5%
±0.5%
20.5~20M
10~20
PWR10
(2010)
±1%, ±5%
1~20
±0.5%, ±1%, ±5%
20.5~20M
Lower Resistance :(1~10)Ω.
Operating Voltage = ( 퐏 ∗ 퐑 ) , or Max. Operating Voltage listed in above table whichever is lower.
√
Overloading Voltage = 2.5* ( 퐏 ∗ 퐑 ) , or Max. Overloading Voltage listed in above table whichever is lower.
√
Optional specifications can be required.
Page: 4/13
Environmental Characteristics
Environmental Characteristics (PWR)
Test Item
Specification
Test Method
JIS-C-5201-1 4.13
±0.5%
IEC-60115-1 4.13
Short Time Overload
RCWV*2.5 or Max Overloading Voltage whichever is lower for 5 seconds
JIS-C-5201-1 4.18
IEC-60068-2-58 8.2.1
-55℃~155℃, 5 cycles
Individual leaching area ≥5%
Total leaching area ≥10%
Leaching
JIS-C-5201-1 4.8
IEC-60115-1 4.8
+25/-55/+25/+125/+25℃
Temperature Coefficient of
Resistance
As Spec.
JIS-C-5201-1 4.25
IEC-60115-1 4.25.1
RCWV, 70℃, 1.5 hours ON, 0.5 hours OFF,
Load Life
(Endurance)
±(1%+0.05Ω)
total 1000 hours
JIS-C-5201-1 4.24
IEC-60115-1 4.24
40±2℃, 90~95%RH, RCWV 1.5 hours ON,
Humidity (Steady State)
(Damp Heat with Load)
±(0.5%+0.05Ω)
0.5 hours OFF, total 1000 hours
JIS-C-5202-7.2
96 hours @ +155℃ without load
±0.5%
±0.5%
Resistance to Dry Heat
JIS-C-5202-7.1
1hour,-65℃ followed by 45 minutes of RCWV
Low Temperature
Operation
JIS-C-5201-1 4.23
IEC-60115-1 4.23.2
at +155℃ for 1000 hrs. 2010, 2512 sizes: 2mm; Other sizes: 3mm
±(0.5%+0.05Ω)
±(1%+0.05Ω)
±(0.5%+0.05Ω)
Dry Heat
JIS-C-5201-1 4.33
IEC-60115-1 4.33
Bending once for 5 seconds. 2010, 2512 sizes: 2mm; Other sizes: 3mm
Bending Strength
JIS-C-5201-1 4.18
IEC-60115-1 4.18
260±5℃, 10±1seconds
Resistance to Soldering
Heat
JIS-C-5201-1 4.17
IEC-60115-1 4.17
245℃±5℃ for 3 seconds
95% min coverage
No breakdown or flashover
>10GΩ
Solderability
JIS-C-5201-1 4.7
IEC-60115-1 4.7
1.42 times Max. Operating Voltage for 1 minute
Dielectric Withstand
Voltage
(Voltage Proof)
JIS-C-5201-1 4.6
IEC-60115-1 4.6
Insulation Resistance
Max. Overload Voltage for 1 minute
Power Derating Curve (PWR)
Note: Storage Temperature: 25±3℃; Humidity: <80%RH
Rated continuous Working Voltage (RCWV) = 퐏퐨퐰퐞퐫 퐑퐚퐭퐢퐧퐠 × 퐑퐞퐬퐢퐬퐭퐚퐧퐜퐞 퐕퐚퐥퐮퐞 (훀) or Max. Operating voltage
√
whichever is lower.
Storage Temperature: 15℃~28℃; Humidity < 80%RH;
Page: 5/13
Lightning Surge
Lightning Surge of Pulse Withstanding Chip Resistor (PWR)
1.2/50µs Lightning Surge Chip Resistor (PWR)
10/700µs Lightning Surge Chip Resistor (PWR)
Note: Lightning Surge of Pulse Withstanding Chip Resistors are tested in accordance with IEC 60 115-1 using both 10/700μs
and 1.2/50μs pulse shapes.
The limit of acceptance is a shift in resistance of less than 1% from the initial value.
Pulse withstanding capacity of Pulse Withstanding Chip Resistor (PWR)
Pulse withstanding capacity of Chip Resistor (PWR)
Note: The single impulse graph is the result of 50 impulses of rectangular shape applied at one-minute intervals.
The power applied was subject to the restrictions of the maximum permissible impulse voltage graph shown.
The limit of acceptance was a shift in resistance of less than 1% from the initial value.
Page: 6/13
Continuous Pulse of Pulse Withstanding Chip Resistor (PWR)
Continuous Pulse of Pulse Withstanding Chip Resistor (PWR)
Pulse Voltage of Chip Resistor (PWR)
Note: The continuous load graph was obtained by applying repetitive rectangular pulses where the pulse period was adjusted
so that the average power dissipated in the resistor was equal to its rated power at 70℃. Again the limit of acceptance was a
shift in resistance of less than 1% from the initial value.
