Sharp 28JW-73H (serv.man2) Service Manual ▷ View online
50Hz Widescreen Colour Television – GA20 Chassis
Sharp Electronics (UK) Ltd
Technical Support
Issued June 02
Page 5
S
TANDBY
During standby Q754 is turned on by the microprocessor which has the effect of connecting D757 and
D712 in parallel across D758. This will keep the opto-coupler (IC702) turned on, simulating an over
voltage condition. IC701 is now operating in burst mode.
D712 in parallel across D758. This will keep the opto-coupler (IC702) turned on, simulating an over
voltage condition. IC701 is now operating in burst mode.
S
ECONDARY
P
ROTECTION
In the event that a secondary supply rails fails due to excessive current or increases beyond safe
limits then this power supply is designed to return to the burst start-up mode.
limits then this power supply is designed to return to the burst start-up mode.
Q704
D712
Q701
R717
10K
R719
10K
D706
R723
2K2
R707
150K
R703
150K
D710
C15
R725
2K7
D708
R724
10R
+350v
IC701 Pin 4
(demag)
1
2
Part
of
T703
IC702
IC701 Pin 1
(vcc)
IC701 Pin 3
(ctl)
IC703
C714
22µF
C705
22µF
This is achieved by a supply rail monitoring circuit which consisting of Q751, Q752, Q753, Q762 and
Q759, and a control circuit consisting of IC703, Q701, D706 and D712.
The opto-coupler (IC703) is normally turned off. If it is turns on, then thyristor D706 will conduct,
turning on Q701. Q701 emitter is connected to power supply ground and its collector is connected via
D712 to IC701 pin 1 (VCC ). Therefore, while Q701 is turned on it is impossible for the voltage at
IC701 pin 1 (VCC) to reach its turn on threshold, hence the power supply remains in burst mode.
50Hz Widescreen Colour Television – GA20 Chassis
Sharp Electronics (UK) Ltd
Technical Support
Issued June 02
Page 6
Q751
Q752
R743
4K7
R746
4K7
R747
2K2
R758
10K
D759
D758
R749
2K2
R756
12K
Q753
R755
5K6
D761
D760
R754
18K
R766
1K
D774
Q759
D770
R765
1K8
R764
8K2
D766
R774
1K
D775
R781
1K
D773
+5v Stby
-16v
+16v
IC703
R771
15K
+5v Stby
Stby
+10V
R794
1K
Q762
D783
C787
D784
D787
C12
D785
C6v2
C6v2
D786
R795
39K
+14v
CRT
Heaters
C774
1µF
Excessive EHT
If the EHT increases then the horizontal flyback pulses will also increase. The +14v is horizontal
flyback pulses rectified by D601, Therefore if the EHT increases then the +14v would also increase.
The +14v is monitored by D785, C774 and R795 and applied to the base of Q762 which is normally
turned off. When Q762 turns on it will forward bias D770, D759 and D758 causing Q752 to turn on.
When Q752 turns on Q751 turns on, turning on the thyristor D706 via IC703, removing IC701 Vcc,
resulting in the power supply entering burst mode.
If the EHT increases then the horizontal flyback pulses will also increase. The +14v is horizontal
flyback pulses rectified by D601, Therefore if the EHT increases then the +14v would also increase.
The +14v is monitored by D785, C774 and R795 and applied to the base of Q762 which is normally
turned off. When Q762 turns on it will forward bias D770, D759 and D758 causing Q752 to turn on.
When Q752 turns on Q751 turns on, turning on the thyristor D706 via IC703, removing IC701 Vcc,
resulting in the power supply entering burst mode.
CRT Heater Voltage
An increase in CRT heater voltage has a similar effect to excessive EHT, but this time the monitoring
component is D787.
An increase in CRT heater voltage has a similar effect to excessive EHT, but this time the monitoring
component is D787.
