Title of Invention

SWITCHED-MODE POWER SUPPLY WITH A DAMPING NETWORK

Abstract ABSTRACT "SWITCHED-MODE POWER SUPPLY WITH A DAMPING NETWORK" The Switched-mode power supply having a transformer (TR) and a switching translator (T1) in series with the primary winding (WP) of the transformer (TR), whose first secondary winding (Wl) is coupled via a first diode (Dl) to a charge-storage capacitor (C1) which provides an operating voltage (U1), and is coupled via a series circuit with a second diode (D2) to this charge-storage capacitor (C1), and a first junction point (a) of the series circuit (D2, C2) is coupled via an inductance (L1) to a references potential, characterized in that a fourth diode (D4) is arranged between the reference potential and the first junction point (a), and a second junction point (b) between the inductance (L1) and the first junction point (a) is coupled to a second secondary winding (W2) of said transformer (TR). Figure 2
Full Text FORM 2
THE PATENTS ACT 1970
[39 OF 1970]
COMPLETE SPECIFICATION
[See Section 10; rule 13]
"SWITCHED-MODE POWER SUPPLY WITH A DAMPING NETWORK"
THOMSON LICENSING S.A., a French company of 46 Quai A. Le Gallo, F-92100 Boulogne-Billancourt, France,
GRANTED 5-3-2007
ORIGINAL 0023MUMNP 2004
The following specification particularly describes the nature of the invention and the manner in which it is to be performed :-

The present invention relates to Switched-mode power supply with a damping network.
The invention is based on a switched-mode power supply-having a transformer and having a switching transistor, which is connected in series with the primary winding of the transformer. Switched-mode power supplies of this type are used, for example, in televisions, video recorders or computer monitors, and preferably operate as flyback converters, in a power range from about 50 to 150 watts.
In the flyback converter mode, energy is stored in the transformer during the phase in which the switching transistor is switched on, and this is subsequently transmitted to the secondary side, during the phase in which the switching transistor is switched off. In this case, however, disturbing voltage spikes are produced when the switching transisitor switches off, and these lead to a severe voltage load on the switching transistor, as well as causing radiated interference. It is thus known for a damping network, also referred to as a snubber network, to be provided in parallel with the primary winding, and this network is used to limit the voltage spikes of the current input of the switching transistor when the switching transistor switches off. This network normally has a capcitor in parallel with the primary winding, which capcitor is charged when the switching transistor is switched off, and whose energy is then emitted to an energy-storage capacitor on the input side, or is consumed in a resistor and converted into heat. A damping network of this type is known, by way of example, from DE-A-40 29 221.
EP-A-0 695 023 discloses a switched-mode power supply which, in addition to a damping network in parallel with the primary winding, also has a second damping network in parallel with a winding on the secondary side of the transformer. In this case, a series circuit formed by a capcaitor and a second diode is connected in parallel with a rectifying diode, which produces a desired output voltage




across a charge-storage capacitor, and the centre point of this series circuit is connected to a reference potential via a diode and an inductance. Energy is in this case likewise transferred to the charge-storage capacitor via this capacitor, for energy recovery purposes, when the switching transistor switches off.
The method of operation of this switch-mode power supply will now be described in more detail with reference to Figure 1. This switched-mode power supply has a network connection UN, to which a network rectifier 1 followed by an energy-storage capacitor CO are connected, across which a DC voltage UO is produced. This is applied to a primary winding WP of a transformer TR, in series with which a switching transistor Tl is connected. The switching transistor Tl is driven in a known manner by a driver circuit 2, illustrated only symbolically here, with switching pulses 3. The switched-mode power supply in this case operates in particular in the flyback converter mode, in which energy is transferred from the transformer TR to one or more secondary windings during the phase in which the switching transitor Tl is switched off.
A damping network for damping voltage spikes when the transistor Tl is switched off is connected in parallel with the primary winding WP. This damping network has a series circuit formed by a capacitor Cs and a diode Ds, with a resistor Rs being connected in parallel with its diode. The voltage spikes which are produced when the switching transistor Tl switches off are in this case absorbed by the capacitor Cs and are partially fed back via the diode Ds to the energy-storage capacitor CO, while the remainder is converted into heat in the resistor Rs.

