NP3500SBMCT3G [ONSEMI]

80A, Ultra Low Capacitance TSPD; 80A ，超低电容TSPD


型号：	NP3500SBMCT3G
厂家：	ONSEMI
描述：	80A, Ultra Low Capacitance TSPD 80A ，超低电容TSPD 光电二极管
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NP-SBMC Series

80A, Ultra Low Capacitance

TSPD

The NP−SBMC series of Low Capacitance Thyristor Surge

Protection Devices (TSPD) protect sensitive electronic equipment

from transient overvoltage conditions. Due to their ultra low off−state

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capacitance (C ), they offer minimal signal distortion for high speed

equipment such as ADSL2+, VDSL and T1/E1 circuits. The low

nominal offstate capacitance translates into the extremely low

differential capacitance offering superb linearity with applied voltage

or frequency. These reliable silicon devices are also a suitable

alternative to GDT protectors.

The NP−SBMC Series helps designers to comply with the various

regulatory standards and recommendations including:

GR−1089−CORE,IEC 61000−4−5, ITU K.20/K.21/K.45, IEC 60950,

TIA−968−A,FCC Part 68, EN 60950, UL 1950.

ULTRA LOW CAPACITANCE

BIDIRECTIONAL SURFACE

MOUNT THYRISTOR

80A, 10x1000ms SURGE

Features

• Ultra Low − Micro Capacitance

• Low Leakage (Transparent)

• High Surge Current Capabilities

• Precise Turn on Voltages

• Low Voltage Overshoot

• These are Pb−Free Devices

SMB

JEDEC DO−214AA

CASE 403C

Typical Applications

• xDSL Central Office and Customer Premise

• T1/E1

• Other Broadband High Speed Data Transmission Equipment

MARKING DIAGRAM

ELECTRICAL CHARACTERISTICS

AYWW

xxxBMG

C , 2 V,

1 MHz

C , 50 V,

1 MHz

(BO)

DRM

pF (Max)

Device

xxx

= Assembly Location

= Year

= Work Week

= Specific Device Code

(NPxxx0SBMC)

= Pb−Free Package

NP0640SBMCT3G

NP0720SBMCT3G

NP0900SBMCT3G

NP1100SBMCT3G

NP1300SBMCT3G

NP1500SBMCT3G

NP1800SBMCT3G

NP2100SBMCT3G

NP2300SBMCT3G

NP2600SBMCT3G

NP3100SBMCT3G

NP3500SBMCT3G

$58

$65

$77

$88

$75

$98

$90

$130

$160

$180

$220

$240

$260

$300

$350

$400

$120

$140

$170

$180

$190

$220

$275

$320

(Note: Microdot may be in either location)

ORDERING INFORMATION

†

Device

Package

Shipping

NPxxx0SBMCT3G

SMB

(Pb−Free)

2500 /Tape &

Reel

†For information on tape and reel specifications,

including part orientation and tape sizes, please

refer to our Tape and Reel Packaging Specifications

Brochure, BRD8011/D.

G in part number indicates RoHS compliance

Other protection voltages are available upon request

Symmetrical Protection − Values the same in both negative and positive

excursions

(See V−I Curve on page 3)

Publication Order Number:

September, 2008 − Rev. 1

NP3100SBMC/D

NP−SBMC Series

SURGE RATINGS

TSM

PPS

di/dt

Waveform (ms)

2x10

250

8x20

250

10x160

150

10x560

10x360

125

10x1000

5x310

100

0.1 s

A/ms

60 Hz

Value

100

500

MAXIMUM RATINGS (T = 25°C unless otherwise noted)

Symbol

Rating

Value

Unit

Repetitive peak off−state voltage: Rated maximum

(peak) continuous voltage that may be applied in the

off−state conditions including all dc and repetitive

alternating voltage components.

NP0640SBMCT3G

NP0720SBMCT3G

NP0900SBMCT3G

NP1100SBMCT3G

$58

$65

$75

$90

$120

$140

$170

$180

$190

$220

$275

$320

250

DRM

NP1300SBMCT3G

NP1500SBMCT3G

NP1800SBMCT3G

NP2100SBMCT3G

NP2300SBMCT3G

NP2600SBMCT3G

NP3100SBMCT3G

NP3500SBMCT3G

2x10 ms, GR−1089−CORE

8x20 ms, IEC−61000−4−5

10x160 ms, TIA−968−A

10x560 ms, TIA−968−A

10x360 ms, GR−1089−CORE

Nonrepetitive peak pulse current: Rated maximum

value of peak impulse pulse current that may be

applied.

PPS

250

150

100

125

10x1000 ms, GR−1089−CORE

5x310 ms, ITU−K.20/K.21/K.45

0.1s, 50/60 Hz, full sine wave

100

Nonrepetitive peak on−state current: Rated

maximum (peak) value of ac power frequency

on−state surge current which may be applied for a

specified time or number of ac cycles.

