IMPORTANT NOTICE
10 December 2015
1. Global joint venture starts operations as WeEn Semiconductors
Dear customer,
As from November 9th, 2015 NXP Semiconductors N.V. and Beijing JianGuang Asset
Management Co. Ltd established Bipolar Power joint venture (JV),
WeEn Semiconductors,
which
will be used in future Bipolar Power documents together with new contact details.
In this document where the previous NXP references remain, please use the new links as shown
below.
WWW
- For www.nxp.com use
www.ween-semi.com
Email
- For salesaddresses@nxp.com use
salesaddresses@ween-semi.com
For the copyright notice at the bottom of each page (or elsewhere in the document, depending
on the version) “
©
NXP Semiconductors N.V.
{year}.
All rights reserved”
becomes “
©
WeEn
Semiconductors Co., Ltd.
{year}.
All rights reserved”
If you have any questions related to this document, please contact our nearest sales office via e-
mail or phone (details via
salesaddresses@ween-semi.com).
Thank you for your cooperation and understanding,
WeEn Semiconductors
BT139-600E
4Q Triac
27 September 2013
Product data sheet
1. General description
Planar passivated sensitive gate four quadrant triac in a SOT78 (TO-220AB) plastic
package intended for use in applications requiring high bidirectional transient and
blocking voltage capability and high thermal cycling performance. Typical applications
include motor control, industrial and domestic lighting, heating and static switching. This
sensitive gate "series E" triac is intended to be interfaced directly to microcontrollers,
logic integrated circuits and other low power gate trigger circuits.
2. Features and benefits
•
•
•
•
•
Direct triggering from low power drivers and logic ICs
High blocking voltage capability
Planar passivated for voltage ruggedness and reliability
Sensitive gate
Triggering in all four quadrants
3. Applications
•
•
General purpose motor control
General purpose switching
4. Quick reference data
Table 1.
Symbol
V
DRM
I
TSM
I
T(RMS)
Quick reference data
Parameter
repetitive peak off-
state voltage
non-repetitive peak on- full sine wave; T
j(init)
= 25 °C;
state current
t
p
= 20 ms;
Fig. 4; Fig. 5
RMS on-state current
full sine wave; T
mb
≤ 99 °C;
Fig. 1;
Fig. 2; Fig. 3
Static characteristics
I
GT
gate trigger current
V
D
= 12 V; I
T
= 0.1 A; T2+ G+;
T
j
= 25 °C;
Fig. 7
V
D
= 12 V; I
T
= 0.1 A; T2+ G-;
T
j
= 25 °C;
Fig. 7
-
4
10
mA
-
2.5
10
mA
Conditions
Min
-
-
-
Typ
-
-
-
Max
600
155
16
Unit
V
A
A
Scan or click this QR code to view the latest information for this product
TO
-2
20A
B
NXP Semiconductors
BT139-600E
4Q Triac
Symbol
Parameter
Conditions
V
D
= 12 V; I
T
= 0.1 A; T2- G-;
T
j
= 25 °C;
Fig. 7
V
D
= 12 V; I
T
= 0.1 A; T2- G+;
T
j
= 25 °C;
Fig. 7
Min
-
-
Typ
5
11
Max
10
25
Unit
mA
mA
5. Pinning information
Table 2.
Pin
1
2
3
mb
Pinning information
Symbol Description
T1
T2
G
T2
main terminal 1
main terminal 2
gate
mounting base; main
terminal 2
Simplified outline
mb
Graphic symbol
T2
sym051
T1
G
1 2 3
TO-220AB (SOT78)
6. Ordering information
Table 3.
Ordering information
Package
Name
BT139-600E
BT139-600E/DG
TO-220AB
TO-220AB
Description
plastic single-ended package; heatsink mounted; 1 mounting
hole; 3-lead TO-220AB
plastic single-ended package; heatsink mounted; 1 mounting
hole; 3-lead TO-220AB
Version
SOT78
SOT78
Type number
BT139-600E
All information provided in this document is subject to legal disclaimers.
© NXP N.V. 2013. All rights reserved
Product data sheet
27 September 2013
2 / 13
NXP Semiconductors
BT139-600E
4Q Triac
7. Limiting values
Table 4.
Limiting values
In accordance with the Absolute Maximum Rating System (IEC 60134).
Symbol
V
DRM
I
T(RMS)
I
TSM
Parameter
repetitive peak off-state voltage
RMS on-state current
non-repetitive peak on-state
current
full sine wave; T
mb
≤ 99 °C;
Fig. 1;
Fig. 2; Fig. 3
full sine wave; T
j(init)
= 25 °C;
t
p
= 20 ms;
Fig. 4; Fig. 5
full sine wave; T
j(init)
= 25 °C;
t
p
= 16.7 ms
I t
dI
T
/dt
2
Conditions
Min
-
-
-
-
-
-
-
-
-
-
-
Max
600
16
155
170
120
50
50
50
10
2
5
0.5
150
125
Unit
V
A
A
A
2
I2t for fusing
rate of rise of on-state current
t
p
= 10 ms; SIN
I
T
= 20 A; I
G
= 0.2 A; dI
G
/dt = 0.2 A/µs;
T2+ G+
I
T
= 20 A; I
G
= 0.2 A; dI
G
/dt = 0.2 A/µs;
T2+ G-
I
T
= 20 A; I
G
= 0.2 A; dI
G
/dt = 0.2 A/µs;
T2- G-
I
T
= 20 A; I
G
= 0.2 A; dI
G
/dt = 0.2 A/µs;
T2- G+
A s
A/µs
A/µs
A/µs
A/µs
A
W
W
°C
°C
I
GM
P
GM
P
G(AV)
T
stg
T
j
peak gate current
peak gate power
average gate power
storage temperature
junction temperature
over any 20 ms period
-
-40
-
BT139-600E
All information provided in this document is subject to legal disclaimers.
© NXP N.V. 2013. All rights reserved
Product data sheet
27 September 2013
3 / 13
NXP Semiconductors
BT139-600E
4Q Triac
50
I
T(RMS)
(A)
40
001aab090
20
I
T(RMS)
(A)
15
001aab091
(1)
30
10
20
5
10
0
10
- 2
10
- 1
1
10
surge duration (s)
0
- 50
0
50
100
T
mb
(°C)
150
f = 50 Hz; T
mb
= 99 °C
Fig. 1.
RMS on-state current as a function of surge
duration; maximum values
25
P
tot
(W)
20
(1) T
mb
= 99 °C
Fig. 2.
RMS on-state current as a function of mounting
base temperature; maximum values
001aab093
95
T
mb(max)
(°C)
101
α=
180
120
90
15
60
30
107
10
α
113
5
α
119
0
0
5
10
15
I
T(RMS)
(A)
125
20
α = conduction angle
a = form factor = I
T(RMS)
/ I
T(AV)
Fig. 3.
Total power dissipation as a function of RMS on-state current; maximum values.
BT139-600E
All information provided in this document is subject to legal disclaimers.
© NXP N.V. 2013. All rights reserved
Product data sheet
27 September 2013
4 / 13
京公网安备 11010802033920号
EEWORLD
