Title of Invention

AN OPERATING METHOD FOR A DISCHARGE LAMP

Abstract Operating method for a discharge lamp (L) having a dielectric layer between at least one electrode and a discharge medium using a ballast having a power supplied primary circuit (P), a secondary circuit (S) containing the discharge lamp (L), and also a transformer (T) which connects the primary circuit (P) to the secondary circuit (S), in which method a voltage pulse is impressed on the secondary circuit (S) from the primary circuit (P) via the transformer (T), which voltage pulse leads to an external voltage (UL) effecting an ignition across the discharge lamp (L), and to an internal counterpolarization in the discharge lamp (L), characterized in that, after the voltage pulse has been impressed, the secondary circuit(S) performs an oscillation through which the charge is withdrawn again from the discharge lamp (L), until the counterpolarization leads to the back ignition, and the voltage pulse is impressed from the primary circuit (P) into the secondary circuit (S) according to the forward converter principle.
Full Text Technical field
This invention relates to an operating method for a discharge lamp.
The present invention relates to an operating method
and a corresponding electronic ballast for a discharge
lamp. In this case, the operating method and the
ballast relate to a specific type of discharge lamp, in
which so-called dielectrically impeded discharges are
utilized to generate light. In order to produce such
discharges, a dielectric layer is situated between at
least one of the discharge electrodes and the discharge
medium of the discharge lamp. The technology of
discharge lamps with dielectrically impeded discharges
is not discussed in detail here and, in this regard,
reference is made to the prior art.
Prior art
Technical development in this field has principally
been concerned heretofore with the discharge lamp as
such. One exception to this is an earlier patent
application in respect of a relevant operating method
with pulsed active power coupling into the discharge
lamp. In this respect, reference is made to
WO 94/23442, whose disclosure content is incorporated
here by reference. The operating method presented
therein forms the foundation for the invention
described below.
In this case, the present invention is concerned with
converting the operating procedure which is described
in principle in the cited prior art into an operating
method which is particularly advantageous in terms of
electrical engineering, and an associated electronic
ballast. When developing such an operating method and
ballast, the aim generally is to fulfil various quality
criteria in an overall compromise which is as favorable
as possible. Firstly, an electronic ballast should be
operated as power-efficiently as possible in order to
obtain, together with the efficiency of the lamp, a
good overall efficiency of an illumination system
comprising discharge lamp and ballast.
A second aspect concerns the electronic ballast having
a compact and lightweight design made possible by a
corresponding operating method, which ballast, in this
respect, is also suitable for installation in the case
of confined space conditions or weight restrictions.
This has a significant part to play precisely in the
areas of application which are of particular interest
with regard to discharge lamps with a dielectrically
impeded discharge. Examples are backlighting systems
for flat screens or copying lamps, which will be
discussed further on in the description.
Finally, economic advantages with regard to mass
production costs and service life and frequency of
failure are intended to be attained.
Summary of the invention
The invention is based on the technical problem
proceeding from the technical teaching of WO 94/23442
of specifying a particularly favorable operating method
using a ballast, and an illumination system and ballast
designed for this.
For this purpose, the invention provides an operating
method for a discharge lamp having a dielectric layer
between at least one electrode and a discharge medium
using a ballast having a power-supplied primary
circuit, a secondary circuit containing the discharge
lamp, and also a transformer which connects the primary
circuit to the secondary circuit, in which method a
voltage pulse is impressed on the secondary circuit
from the primary circuit via the transformer, which
voltage pulse leads to an external voltage UL effecting
an ignition across the discharge lamp L and to an
internal counterpolarization in the discharge lamp
characterized in that, by means of the ballast
afterward the charge effecting the external voltage
across the discharge lamp is withdrawn from the
discharge lamp and, in this way, the discharge lamp is
led to effect a back ignition by the remaining internal
counterpolarization.
Furthermore, the invention relates to an illumination
system having a discharge lamp and a ballast which is
designed for the operating method according to the
invention.
Finally, the invention also relates to a particular
design of a ballast which is suitable for the operating
method, namely in the form of a forward converter.
The various dependent claims relate to preferred
refinements of the invention.