TSM

Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the

Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect

device reliability.

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NP−SBMC Series

ELECTRICAL CHARACTERISTICS TABLE (T = 25°C unless otherwise noted)

Symbol

Rating

Min Typ Max

$77

Unit

(BO)

Breakover voltage: The maximum voltage across the device in or at the NP0640SBMCT3G

breakdown region.

NP0720SBMCT3G

NP0900SBMCT3G

NP1100SBMCT3G

NP1300SBMCT3G

NP1500SBMCT3G

NP1800SBMCT3G

NP2100SBMCT3G

NP2300SBMCT3G

NP2600SBMCT3G

NP3100SBMCT3G

NP3500SBMCT3G

$88

VDC = 1000 V, dv/dt = 100 V/ms

$98

$130

$160

$180

$220

$240

$260

$300

$350

$400

800

Breakover Current: The instantaneous current flowing at the breakover voltage.

(BO)

Holding Current: The minimum current required to maintain the device in the on−state.

150

Off−state Current: The dc value of current that results from the applica-

tion of the off−state voltage

= 50 V

DRM

= V

DRM

On−state Voltage: The voltage across the device in the on−state condition.

I = 2.2 A (pk), PW = 300 ms, DC = 2%

dv/dt

di/dt

Critical rate of rise of off−state voltage: The maximum rate of rise of voltage (below V

will not cause switching from the off−state to the on−state.

) that

kV/ms

DRM

Linear Ramp between 0.1 V

and 0.9 V

DRM

Critical rate of rise of on−state current: rated value of the rate of rise of current which the device

can withstand without damage.

500

A/ms

Off−state Capacitance

f = 1.0 MHz, V = 1.0 V

NP0640SBMCT3G

NP0720SBMCT3G

NP0900SBMCT3G

NP1100SBMCT3G

NP1300SBMCT3G

NP1500SBMCT3G

NP1800SBMCT3G

NP2100SBMCT3G

NP2300SBMCT3G

NP3100SBMCT3G

NP3500SBMCT3G

, V = −2 Vdc

RMS

THERMAL CHARACTERISTICS

Symbol

Rating

Value

−65 to +150

−40 to +150

Unit

Storage Temperature Range

Junction Temperature

°C

STG

Thermal Resistance: Junction−to−Ambient Per EIA/JESD51−3, PCB = FR4 3”x4.5”x0.06”

Fan out in a 3x3 inch pattern, 2 oz copper track.

°C/W

0JA

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NP−SBMC Series

ELECTRICAL PARAMETER/RATINGS DEFINITIONS

Symbol

Parameter

PPS

Repetitive Peak Off−state Voltage

Breakover Voltage

DRM

TSM

(BO)

Off−state Current

DRM

Off−State Region

Breakover Current

(BO)

−Voltage

+Voltage

Holding Current

DRM

On−state Voltage

(BO)

On−state Current

DRM

Nonrepetitive Peak On−state Current

Nonrepetitive Peak Impulse Current

Off−state Voltage

TSM

PPS

Off−state Current

−I

Figure 1. Voltage Current Characteristics of TSPD

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NP−SBMC Series

100

t = rise time to peak value

t = decay time to half value

Peak

Value

100

Half Value

0.1

100

1000

CURRENT DURATION (s)

TIME (ms)

Figure 2. Nonrepetitive On−State Current vs. Time

Figure 3. Nonrepetitive On−State Impulse vs.

Waveform (I_PPS

(I_TSM

)

Detailed Operating Description

The TSPD or Thyristor Surge Protection Device are

specialized silicon based overvoltage protectors, used to

protect sensitive electronic circuits from damaging

overvoltage transient surges caused by induced lightning

and powercross conditions.

The electrical characteristics of the TSPD help the user to

define the protection threshold for the circuit. During the

open circuit condition the device must remain transparent;

this is defined by the I

. The I

should be as low as

DRM

possible. The typical value is less than 5 mA.

The TSPD protects by switching to a low on state voltage

when the specified protection voltage is exceeded. This is

known as a “crowbar” effect. When an overvoltage occurs,

the crowbar device changes from a high−impedance to a

low−impedance state. This low−impedance state then offers

a path to ground, shunting unwanted surges away from the

sensitive circuits.

The circuit operating voltage and protection voltage must

be understood and considered during circuit design. The

(BO)

is the guaranteed maximum voltage that the protected

circuit will see, this is also known as the protection voltage.

The V is the guaranteed maximum voltage that will

DRM

keep the TSPD in its normal open circuit state. The TSPD

is typically a 20−30% higher than the V . Based

(BO)

DRM

This crowbar action defines the TSPD’s two states of

functionality: Open Circuit and Short Circuit.