On the secondary side, the switched-mode power supply has a secondary winding Wl, which provides a desired output voltage Ul across a rectifier diode Dl and a charge-storage capacitor C1. In order to suppress voltage spikes and in

order to reduce the power losses in the switched-mode power supply, a damping network is likewise coupled to the secondary winding Wl. This damping network has a first series circuit with a capacitor C2 and a diode D2 in parallel with the diode Dl, as well as a second series circuit with an inductance L1 and a diode D4, which is arranged between a tap a on the first series circuit and a reference potential. A resistor Rl is also connected in parallel with the inductance L1 and is used to damp oscillations between this inductance and the capacitor C2.
The network on the secondary side, as shown in Figure 1, operates as follows: during the phase in which the switching transistor Tl is switched on, the voltage Us on the secondary winding Wl is negative, so that the capacitor C2 is charged via the inductance L1 and the diode D4. Thus, in the process, energy is stored in the capacitor C2, with the inductance L1 limiting the current rise during the charging process. When the switching transistor Tl is switched off, the voltage Us rises rapidly, until, in the end, the voltage Ul is reached, and the diode Dl changes to the forward-biased state, with the charge-storage capacitor C1 thus once again being recharged. However, the output voltage Ul is reached at an earlier stage across the capacitor C2, since the centre point a of the series circuit formed by C2 and D2 is positive with respect to the voltage Us. The diode D2 thus becomes forward-biased before the diode Dl, so that the voltage rise of the voltage Us is damped. The energy in the capacitor C2 is likewise transferred to the charge-storage capacitor C1 during this process. In this case, any oscillations which occur between the capacitor C2 and the inductance L1 are damped by the resistor Rl. Further details of the operation of this damping network are described in EP-A-0 695 023, which is hereby referred to.



A further damping network with a damping network on the primary side and a damping network on the secondary side is known from EP-A-0 279 335.
The object of the present invention is to reduce the power losses in a damping network on the secondary side of the previous type.
This object is achieved by a switched-mode power supply according to Claim 1. Advantageous developments of the invention are specified in the dependent claims.
According to the invention, the damping network has a connection for a second secondary winding, via which energy is transferred from this damping network, for example, to a charge-storage capacitor which is coupled to this secondary winding. The connection is advantageously produced via a rectifying element, for example a diode, which is coupled after the rectifying diode of the second secondary winding, thus preventing this secondary winding from having any reaction on the damping network.
In a further exemplary embodiment, the diode in the series circuit which is connected in parallel with the rectifier diode of the first secondary winding is not coupled to the charge-storage capacitor for the first secondary winding, but is likewise coupled to the charge-storage capacitor for the second secondary winding. This is particularly advantageous when the operating voltage of the first secondary winding is considerably higher than the operating voltage of the second secondary winding, so that this capacitor is discharged to a greater extent, and the damping characteristics of the.network when the switching transistor is switched off are improved. An LC low-pass filter is also arranged, in particular, in the connection between this capacitor and the charge-storage capacitor for the second secondary winding, and is used to prevent disturbing voltage spikes on thiS charge-storage capacitor.

The invention will be explained in more detail in the following text with reference, by way of example, to schematic drawings, in which:
Figure 1 shows a switched-mode power supply with a damping network according to the prior art arranged on the secondary side,
Figure 2 shows a damping network according to the invention arranged on the secondary side, which supplies energy not only to a charge-storage capacitor for a first secondary winding, but also to a charge-storage capacitor for a second secondary winding, and
Figure 3 shows a damping network arranged on the
secondary side, which has two connections for a second secondary winding.
The switched-mode power supply according to the invention operates, by way of example, on the flyback converter principle, with a switching transistor in series with a primary winding of the transformer, as explained with reference to Figure 1. However, it is not restricted to this principle. Reference should be made in particular to EP-A-0 695 023 for further details relating to the operation of this switched-mode power supply. Figures 2 and 3 show preferred exemplary embodiments of the invention, which relate to an improved damping network arranged on the secondary side. Identical components are thus provided with the same reference symbols. Furthermore, in Figures 2 and 3, the part of the switched-mode power supply which is on the primary side as well as further details of the secondary side, in particular regulation elements for voltage stabilization and further secondary windings, are not shown, since these do not relate to the present invention.