The invention thus provides an operating method for a
discharge lamp of the type already described, in which
a ballast is used. For the purposes of this invention,
this ballast which is preferably an electronic
ballast coimorises a orimary circuit which is supplied
with power in a manner that is of no further interest
here and a secondary circuit into which the lamp is
intended to be connected or is connected. The primary
circuit and the secondary circuit are coupled via a
transformer via which power can be coupled into the
secondary circuit from the primary circuit.
Provision is now made for coupling a voltage pulse into
the secondary circuit via the transformer, which
voltage pulse leads to an external voltage across the
discharge lamp. The subsequent behavior of the
discharge lamp itself is of importance for the concept
underlying the invention. Specifically, it has been
found that, in the discharge lamps with dielectrically
impeded discharges which are considered here, a
counterpolarization occurs in the discharge lamp as a
dielectric reaction to the external voltage and as a
result of a discharge ignited by an external voltage.
To be precise, after the ignition voltage has been
reached, discharges are formed in the discharge medium,
as is described in more detail in the foundation
application pertaining to the operating method, to
which reference has already been made. As a
consequence, charge carriers move to the dielectric
layer on one of the electrodes and accumulate to an
increasing extent on the dielectric layer. This creates
an internal counterpolarization relative to the
external field which increases until an overall field
is no longer present in the discharge medium, which
also means that current can no longer flow through the
lamp. As a result, the discharge medium has changed
frdm a behavior acting as an ohmic load - although with
time-variable resistance - to an electrical behavior
manifested as capacitance.
Added to this is the fact that further capacitances are c
connected in series with the discharge medium, to be
precise in particular through one or a plurality of
dielectric layers on the electrodes.
Proceeding from this physical behavior of the discharge
lamp, the fundamental concept of the invention
consists, then, in not interpreting this internal
counterpolarization as a disturbing effect, but rather
integrating it functionally into the operating method
and also into the functional principle of the
associated ballast., In this sense, the operating method
according to the invention provides for the external
voltage across the discharge lamp, which originally
caused the counterpolarization just described, to be
withdrawn again from the discharge lamp sufficiently
rapidly in order to have the internal
counterpolarization lead to a further ignition in the
opposite direction after the first ignition effected by
the external voltage. This second ignition is in this
case designated as back ignition and is not attributed,
at any rate not completely, to an external voltage but
rather, at any rate at least partly, to the internal
counterpolarization.
In this application, for the sake of clarity of
explanation, it is thus argued that the external
voltage across the discharge lamp or the internal
counterpolarization effects an ignition. For the sake
of completeness, however, this must also be expanded by
stating that the ignition behavior of the lamp depends
on a number of further parameters. In particular, the
edge steepness or the dissipation when building up a
voltage across the lamp or a field in the lamp has a
significant part to play. This means that, for example,
an ignition _pn account of an external voltage across
the discharge lamp takes place at smaller voltage
values if said external voltage is built up very
rapidly. This basically empirical result can probably
be explained by the fact that the electrodes can follow
the field rise more poorly, possibly also by the fact
that with a steeper voltage rise and thus a larger
proportion of high-frequency Fourier components on the
voltage profile, the high-frequency conductivity in
particular of the dielectric is improved and the field
actually prevailing in the discharge medium is thus
enlarged.
Other time parameters also play a part, for instance
the so-called dead time between the individual active
power pulses. The longer this dead time is chosen to
be, the smaller the residual ionization which remains
at the end of the dead time, and thus the higher the
voltage which is necessary for renewed ignition.
The problems associated with these relationships will
not be discussed further in the rest of this
application because they are not directly connected
with the principle of this invention. However, it must
be kept in mind that a significant part is played not
only by the pure voltage values and the lamp parameters
for the ignition and back ignition behavior, but also
by the temporal parameters of the operating method.
With regard to the temporal order and the designations
first ignition and back ignition used below, it should
be noted that this operating method, apart from the
start of the discharge lamp, is of course directed at a
continuous discharge operation, so that the back
ignition is again followed by a "forward ignition",
that is to say first ignition. However, only a basic
unit of this repeated sequence will be considered in
the description of the invention, in which case, for
the sake of simplicity, the "first" ignition is
referred to the external voltage. Moreover, it is not
absolutely necessary here for the operating method
overall to be strictly periodic.
