BCR16A-10 datasheet, PDF - EEWORLD Datasheet

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BCR16A-10: DescriptionTRIAC, 500V V(DRM), 16A I(T)RMS, FLAT BASE PACKAGE; CategoryAnalog mixed-signal IC Trigger device; File Size95KB，5 Pages; ManufacturerMitsubishi; Websitehttp://www.mitsubishielectric.com/semiconductors/

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BCR16A-10 Overview

TRIAC, 500V V(DRM), 16A I(T)RMS, FLAT BASE PACKAGE

BCR16A-10 Parametric

Parameter Name	Attribute value
Maker	Mitsubishi
package instruction	,
Reach Compliance Code	unknown
Maximum DC gate trigger current	30 mA
Maximum DC gate trigger voltage	1.5 V
Maximum leakage current	3 mA
Maximum operating temperature	125 °C
Minimum operating temperature	-25 °C
Certification status	Not Qualified
Maximum rms on-state current	16 A
Off-state repetitive peak voltage	500 V
surface mount	NO
Trigger device type	TRIAC

BCR16A-10 Preview

MITSUBISHI SEMICONDUCTOR

〈TRIAC〉

BCR16A, BCR16B, BCR16C, BCR16E

MEDIUM POWER USE

A, B, C : NON-INSULATED TYPE, E : INSULATED TYPE, GLASS PASSIVATION TYPE

BCR16A, BCR16B, BCR16C, BCR16E

OUTLINE DRAWING

Dimensions

in mm

φ2.0

MIN

φ2.0

MIN

14 MAX

φ8.7

MAX

φ11.1

MAX

• I

T (RMS)

...................................................................... 16A

• V

DRM

..............................................................400V/500V

• I

FGT

, I

RGT

, I

RGT

........................................... 30mA

TERMINAL

GATE TERMINAL

BCR16A

APPLICATION

Contactless AC switches, light dimmer, on/off and speed control of small induction motors,

on/off control of traffic signals, on/off control of copier lamps,

solid state relay, microwave ovens

MAXIMUM RATINGS

Symbol

DRM

DSM

Parameter

Repetitive peak off-state voltage

Non-repetitive peak off-state

voltage

Voltage class

400

600

500

700

Unit

Symbol

T (RMS)

TSM

G (AV)

Parameter

RMS on-state current

Surge on-state current

for fusing

Peak gate power dissipation

Average gate power dissipation

Peak gate voltage

Peak gate current

Junction temperature

Conditions

Commercial frequency, sine full

wave, 360° conduction

BCR16A, B, C

BCR16E

=99°C

=71°C

3 MAX

6.5 MAX

Unit

°C

Ratings

60Hz sinewave 1 full cycle, peak value, non-repetitive

Value corresponding to 1 cycle of half wave 60Hz, surge on-state

current

170

121

0.5

–20 ~ +125

V1.

Gate open.

Feb.1999

19 MAX

MITSUBISHI SEMICONDUCTOR

〈TRIAC〉

BCR16A, BCR16B, BCR16C, BCR16E

MEDIUM POWER USE

A, B, C : NON-INSULATED TYPE, E : INSULATED TYPE, GLASS PASSIVATION TYPE

MAXIMUM RATINGS (continue)

Symbol

stg

Parameter

Storage temperature

BCR16A

—

Weight (Typical value)

BCR16B

BCR16C

BCR16E

—

iso

Soldering temperature

Mounting torque

Isolated voltage

BCR16A only, 10 sec.

BCR16C only (Typical value)

BCR16E only, T

=25°C, AC 1 minute, T

Terminal to base

Test conditions

Ratings

–20 ~ +125

3.0

8.5

9.5

230

2.94

1500

°C

kg·cm

N·m

Unit

°C

ELECTRICAL CHARACTERISTICS

Symbol

DRM

FGT

RGT

FGT

RGT

th (j-c)

th (j-b)

(dv/dt)

Gate non-trigger voltage

Thermal resistance

Critical-rate of rise of off-state

commutating voltage

Gate trigger

current

Gate trigger voltage

Parameter

Repetitive peak off-state current

On-state voltage

=125°C, V

=1/2V

DRM

Test conditions

=125°C, V

DRM

applied

=25°C, T

=25°C (BCR16E only), I

=25A , Instantaneous

measurement

Limits

Min.

—

Typ.

—

Max.

3.0

1.6

1.5

—

1.2

2.5

—

Unit

°C/W

V/µs

=25°C, V

=6V, R

=6Ω, R

=330Ω

—

0.2

—

=25°C, V

=6V, R

=6Ω, R

=330Ω

Junction to case (BCR16A, BCR16B, BCR16C)

Junction to base (BCR16E)

V2.

Measurement using the gate trigger characteristics measurement circuit.

V3.

The critical-rate of rise of the off-state commutating voltage is shown in the table below.

Voltage

class

DRM

(V)

(dv/dt)

Symbol

Min.