Page: 7/13
Packaging & Reel Tape
Packaging Quantity & Reel Specifications (Unit: mm) (PWR)
Packaging Quantity
(KPcs)
Tape
Width
Reel
Diameter
ΦA
(mm)
178.5±1.5 60+1
ΦB
(mm)
ΦC
(mm)
W
(mm)
T
(mm)
Codes
5K
8mm
8mm
8mm
7 inch
13.0±0.2 9.0±0.5 12.5±0.5
13.0±0.2 9.5±0.5 13.5±0.5
13.0±0.2 9.5±0.5 13.5±0.5
PWR03
PWR05
PWR06
PWR13
Paper
10K
20K
10 inch
13 inch
254±1
330±1
100±0.5
100±0.5
4K
8K
12mm
12mm
7 inch
178.5±1.5 60+1
13.0±0.5 13.0±0.5 15.5±0.5
13.0±0.5 12.5±0.5 16.5±0.5
PWR10
PWR12
Embossed
10 inch
250±1 62±0.5
Packaging Quantity & Reel Specifications (PWR)
Page: 8/13
Paper Tape Specifications (Unit: mm) (PWR)
Codes A (mm) B (mm) W (mm) E (mm) F (mm) P0 (mm) P1 (mm) P2 (mm) ΦD0 (mm) T (mm)
1.10±0.10 1.90±0.1 8.0±0.2 1.75±0.1 3.50±0.05 4.00±0.10 4.00±0.05 2.00±0.05 1.50+0.1,-0 0.70±0.1
PWR03
1.60±0.10 2.40±0.2 8.0±0.2 1.75±0.1 3.50±0.05 4.00±0.10 4.00±0.05 2.00±0.05 1.50+0.1,-0 0.85±0.1
PWR05
1.90±0.10 3.50±0.2 8.0±0.2 1.75±0.1 3.50±0.05 4.00±0.10 4.00±0.05 2.00±0.05 1.50+0.1,-0 0.85±0.1
PWR06
2.90±0.10 3.50±0.2 8.0±0.2 1.75±0.1 3.50±0.05 4.00±0.10 4.00±0.05 2.00±0.05 1.50+0.1,-0 0.85±0.1
PWR13
Paper Tape Specifications (PWR)
Emboss Plastic Tape Specifications (Unit: mm) (PWR)
Codes A (mm) B (mm) W (mm) E (mm) F (mm) P0 (mm) P1 (mm) P2 (mm) ΦD0 (mm) T (mm)
2.8±0.10 5.5±0.10 12.0±0.3 1.75±0.1 5.5±0.05 4.00±0.10 4.00±0.1 2.00±0.05 1.50+0.1, -0
3.5±0.10 6.7±0.10 12.0±0.3 1.75±0.1 5.5±0.05 4.00±0.10 4.00±0.1 2.00±0.05 1.50+0.1, -0
1.2+0
1.2+0
PWR10
PWR12
Embossed Plastic Tape (PWR)
Page: 9/13
Application Notes
Pulse Withstanding Chip Resistors (PWR) Application & Soldering Notes
Today's electronic devices are becoming smaller and smaller. The requirement, in particular, for pulse
withstand capability is growing due to the need to protect sensitive modern electronic systems.
To meet this demand Token Electronics have designed a Pulse Withstanding Chip Resistor (PWR
Series). The enhanced performance of the chips is made possible by the precise use of the best
resistance inks and a closely controlled production process.
Application Notes:
Applications vary from line protection for telecommunications to surge withstanding resistors for use in
circuit breakers. Details of a typical telecomm and power supply application are given below.
Telephone lines can be subjected to a large range of voltage disturbances, many of which can damage
switching equipment. This has led to the need for circuit protection against both high voltage transients,
usually of short duration caused by lighting strikes and overloads of longer duration, due to direct
connection to mains power lines.
These two faults are separated into primary and secondary protection.
1.
2.
Primary protection handles the high voltage transients, and is usually located within the exchange.
Secondary protection is usually built into the equipment to be protected, and deals with both current and
voltage limiting.
Voltage limiting prevents damage to the equipment and shock hazards, and current limiting prevents
damage to wiring.
To determine the suitability of a (PWR) series chip resistors for your application refer to the pulse
withstanding data as given lighting surge performance using both 1.2/50μs and 10/700μs pulse shapes.
Soldering Notes:
Electrical connection to a ceramic substrate or to a printed circuit board can be made by
reflow or wave soldering of wrap-around terminations.
Wrap-around terminations provide good leach properties and ensure reliable contact.
Due to the robust construction, the (PWR) can be immersed in the solder bath for 30 seconds at 260℃.