Accordingly, the invention also relates to an
illumination system, in this case meaning a system
comprising a discharge lamp and a ballast which are
designed for operation according to the operating
method according to the invention. To that end, the
ballast must be suitably coordinated with the
respective discharge lamp, with regard to the method of
functioning intended by the invention, above all with
regard to the capacitance.
The back ignition according to the invention has the
following essential advantages: firstly, at least a
considerable part of the energy which has passed to an
extent unavoidably into the counterpolarization is
converted into light generation by the back ignition
and the overall energy utilization is thus improved.
Although the counterpolarization could also be suitably
reduced in such a way that the energy stored therein
can flow back into the primary circuit via the
transformer, this is, of course, associated with an
overall increase in losses, because the proportion
which has passed back into the primary circuit must
again pass via the transformer and the secondary
circuit into the discharge lamp in order to be made
utilizable.
Furthermore, it emerges from the improved energy
utilization and, in particular, also in comparison with
a reduction of the counterpolarization in the form of
feedback into the primary circuit that the circuit of
the ballast can be designed to be smaller for a given
discharge lamp power. This follows simply from the fact
that, with the aid of the invention, the same discharge
lamp power can be supplied with a primary circuit which
is designed toward smaller power levels, to be precise
by virtue of the better energy utilization on the
secondary-circuit side and by virtue of the obviation
or reduction of the need to feed amounts of energy not
"consumed" on the secondary-circuit side back to the
primary-circuit side. To the extent of an improvement
of the energy utilization as such, the secondary-
circuit side can also be designed toward smaller power
levels.
Finally, it has also been found that the back ignition
is advantageous for the discharge physics in the
discharge lamp itself, in that it homogenizes the local
distributions of different chemical species and charge
carriers. Thus, the mode of operation according to the
invention, with back ignitions following first
ignitions, should not be understood in the sense that
back ignitions are to an extent accepted for electrical
engineering reasons, rather that, both from the
perspective of the physics of the discharge medium and
from an electrical engineering standpoint, it
represents a particularly favorable realization of the
underlying pulsed mode of operation in accordance with
the application to which reference has been made.
From the inventors viewpoint, it is useful, for an
understanding of the effects underlying the invention,
to make it clear that in the discharge lamps considered
by the invention, in comparison with metals, charge
carrier concentrations occur which are typically lower
by many orders of magnitude, so that external fields
can be compensated by an opposing field only with the
covering of comparatively larger distances by the
respective mobile charge carriers. These very much
larger distances in comparison with quasi
instantaneously shielding metals result in time delays,
from which it has been found that they can already
constitute a significant effect in the range of typical
pulse frequencies of the pulsed mode of operation
considered here.
What the invention involves, then, is a matter of
leading the secondary circuit to withdraw the external
voltage from the discharge lamp in the time period
between the first ignition and the back ignition. As
explained below, this can be done, in particular, by
allowing the Secondary circuit to oscillate through as
far as possible in an unbraked manner, that is also
possible, according to the invention, by means of
intervention on the part of the primary circuit, for
instance by means of shifting in the correct phase, or
by means of a pulse which is coupled in at a suitable
location and supports the charge transfers according to
the invention in the secondary circuit. Reference is
made to the disclosure content of the parallel
application "Electronic ballast for discharge lamp with
dielectrically impeded discharges" by the same
applicant on the same application day and with the file
reference 198 39 336.9.
According to a more specific aspect of the invention,
the back ignition in the discharge lamp is also used
for a further function over and above the aspect of
improved energy utilization. This further function
concerns the demagnetization of the transformer in the
ballast.
In this respect, it must firstly be explained that in
the case of a ballast having the above-described
construction comprising a primary circuit and a
secondary circuit connected to the primary circuit via
a transformer, in the case of active power coupling
into the secondary circuit in a pulsed manner,
generally a certain residual magnetization remains in
the transformer after the first ignition in the jargon
of this application. In the prior art, a very large
number of different possibilities have been proposed
for reducing this residual magnetization in order that
the transformer is not driven directly into magnetic
saturation during continuous operation by amounts of
residual magnetization which repeatedly build up on one
another. By way of example, it is possible to use
circuits comprising demagnetization coils and diodes,
said circuits being connected parallel with the primary
side of the transformer. An example of a relatively
complicated solution is shown by US 4 739 285. At any
rate, conventional ballasts from the prior art have, in
principle, demagnetization circuits configured in some
way.