50Hz Widescreen Colour Television – GA20 Chassis
Sharp Electronics (UK) Ltd
Technical Support
Issued June 02
Page 7
Horizontal Output Stage
The horizontal output stage employed in the GA20 chassis is a conventional transformer driver circuit
with a diode modulator for the purpose of east west correction.
If the horizontal output stage develops a short circuit, the power supply will operate in burst mode. To
confirm that it is the horizontal output stage causing burst mode operation; remove the HT feed to
T602 by disconnecting R606.
Q601
R602
220R
220R
R601
150R
150R
Q1006
T601
R605
5K6
R604
2K7
R607
15R
Q602
R606
3R3
D602
D603
C605
4700pF
C610
8500pF
C611
0.033µF
C608
8100pF
Scan Coils
East/West
C606
150pF
Part of T602
Fly-back TX
C602
560pF
150V
C601
1000pF
IC1001 Pin 76
H-drive
IC1001 Pin 81
H-mµte
4
1
H
ORIZONTAL
D
RIVE
M
UTE
Q1006 is the horizontal drive muting transistor which is controlled by the microprocessor (IC1001) pin
81, At switch on IC1001 pin 81 is high, keeping Q1006 turned on, shorting the horizontal drive to
ground. Once IC1001 start-up sequence is complete and it is ready to allow the horizontal stage to
start, pin 81 will go low turning off Q1006, allowing the horizontal drive to reach the driver transistor
Q601.
If at any time the microprocessor detects a fault where it needs to stop the horizontal drive for safety
reasons then Q1006 will be turned on again.
H
ORIZONTAL
O
UTPUT
T
HEORY
Consider the circuit at rest, i.e. the beam spot at the centre and no current flowing through the scan
coils. The S-correction (DC blocking) and the fly back tuning capacitor charged.
coils. The S-correction (DC blocking) and the fly back tuning capacitor charged.
Scan Coils
S-Correction
Fly-Back Tuning
Capacitor
Efficiency
Diode
Horizontal
Output
Direction Of Scan
Scan is initiated when the horizontal output transistor is switched on.
50Hz Widescreen Colour Television – GA20 Chassis
Sharp Electronics (UK) Ltd
Technical Support
Issued June 02
Page 8
Scan Coils
S-Correction
Fly-Back Tuning
Capacitor
Efficiency
Diode
Horizontal
Output
Direction Of Scan
This causes current to flow through the scan coils from the S-correction capacitor, which results in a
linear build up of magnetic energy in the scan coils that will move the beam spot from the centre
position towards the right hand edge of the CRT.
Scan Coils
S-Correction
Fly-Back Tuning
Capacitor
Efficiency
Diode
Horizontal
Output
Direction Of Scan
At the point where horizontal drive pulse returns to zero, and the horizontal output transistor turns off.
The magnetic energy that has built up in the scan coils begins to collapse at a rate determined by the
flyback tuning capacitors. A back emf is produced by this collapsing magnetic field which charges the
flyback tuning capacitor. The spot will now move from the right hand edge of the CRT towards the left
at a higher speed. When the beam spot reaches the centre position the current through the scan coils
(magnetic field totally collapsed) is at a minimum and the voltage across the flyback tuning capacitor
is at a maximum. The charge that has been built up in the flyback tuning capacitor will now flow in the
reverse direction through the scan coils keeping the beam spot moving towards the left hand side of
the CRT.
When the voltage across the tuning capacitor becomes zero all the energy is now stored in the scan
coils as a magnetic field, flyback is completed.
Scan Coils
S-Correction
Fly-Back Tuning
Capacitor
Efficiency
Diode
Horizontal
Output
Direction Of Scan
As a linear scanning current is required, the oscillation set up in the scan coils and tuning capacitors
during flyback has to be stopped. If resistance were used to damp the oscillation (15625 times/sec)
the stored energy would be wasted. The oscillation is damped by a diode connected across the
collector/emitter (can be encapsulated within the transistor).
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