Open Circuit – The TSPD must remain transparent during

normal circuit operation. The device looks like an open

across the two wire line.

on these characteristics it is critical to choose devices which

have a V higher than the normal circuit operating

DRM

voltage, and a V

which is less than the failure threshold

(BO)

of the protected equipment circuit. A low on−state voltage

V allows the TSPD to conduct large amounts of surge

Short Circuit – When a transient surge fault exceeds the

TSPD protection voltage threshold, the devices switches on,

and shorts the transient to ground, safely protecting the

circuit.

current (500 A) in a small package size.

Once a transient surge has passed and the operating

voltage and currents have dropped to their normal level the

TSPD changes back to its open circuit state.

(OP)

•TSPD looks like an open

•Circuit operates normally

Protected

−

TSPD

(OP)

Equipment

−

Normal Circuit Operation

•Fault voltage greater than V occurs

(Fault)

•TSPD shorts fault to ground

•After short duration events the O/V

switches back to an open condition

•Worst case (Fail/Safe)

•O/V permanent short

•Equipment protected

Protected

(Fault)

TSPD

(Fault)

Equipment

−

Operation during a Fault

Figure 4. Normal and Fault Conditions

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NP−SBMC Series

DEVICE SELECTION

Transient Surge

When selecting a TSPD use the following key selection

parameters.

Off−State Voltage V_DRM

Equipment Failure Threshold

Choose a TSPD that has an Off−State Voltage greater than

the normal system operating voltage. The protector should

not operate under these conditions:

Example:

TSPD Protection Voltage

Upper Limit

Normal System

Vbat = 48 Vmax

Operating Voltage

TSPD Transparent

(open)

TSPD Protection

TSPD Transparent

(open)

Vring = 150 Vrms = 150*1.414 = 212 V peak

(short)

DRM

should be greater than the peak value of these two

components:

Time

V_DRM> 212 + 48 = 260 V_DRM

Figure 5. Protection During a Transient Surge

Breakover Voltage V_(BO)

TSPD’s are useful in helping designers meet safety and

regulatory standards in Telecom equipment including

GR−1089−CORE,ITU−K.20, ITU−K.21, ITU−K.45, FCC

Part 68, UL1950, and EN 60950.

ON Semiconductor offers a full range of these products in

the NP series product line.

Verify that the TSPD Breakover Voltage is a value less

than the peak voltage rating of the circuit it is protecting.

Example: Relay breakdown voltage, SLIC maximum

voltage, or coupling capacitor maximum rated voltage.

Peak Pulse Current Ipps

Choose a Peak Pulse current value which will exceed the

anticipated surge currents in testing. In some cases the 100 A

“C” series device may be needed when little or no series

resistance is used. When a series current limiter is used in the

circuit a lower current level of “A” or “B” may be used. To

determine the peak current divide the maximum surge

current by the series resistance.

Hold Current (I_H)

The Hold Current must be greater than the maximum

system generated current. If it is not then the TSPD will

remain in a shorted condition, even after a transient event

has passed.

TYPICAL APPLICATION

Tip

NP3100SBMC

Voice

DSL

NP3100SBMC

Ring

Figure 6. ADSL

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NP−SBMC Series

PACKAGE DIMENSIONS

SMB

CASE 403C−01

ISSUE A

NOTES:

1. DIMENSIONING AND TOLERANCING PER ANSI

Y14.5M, 1982.

2. CONTROLLING DIMENSION: INCH.

3. D DIMENSION SHALL BE MEASURED WITHIN

DIMENSION P.

INCHES

DIM MIN MAX

MILLIMETERS

MIN

4.06

3.30

1.90

1.96

MAX

4.57

3.81

2.41

2.11

0.152

0.30

1.27

0.160

0.130

0.075

0.077

0.180

0.150

0.095

0.083

0.0020 0.0060 0.051

0.006

0.030

0.012

0.050

0.15

0.76

0.020 REF

0.51 REF

0.205

0.220

5.21

5.59

SOLDERING FOOTPRINT*

2.261

0.089

2.743

0.108

2.159

0.085

inches

SCALE 8:1

*For additional information on our Pb−Free strategy and soldering

details, please download the ON Semiconductor Soldering and

Mounting Techniques Reference Manual, SOLDERRM/D.

ON Semiconductor and

are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice

to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability

arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages.

“Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All

operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights

nor the rights of others. SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications

intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death may occur. Should

Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees, subsidiaries, affiliates,

and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death

associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture of the part. SCILLC is an Equal

Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner.

PUBLICATION ORDERING INFORMATION

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For additional information, please contact your local

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NP3100SBMC/D

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NP3500SBMCT3G [ONSEMI]

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