Figure 2 shows, schematically, a transformer TR for a switched-mode power supply with secondary windings Wl and W2, and arranged on the secondary side. The secondary winding Wl in this case produces a first operating voltage Ul via a diode Dl and a charge-storage capacitor C1, and the secondary winding W2 produces a second operating voltage U2 via a diode D5 and a charge-storage capacitor C3 . The operating voltages Ul and U2 are used in particular for supplying electronic circuits in a television.
Furthermore, the circuit as shown in Figure 2 has a damping network DN, which is coupled on the input side to the secondary winding Wl and on the output side to the charge-Storage capacitors C1 and C3. It contains a series
circuit comprising a capacitor C2 and a diode D2 in
parallel with the diode Dl, by means of which energy is transferred from the secondary winding Wl to the charge-storage capcitor C1, as already described in the introduction. Furthermore, a series circuit comprising an inductance L1, for example a coil with an inductance of 100 uH, and a diode D4 is coupled to a junction point a between the capacitor C2 and the diode D2, thus allowing a current to flow from a reference potential in the direction of the junction point a. A resistor Rl is also connected in
parallel with the inductance L1. To this extent, this
circuit corresonds to the damping network as described in Figure 1, with the exception of the change in the sequence of L1 and D4
According to the invention, a junction point between the junction point a and the inductance L1, in this exemplary embodiment a junction point b between the diode D4 and L1, is now connected to a second secondary winding W2 of the transformer TR. The connection is in this case produced via a diode D3, by means of which the inductance L1 is coupled to the charge-storage capacitor C3.

This circuit in this case operates as follows: when the switching transistor in the switched-mode power supply is switched on, the voltage Us on the secondary winding Wl is negative, so that the capacitor C2 is charged via the diode D4 and the inductance L1, corresponding to the negative forward voltage on this secondary winding. L1 in this case limits the charging current and in consequence results in the capacitor C2 being charged slowly when the switching transistor switches on.

when the switching transistor switches off, the voltage Us rises very rapidly and, when the voltage at the junction point a reaches the voltage Ul, the diode D2 becomes forward-biased, so that the capacitor C2 is discharged in the direction of the charge-storage capacitor C1. In the process, the diode D2 becomes forward-biased as a result of the positive voltage across the capacitor C2 upstream of the diode Dl so that, in consequence, the voltage rise of the voltage Us is limited, and the coupling between the transformer windings WP, Wl likewise limits the voltage rise across the switching transistor Tl. The charge which the capacitor C2 taps off from the secondary winding Wl in the process is in consequence fed back into the system once again, and is thus not lost. However, oscillations occur in this case between the capacitor C2 and the inductance LI, and these must be damped by the resistor Rl. However, these oscillations are now additionally damped by the diode D3, so that the power loss in the resistor Rl is considerably reduced.
Figure 3 shows a further exemplary embodiment of a damping network according' to the invention, arranged on the secondary side. However, in this case, the diode D2 is not coupled to the charge-storage capacitor C1 but, in the same way as the diode D3, is likewise coupled to the
charge-storage capacitor C3 for the secondary winding W2. This is particularly advantageous when the voltage Ul is considerably greater than the voltage U2. In this exemplary


"8—
embodiment, the voltage Ul is the system voltage Usys of, by way of example, 130 volts, and the operating voltage U2 is a voltage of 10 volts, so that the capacitor C2 can be discharged to a greater extent when the voltage Us on the secondary winding Wl is high. This achieves a greater damping effect.
Since, in this exemplary embodiment, the operating voltage U2 is used as a video supply voltage, a filter element, comprising an inductance L3 and a capacitor C4, is also arranged between the diode D2 and the charge-storage capacitor C3. This avoids picture interference resulting from voltage spikes on the supply voltage U2.
Further refinement forms of the invention are within the scope of a person skilled in the art and, by way of example, the diode D2 may also be connected to a further secondary winding of the transformer TR, instead of being connected to the secondary winding W2. In the exemplary embodiments explained here and in the claims, diodes are preferably used as the rectifying elements. However, within the scope of this invention, other rectifying elements, for example transistors which are switched for voltage rectification purposes, may also be used instead of diodes.