—

Unit

Test conditions

Commutating voltage and current waveforms

(inductive load)

400

V/µs

—

1. Junction temperature

=125°C

2. Rate of decay of on-state commutat-

ing current

(di/dt)

=–8A/ms

3. Peak off-state voltage

=400V

SUPPLY

VOLTAGE

MAIN CURRENT

MAIN

VOLTAGE

(dv/dt)c

(di/dt)c

TIME

500

Feb.1999

MITSUBISHI SEMICONDUCTOR

〈TRIAC〉

BCR16A, BCR16B, BCR16C, BCR16E

MEDIUM POWER USE

A, B, C : NON-INSULATED TYPE, E : INSULATED TYPE, GLASS PASSIVATION TYPE

OUTLINE DRAWING

BCR16B

2-φ3.2 MIN

20 MAX

Dimensions

in mm

BCR16C

2-φ3.2 MIN

BCR16E

5.3 MAX

20 MAX

21 MAX

Feb.1999

22 MAX

23±0.2

33 MAX

(16.2)

φ2.5

MIN

φ2.0

MIN

16 MAX

TERMINAL

GATE TERMINAL

φ2.0

MIN

15.5 MAX

φ2.0

MIN

10 MAX 16 MAX

1.9 MAX

(φ16)

23±0.2

φ33

MAX

8.5 MAX

3 MIN

21 MAX

φ2.0

MIN

1.8

MAX

10 MAX

1.8 MAX

8 MAX

20.5 MAX

φ8.7

MAX

φ8.7

MAX

φ8.7

MAX

M6×1.0

PERFORMANCE CURVES

MAXIMUM ON-STATE CHARACTERISTICS

SURGE ON-STATE CURRENT (A)

RATED SURGE ON-STATE CURRENT

200

180

160

140

120

100

2 3 4 5 7 10

ON-STATE CURRENT (A)

7 T

= 25°C

5 T

= 25°C

0.4 0.8 1.2 1.6 2.0 2.4 2.8 3.2 3.6 4.0 4.4

ON-STATE VOLTAGE (V)

CONDUCTION TIME

(CYCLES AT 60Hz)

GATE VOLTAGE (V)

3 V

= 1.5V

= 5.0W

= 2A

GATE TRIGGER CURRENT • VOLTAGE (T

= t°C)

GATE TRIGGER CURRENT • VOLTAGE (T

= 25°C)

2 V

= 10V

G(AV)

= 0.5W

100 (%)

GATE CHARACTERISTICS

GATE TRIGGER CURRENT·VOLTAGE VS.

JUNCTION TEMPERATURE

200

TEST PROCEDURE

Ι, ΙΙ

AND

ΙΙΙ

180

160

140

120

100

60 GATE TRIGGER

VOLTAGE

–40 –20 0 20 40 60 80 100 120 140 160

JUNCTION TEMPERATURE (°C)

GATE TRIGGER CURRENT

FGT I,

RGT I,

RGT III

= 0.2V

–1

2 3 5 7 10

GATE CURRENT (mA)

MITSUBISHI SEMICONDUCTOR

〈TRIAC〉

BCR16A, BCR16B, BCR16C, BCR16E

MEDIUM POWER USE

A, B, C : NON-INSULATED TYPE, E : INSULATED TYPE, GLASS PASSIVATION TYPE

MAXIMUM TRANSIENT THERMAL

IMPEDANCE CHARACTERISTICS

(JUNCTION TO CASE) (BCR16A, B, C)

MAXIMUM TRANSIENT THERMAL

IMPEDANCE CHARACTERISTICS

(JUNCTION TO BASE) (BCR16E)

TRANSIENT THERMAL IMPEDANCE (°C/W)

1.4

1.2

1.0

0.8

0.6

0.4

0.2

–1

2 3 5 7 10

CONDUCTION TIME

(CYCLES AT 60Hz)

TRANSIENT THERMAL IMPEDANCE (°C/W)

2 3 5 7 10

1.6

2 3 5 7 10

3.2

2.8

2.4

2.0

1.6

1.2

0.8

0.4

–1

2 3 5 7 10

CONDUCTION TIME

(CYCLES AT 60Hz)

MAXIMUM ON-STATE POWER

DISSIPATION

ALLOWABLE CASE TEMPERATURE

VS. RMS ON-STATE CURRENT

160

CURVES APPLY REGARDLESS

OF CONDUCTION ANGLE

ON-STATE POWER DISSIPATION (W)

360°

CONDUCTION

25 RESISTIVE,

INDUCTIVE

20 LOADS

8 10 12 14 16 18 20

CASE TEMPERATURE (°C)

140

120

100

BCR16A, BCR16B,

80 BCR16C

BCR16E

40 360°

CONDUCTION

20 RESISTIVE,

INDUCTIVE LOADS

0 2 4 6 8 10 12 14 16 18 20

RMS ON-STATE CURRENT (A)

AMBIENT TEMPERATURE (°C)

ALLOWABLE AMBIENT TEMPERATURE

VS. RMS ON-STATE CURRENT

(BCR16A)