According to the invention, then, in conjunction with
the withdrawal of the external voltage or the charge
effecting the latter from the discharge lamp in
preparation for the back ignition, at least a
considerable part of the residual magnetization in the
transformer is removed at the same time. As a result,
depending on the exact embodiment of the circuit,
demagnetization circuits according to the prior art can
either be completely omitted or actually be designed
with regard to distinctly smaller amounts of residual
magnetization. In particular, it is alternatively
possible to work without any demagnetization circuit,
in that the secondary-circuit side, as a result of the
back ignition, largely consumes the amount of energy
corresponding to the residual magnetization from the
transformer and any remaining small amount of energy
can, if appropriate, be suitably fed back into the
primary circuit through the transformer itself, but
does not necessarily have to be fed back. This will be
explained in further detail below.
Finally, it must be established here that the residual
magnetization in no way has to be returned to zero
after the back ignition in the case of this invention.
More generally, it is not necessary for the secondary
circuit to become entirely energy-free after the back
ignition. All that is crucial is that a saturation
state of the transformer be avoided. Furthermore, a
voltage possibly remaining across the discharge lamp -
taking account of the steepness of the edges occurring
- must not, of course, reach the ignition voltage. In
this sense, the associated claims should be understood
such that the intention is to make at least a
contribution to the demagnetization of the transformer.
An advantage of the invention's demagnetization of the
transformer by the reduction of the external voltage
across the discharge lamp and the back ignition is
firstly the possibility of either avoiding
demagnetization circuits entirely or designing them to
be smaller. The preferred case is the one in which the
ballast according to the invention has no separate
demagnetization circuit. As a result, the circuit not
only becomes more efficient but also simpler and less
expensive. The omission of the components associated
with a conventional demagnetization circuit means that
it is also possible to achieve a gain in reliability.
In particular, however, it has been found to be an
essential advantage of the invention that corresponding
ballasts can be made quite considerably much smaller
and lighter than conventional comparison circuits. This
is quite a considerable advantage for many
applications, for example in the areas of copying lamps
or of flat screen backlighting systems already
mentioned.
Finally, complete DC isolation between the primary-
circuit side and the secondary-circuit side can also be
achieved by the transformer if no such demagnetization
circuits which connect these two circuits are present.
This is highly desirable for safety reasons.
The invention furthermore relates to a concrete circuit
embodiment or circuit operating mode for the operating
method according to the invention, which has already
been generally described. In the case of this preferred
circuit embodiment, the secondary circuit is considered
as a resonant circuit after the voltage pulse has been
impressed - at the latest after the building-up of the
external voltage across the discharge lamp. In this
case, the charge connected with the external voltage
across the discharge lamp is allowed to drain away from
the discharge lamp in an electromagnetic oscillation
and the counterpolarization, until the back ignition,
is thus to an extent allowed time until the external
voltage has fallen to a sufficient extent. In this
case, the oscillation need not necessarily" be a fully
free oscillation, but it is essential for this concrete
circuit embodiment that external "triggering" of the
back ignition can be dispensed with.
To that end, a forward converter, in particular, is
suitable as ballast, in which the primary circuit
impresses the voltage pulse into the secondary circuit
with direct temporal coupling between a primary-circuit
current through the transformer and the corresponding
secondary-circuit induced current. In the case of the
forward converter, therefore, a corresponding primary-
side transformer current also flows at the instant of
voltage generation on the secondary-circuit side. The
building-up of the external voltage across the
discharge lamp takes place with a corresponding charge-
reversal time delay.
In this case, it is preferred for the secondary circuit
to be isolated as a resonant circuit after the
generation of the voltage pulse and after the ignition
in the discharge lamp, that is to say, in particular,
not to be greatly damped by a further induced current
flow on the primary-circuit side of the transformer.
For this purpose, a switch may be provided on the
primary-circuit side, which switch interrupts the
transformer current at a given instant and thus
isolates the secondary circuit as a resonant circuit.