This enables the resistor to be mounted on one side of a printed circuit board and wire-leaded components
applied on the other side.
(PWR) resistors themselves can operate at a maximum temperature of 155℃.
For soldered resistors, the joint temperature should not exceed 110℃.
This condition is met when the stated power levels at 70℃ and recommended pad and trace areas are
used.
Allowance should be made if smaller areas of copper are used.
Page: 10/13
Recommend Soldering Condition (PWR)
Recommend Soldering Condition (PWR)
Time of IR reflow soldering at maximum temperature point 260℃:10s
Page: 11/13
Order Codes
Order Codes (PWR)
PWR
05
D
TR
C1
W
10R0
Part
Number
Dimensions
Resistance
Tolerance
(%)
Package
Bulk
TCR
(ppm/℃)
Power
Rating
(W)
Resistance
Marking
Standard
(Ω)
03 EIA0603
05 EIA0805
06 EIA1206
13 EIA1210
10 EIA2010
12 EIA2512
P
10R0 10
Marking
for
E96/E24
C1 ±100
Taping
Reel
D
±0.5%
±1%
A
1.5
1/3
3/4
1
TR
1000
2201
1002
1003
1004
1005
100
C
±200
F
J
O
Q
T
2K2
10K
100K
1M
No
Marking
N
±5%
U
V
P
1/2
1/4
1/5
1/8
1/10
10M
W
X
0805~2512 4 digits marking for Example Marking
Resistance
100Ω
2.2KΩ
10KΩ
49.9KΩ
100KΩ
1003
1MΩ
1004
1000
2201
1002
4992
Marking
0603: 3 digits Marking E24 Nominal Table
E24 code 10 11 12 13 15 16 18 20 22 24 27 30 33 36 39 43 47 51 56 62 68 75 82 91
Example: 101=100Ω 102=1KΩ (1st and 2nd are E24 code and 3rd code is multiplier)
Resistance tolerance 1% for 0603: 3 digits marking in E96 (E96 series except E24 series)
Digits marking for Example: 13C=13K3Ω; 68B=4K99Ω; 68X=49.9Ω
Marking Table E96 Nominal Table
code 02 03 04 06 07 08 09 10 11 13 14 15 16 17 19 20 21 22 23 24 25 26 27
102 103 107 113 115 118 121 124 127 133 137 140 143 147 154 158 162 165 169 174 178 182 187
E96
code 28 29 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51
191 196 205 210 215 221 226 232 237 243 249 255 261 267 274 280 287 294 301 309 316 324 332
E96
code 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74
340 348 357 365 374 383 392 402 412 422 432 442 453 464 475 487 499 511 523 536 549 562 576
E96
code 75 76 77 78 79 80 81 82 83 84 86 87 88 89 90 91 92 93 94 95 96
590 604 619 634 649 665 681 698 715 732 768 787 806 825 845 866 887 909 931 953 976
E96
Multiplier E96 Marking
Code
A
B
C
D
E
F
X
Y
100
101
102
103
104
105
10-1
10-2
Multiplier
Page: 12/13
General Information
Token Thin Film Chips Add Powerful New Options
Token electronics provides the industry’s most comprehensive range of precision thin film
technologies for discrete, network, and integrated passive components used in instrumentation;
automotive electronics; communications systems; and portable electronics applications. Ultra-reliable
precision Nichrome resistive elements are available on ceramic or silicon substrates in a wide variety
of surface mount resistors.
In response to market demands for increased precision and stability, Token has expanded range of
nichrome thin-film chip resistors. Offering solutions to precision test and measurement and voltage
regulation across industrial, military and medical monitoring equipment markets designed to offer
superior humidity performance.
Token Thick Film Chips Cut the Cost of Precision Resistors
Token electronics has developed an extensive range of thick film / thin film resistive technologies for
electronic circuits in power supplies; test and measurement; industrial electronics; telecommunications;
audio circuits; automotive control systems; lighting controls; medical electronics; industrial equipment;
and control systems applications.
In addition to this, proven thick film technologies from Token electronics provide a large range of
standard resistive low Ohmic current sense products for critical battery management, and line
termination. The enhanced performance of the chips is made possible by the precise use of the best
resistance inks and a closely controlled production process.
Token Chip Low Ohmic Resistors come in Smaller Sizes and Minimized Power Consumption
Today’s electronic devices are becoming smaller and smaller. As a result, designers are moving more
towards surface mount components not only for new designs but also to design out large axial and
other through-hole resistors.
In most cases this is a straight forward task as several resistor manufacturers offer chip resistors with
performances to match axial parts. However in some cases, due to power rating or pulse withstanding
requirements, this has been impossible. The requirement, in particular, for pulse withstand capability is
growing due to the need to protect sensitive modern electronic systems. To meet this demand Token
electronics have designed a Pulse Withstanding Chip Resistor (PWR Series).
Page: 13/13
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