160

160 160 t4.0

140

120 120 t3.0

120

80 80 t2.0

ALL FINS ARE

100

BLACK PAINTED

ALUMINUM AND GREASED

CURVES APPLY

REGARDLESS

OF CONDUCTION

ANGLE

NATURAL CONVECTION

: MOUNTING ON FIN

WITH SOLDER

: MOUNTING PLATE

WITHOUT GREASE

ALLOWABLE AMBIENT TEMPERATURE

VS. RMS ON-STATE CURRENT

(BCR16B)

160

140

120

100

CURVES APPLY

REGARDLESS

OF CONDUCTION

ANGLE

NATURAL CONVECTION

: MOUNTING ON FIN

WITHOUT GREASE

: INSULATED PLATE

WITH GREASE

ALL FINS ARE BLACK PAINTED

ALUMINUM AND GREASED

160 160 t4.0

120 120 t3.0

80 80 t2.0

8 10 12 14 16 18 20

RMS ON-STATE CURRENT (A)

Feb.1999

MITSUBISHI SEMICONDUCTOR

〈TRIAC〉

BCR16A, BCR16B, BCR16C, BCR16E

MEDIUM POWER USE

A, B, C : NON-INSULATED TYPE, E : INSULATED TYPE, GLASS PASSIVATION TYPE

ALLOWABLE AMBIENT TEMPERATURE

VS. RMS ON-STATE CURRENT

(BCR16C)

160

AMBIENT TEMPERATURE (°C)

140

120

100

AMBIENT TEMPERATURE (°C)

ALL FINS ARE BLACK PAINTED

ALUMINUM AND GREASED

NATURAL

160 160

CONVECTION

ALLOWABLE AMBIENT TEMPERATURE

VS. RMS ON-STATE CURRENT

(BCR16E)

160

140

120

100

CURVES APPLY

ALL FINS ARE BLACK PAINTED

ALUMINUM AND GREASED

RESISTIVE, INDUCTIVE LOADS

NATURAL CONVECTION

t4.0

120 120 t3.0

80 80 t2.0

160 160 t4.0

120 120 t3.0

80 80 t2.0

REGARDLESS

CURVES APPLY

OF CONDUCTION

ANGLE

: MOUNTING ON FIN

WITH GREASE

: MICA PLATE

WITH GREASE

REGARDLESS

OF CONDUCTION

ANGLE

8 10 12 14 16 18 20

RMS ON-STATE CURRENT (A)

GATE TRIGGER CHARACTERISTICS TEST CIRCUITS

6Ω

TEST PROCEDURE

6Ω

TEST PROCEDURE

Feb.1999

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BCR16A-10 Related Products

	BCR16A-10	BCR16B-10	BCR16B-8	BCR16C-10	BCR16C-8	BCR16A-8	BCR16E-10	BCR16E-8
Description	TRIAC, 500V V(DRM), 16A I(T)RMS, FLAT BASE PACKAGE	TRIAC, 500V V(DRM), 16A I(T)RMS, MOUNTING PLATE TYPE PACKAGE	TRIAC, 400V V(DRM), 16A I(T)RMS, MOUNTING PLATE TYPE PACKAGE	TRIAC, 500V V(DRM), 16A I(T)RMS, STUD TYPE PACKAGE	TRIAC, 400V V(DRM), 16A I(T)RMS, STUD TYPE PACKAGE	TRIAC, 400V V(DRM), 16A I(T)RMS, FLAT BASE PACKAGE	TRIAC, 500V V(DRM), 16A I(T)RMS	TRIAC, 400V V(DRM), 16A I(T)RMS
Maker	Mitsubishi	Mitsubishi	Mitsubishi	Mitsubishi	Mitsubishi	Mitsubishi	Mitsubishi	Mitsubishi
Reach Compliance Code	unknown	unknown	unknown	unknown	unknown	unknown	unknown	unknown
Maximum DC gate trigger current	30 mA	30 mA	30 mA	30 mA	30 mA	30 mA	30 mA	30 mA
Maximum DC gate trigger voltage	1.5 V	1.5 V	1.5 V	1.5 V	1.5 V	1.5 V	1.5 V	1.5 V
Maximum leakage current	3 mA	3 mA	3 mA	3 mA	3 mA	3 mA	3 mA	3 mA
Maximum operating temperature	125 °C	125 °C	125 °C	125 °C	125 °C	125 °C	125 °C	125 °C
Minimum operating temperature	-25 °C	-25 °C	-25 °C	-25 °C	-25 °C	-25 °C	-20 °C	-20 °C
Certification status	Not Qualified	Not Qualified	Not Qualified	Not Qualified	Not Qualified	Not Qualified	Not Qualified	Not Qualified
Maximum rms on-state current	16 A	16 A	16 A	16 A	16 A	16 A	16 A	16 A
Off-state repetitive peak voltage	500 V	500 V	400 V	500 V	400 V	400 V	500 V	400 V
surface mount	NO	NO	NO	NO	NO	NO	NO	NO
Trigger device type	TRIAC	TRIAC	TRIAC	TRIAC	TRIAC	TRIAC	TRIAC	TRIAC

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