If such a switch in the primary circuit for controllina
the primary-side current flow throuqh the transformer
is conceptually combined with its control, adapted to
the method according to the invention, to form a
switching device, then a ballast without a discharge
lamp connected thereto is already characterized by this
switching device according to the invention in the
primary, circuit of the forward converter. Thus, the
invention is not produced by joining together an
inherently conventional ballast with a corresponding
discharge lamp solely by a suitable choice of the
corresponding electrical quantities with an otherwise
conventional circuit construction. On the contrary, it
is embodied in the switching device according to the
invention, i.e. in a switch - suitably arranged in the
primary circuit - with a drive device which is
characteristic of the method according to the
invention.
The fact of whether a sufficiently complete draining of
the charge from the discharge lamp is possible in a
sufficiently short time in the case of the forward
converter ballast depends on the frequency of the
intended oscillation. According to the invention,
frequencies in the region of at least 100 kHz are
preferred here in order that a sufficiently rapid
draining of charge can be achieved. Frequencies of at
least 200 kHz or 300 kHz are particularly preferred.
However, it is not stipulated in the case of the
invention how to assess the time period between the
"forward ignition" and the back ignition in the sense
of the already cited foundation method of the pulsed
mode of operation. In principle, there are two
alternative possibilities. In one case, both associated
pulses are considered as a uniform active power
coupling-in, which are separated from one another by a
distinctly shorter period of time than the
corresponding dead times according to this method. To
that end, the oscillation frequency should lie above
the abovementioned values.
On the other hand, it is alternatively possible to
allow the secondary circuit to oscillate through very
slowly, which may be expedient in particular in the
case of very large lamp capacitances, that is to say
primarily in the case of very large lamps. The time
period between the first ignition and the back ignition
can then also be interpreted as a dead time, that is to
say typically lie in the range from 5 µs to 1 ms.
However, this requires the time delay with which the
internal counterpolarization in the discharge lamp
follows the reduction of the external voltage to be
sufficiently long. To that end, natural frequencies of
the secondary circuit of at most 33 kHz, better 15 or
10 kHz, are preferred.
In connection with the already mentioned possibility of
performing a feeding-back of energy from the secondary
circuit into the primary circuit via the transformer
itself, it is important to permit or to prevent the
primary-circuit-side current flow through the
transformer after the first ignition. If this current
flow is permitted by an on state of a corresponding
switch, an inductive coupling to the primary circuit
and thus a feeding-back of energy result in connection
with the back oscillation of the secondary circuit and
the associated draining of the charges from the
discharge lamp.
This feeding-back of energy does not, in principle,
obstruct the invention but reduces the energy available
for the back ignition in the secondary circuit. In the
sense of this invention, it is preferred for as much as
possible of the energy which remains in the secondary
circuit after the first ignition to be converted into'
light generation in the back ignition, so that the
primary-circuit-side current flow through the
transformer is preferably interrupted directly after
the first ignition. Thus, feeding back from the
secondary circuit into the primary circuit can be
correspondingly suppressed or reduced.
With regard to the concrete technical configuration of
the ballast, it has been found to be very favorable to
supply the primary circuit with power from a source
with a ceramic multilayer capacitor as storage
capacitor. Two essential advantages are associated with
this. Firstly, in the case of these capacitors, there
is a distinct reduction in back perturbations of high-
frequency interference from the ballast into the supply
network. The ceramic multilayer capacitors have, as it
were, a low-pass filter effect. Furthermore, such
capacitors have very low internal resistances and thus
allow a rapid build-up of corresponding supply currents
for the transformer in the primary circuit. Moreover,
they exhibit significantly longer services lives than
the electrolytic capacitors that are usually used.
As already mentioned several times, the entire ballast
and thus also the operation of the discharge lamp can
be clocked by a switch in the primary circuit and
correspondingly controlled current flow through the
primary-circuit side of the transformer. Such primary-
circuit clocking is a preferred choice in the case of
this invention. It must be noted, however, that other
possibilities for clocking the ballast and the
discharge lamp also lie within the scope of the
invention, for instance by means of a switching device
in the secondary circuit.
A further preferred refinement of the invention relates
to a secondary winding of the transformer having a
center tap, in the case of which safety improvements
and an improvement of the electromagnetic compatibility
can be achieved by choosing the center tap potential as
floating reference-ground potential in the secondary
circuit and supplying the discharge lamp by the
positive and negative voltages with respect to said
reference-ground potential at the external taps of the
secondary winding. This is essentially due to the fact
that in the secondary circuit, with regard to the high-
voltage danger and the electromagnetic radiation,
essentially half the voltage actually applied to the
discharge lamp occurs. Furthermore, the radiated
interference signals partly cancel one another out on
account of the edges in opposite directions.