claim:
1)Switched-mode power supply having a transformer (TR) and a
switching translator (Tl) in series with the primary winding (WP) of
the transformer (TR), whose first secondary winding (W1) is coupled
via a first diode (Dl) to a charge-storage capacitor (C1) which provides
an operating voltage (Ul), and is coupled via a series circuit with a
second diode (D2) to this charge-storage capacitor (C1),
and a first junction point (a) of the series circuit (D2, C2) is coupled via an inductance (L1) to a references potential, characterized in that a fourth diode (D4) is arranged between the reference potential and the first junction point (a), and a second junction point (b) between the inductance (L1) and the first junction point (a) is coupled to a second secondary winding (W2) of said transformer (TR).
2) Switched-mode power supply as claimed in claim 1, wherein the second junction point (b) is coupled via a rectifying element (D3), in particular a third diode (D3), to a charge-storage capacitor (C3) of the second secondary winding (W2).
3) Switched-mode power supply as claimed in claim 1, wherein the fourth diode is arranged between the first inductance (L1) and the first junction point (a), and in that the anode of the rectifying element (D3) is coupled to a junction point (b) between the first inductance (LI) and the fourth diode (D4).
4) Switched-mode power supply as claimed in one of the preceding claims, wherein the series circuit has a second capacitor (C2) in series with the second diode (D2), and in that the first junction point (a) is arranged between the second capacitor (C2) and the second diode (D2).


5) Switched -mode power supply as claimed in one of the preceding claims, wherein the second diode (D2) is not coupled to the first secondary winding (Wl), but is coupled to the second winding (W2) or to a further secondary winding on the transformer(TR).
6) Switched-mode power supply as claimed in claim 5, wherein the cathode of the second diode {D2) is coupled to a charge-storage capacitor {C3) for this secondary winding (W2).
7) Switched-mode power supply as claimed in claim 5 or 6, wherein a filter (L2, C4) is arranged between the second diode (D2) and this secondary winding (W2).
8) Switched-mode power supply as claimed in claim 7, wherein the filter
(L2, C4) is an LC low-pass filter.
9) Switched-mode power supply as claimed in one of the preceding
claims, wherein the first operating voltage (Ul) is the system voltage
of a television or of a monitor and is, by way of example, more than
lOOV, and the second operating voltage (U2) is a low operating
voltage, in particular of less than 20V.
Dated this 09th day January 2004

(VINEET ROHILLA)
OF REMFRY& SAGAR
ATTORNEY FOR THE APPLICANTS
)

Documents:

23-mumnp-2004-abstract(05-03-2007).pdf

23-mumnp-2004-abstract(5-3-07).doc

23-mumnp-2004-cancelled pages(05-03-2007).pdf

23-mumnp-2004-claims(granted)-(05-03-2007).pdf

23-mumnp-2004-claims(granted)-(5-3-07).doc

23-mumnp-2004-correspondence(05-03-2007).pdf

23-mumnp-2004-correspondence(ipo)-(11-09-2007).pdf

23-mumnp-2004-drawing(05-03-2007).pdf

23-mumnp-2004-form 1(09-01-2004).pdf

23-mumnp-2004-form 13(22-05-2006).pdf

23-mumnp-2004-form 18(17-05-2006).pdf

23-mumnp-2004-form 2(granted)-(05-03-2007).pdf

23-mumnp-2004-form 2(granted)-(5-3-07).doc

23-mumnp-2004-form 3(09-01-2004).pdf

23-mumnp-2004-form 3(22-05-2006).pdf

23-mumnp-2004-form 5(05-03-2007).pdf

23-mumnp-2004-form-pct-isa-210(05-03-2007).pdf

23-mumnp-2004-petition under rule 137(05-03-2007).pdf

23-mumnp-2004-petition under rule 138(06-05-2007).pdf

23-mumnp-2004-power of authority(05-03-2007).pdf

23-mumnp-2004-power of authority(29-12-2003).pdf

abstract1.jpg


Patent Number 209909
Indian Patent Application Number 23/MUMNP/2004
PG Journal Number 42/2008
Publication Date 17-Oct-2008
Grant Date 11-Sep-2007
Date of Filing 09-Jan-2004
Name of Patentee THOMSON LICENSING S.A.
Applicant Address 46 QUAI A. LE GALLO, F-92100 BOULOGNE-BILLANCOURT, FRANCE,
Inventors:
# Inventor's Name Inventor's Address
1 ACHIM ELGERT LANGENACKERWEG 2A, D-78083 DAUCHINGEN, GERMANY.
2 MICHEL THIBAULT 26 RUE ROGER QUILLOT, F-49000 ANGERS,
3 JEAN PAUL LOUVEL AM BOEGLE 30, D-78086 BRIGACHTAL,
PCT International Classification Number H02M 3/335
PCT International Application Number PCT/EP02/07917
PCT International Filing date 2002-07-17
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 101 37 176.4 2001-07-31 Germany