Up to this point, mention has been made of a voltage
pulse which is impressed into the secondary circuit
from the primary circuit via the transformer and leads
to an external voltage across the discharge lamp. In
this case, the invention is not restricted in respect
of whether temporally successive external voltage
pulses across the discharge lamp always have the same
sign or perform a sign change in some way. In many
cases it is preferred to work with a unipolar operating
method, in which the external voltage across the
discharge lamp which is generated by a voltage pulse
always has the same sign. In this case, therefore, the
current direction of a "forward ignition" is always the
same. One advantage of this method is e.g. that, with
regard to the electrode structure of the discharge
lamp, a distinction can be made between cathodes and
anodes, only the anodes having to have a dielectric
layer for isolation from the discharge medium.
On the other hand, a bipolar operating method may
alternatively be preferred, in which the sign of the
external voltage across the discharge lamp changes
alternately from voltage pulse to voltage pulse.
However, it is then necessary to use discharge lamps in'
which all electrodes are suitable as anode, that is to
say have a dielectric layer.
One advantage of a bipolar operating method may, for
example, consist in a balancing of the discharge
conditions in the lamp, said balancing going still
further beyond the back ignition principle according to
the invention. Problems caused by asymmetrical
discharqe conditions are thus avoided particularly
effectively, e.g. instances of ion migration in the
dielectric which can lead to blackening, or space
charge accumulations which impair the efficiency of the
discharge.
With regard to the operating method according to the
invention, it is preferred, if bipolar operation is
intended, that, for this purpose, provision be made for
a direction reversal of the primary-circuit-side
current in the transformer, said current effecting the
voltage pulse in the secondary circuit. This is
generally simpler than taking corresponding electrical-
engineering measures for direction reversal on the
secondary-circuit side.
In particular, the transformer may have, for this
purpose, two primary-circuit-side windings which are
respectively assigned to one of the two current
directions, that is to say are used for a primary-
circuit current of only one of the two directions. This
means that current is alternately applied to the two
primary-circuit-side windings. By way of example, this
can be done by using two clocking switches in the
primary circuit which respectively clock the current
through an assigned winding of the two windings. As a
result, each of the two current directions is assigned
a dedicated clock switch and a dedicated primary-
circuit-side winding of the transformer.
If a ballast according to the invention is used on an
alternating-current source, it may be advantageous,
with regard to the two primary-circuit-side current
directions, to use two storage capacitors which are
alternately charged from the alternating-current source
in a half-cycle by half-cycle manner. In other words,
the alternating-current half-cycles of one sign are
used for one of the storage capacitors^ and the
alternating-current half-cycles of the other side are
used for the other storage capacitor. The currents for
a respective direction can then be drawn from these two
storage capacitors. This can be done together with the
depicted double embodiment of the primary-circuit
winding of the transformer, but this is actually not
necessary here. Instead, a single primary-circuit-side
winding can be supplied alternately by the two storage
capacitors by means of corresponding switches, each
storage capacitor being respectively assigned to a
current direction. In order to feed the storage
capacitors from the alternating-current source, it is
possible to use a corresponding rectifier circuit whose
details are clear to the person skilled in the art
without further elaboration.
Description of the drawings
The invention is explained in detail below using
concrete exemplary embodiments. The features disclosed
in the process may also be essential to the invention
in each case individually or in different combinations
from those represented. In the figures:
Figure 1 shows a schematic block diagram of an
illumination system according to the invention;
Figure 2 shows a schematic equivalent circuit diagram
for the discharge lamp from Figure 1;
Figure 3 shows a greatly simplified diagram for
illustrating the relationship between the external
voltage and the internal counterpolarization across and
in the discharge lamp;
Figure 4 shows a greatly simplified diagram for
illustrating the basic principle of the forward
converter ballast according to the invention;
Figure 5 shows exemplary measurement curves for an
actual operation of a forward converter ballast
according to the invention;
Figure 6 shows a diagram with further exemplary
measurement curves for the actual operation of the
forward converter ballast according to the invention;
Figure 7 shows a diagram with measurement curves for
the external voltage across and the current through the
discharge lamp in the case of a mode of operation which
differs in its particulars from Figures 5 and 6 but is
in accordance with the invention;
Figure 8 shows a schematic block diagram -
corresponding to Figure 1 - of a further illumination
system according to the invention; and
Figure 9 shows a diagram - corresponding to Figure 7 -
with measurement curves for the external voltage across
and the current through the discharge lamp in the case
of the illumination system according to Figure 8.
A schematic block diagram for an illumination system
according to the invention is represented in Figure 1,
in which, firstly, L represents a discharge lamp which
is designed for dielectrically impeded discharges. A
basic equivalent circuit diagram for the discharge lamp
L will be explained below with reference to Figure 2.
The actual construction of the discharge lamp L is not
crucial for understanding the operating method,
illumination system and ballast according to the
invention.
The discharge lamp L is connected into a secondary
circuit S containing, in addition to the discharge lamp
L, a secondary winding W2 of a transformer T.
The primary winding Wl of the transformer T is located
in a primary circuit P which is supplied with power
for the transformer and the discharge lamp L from a
power supply Q.
Furthermore, a fast switch TQ is located in one of the
branches between the power source Q and the primary
winding Wl. This switch is a power MOSFET which is
switched or controlled by a control device SE.
A storage capacitor CQ is connected in parallel witn
the series circuit comprising the primary winding Wl
and the switch TQ. This storage capacitor CQ is
recharged by the source Q, basically belongs to the
source Q and serves for the application of a voltage to
the primary winding Wl depending on the switching state
of the switch TQ. This involves ceramic multilayer
capacitors.
In the case of the forward converter, a current flow
through the primary winding Wl is generated initially
in a conventional manner, the turns ratio of the
transformer T being designed such that the current flow
through the primary winding Wl induces an ignition
voltage in the secondary winding W2 and thus indirectly
across the discharge lamp L. If the switch TQ is opened
by the control device SE, then energy at least in the
form of a residual magnetization of the transformer T
remains in the secondary circuit S.
As already explained in the introduction to the
description, demagnetization circuits have
conventionally been used to reduce said residual
magnetization, which might comprise e.g. a third
winding of the transformer T and a diode connected with
said winding in parallel with the series circuit
comprising the primary winding Wl and the switch TQ.
Using such a demagnetization circuit, the residual
magnetization of the transformer T could then be
reduced in the off phase of the switch TQ.
It is directly apparent from Figure 1 that there is
complete DC isolation between the primary circuit P and
the secondary circuit S. This is a considerable safety
advantage with regard to the high voltages present on
the secondary-circuit side. A further safety advantage
can be achieved by virtue of the fact that the
secondary winding W2 has a (third) center tap which can
serve as "floating" reference-ground potential of the
secondary circuit S. By contrast, if the positive and
negative pulses from the secondary winding W2 are
applied to the respective electrode groups of the
discharge lamp L, the full induced voltage is still
present across the discharge lamp L, although in each
case only half the maximum voltage occurs as safety-
relevant voltage in the secondary circuit relative to
the center tap potential.
This technology also considerably improves the
electromagnetic compatibility with regard to radiation
from the secondary circuit. Reference is made to
DE 197 34 885.8.
Before the invention's embodiment of the illumination
system illustrated in Figure 1 is described, the
electrical behavior of the discharge lamp L shall
firstly be considered in more detail with reference to
Figures 2 and 3. During the ignition operation already
described, the transformer T generates a voltage which
is present across the discharge lamp L and is
proportional to the time derivative of the primary-
circuit-side transformer current. In this case, the
illumination system is designed in such a way that the
current discharge interacting with the transformation
ratio of the transformer T generates, after the closing
of the switch TQ, a sufficiently high external voltage
across the discharge lamp L in order to allow the
latter to arc through.
Discharges in which charge carriers move to the
dielectric layer on the electrodes form in the
discharge medium of the discharge lamp L. In this
connection, gas discharge lamps which are preferably
considered are ones in whose gas space the electrons
are the far more mobile charge carriers and thus
practically solely determine the discharge dynamics
with respect to the ion cores. When the electrons have
moved to the dielectric layer on the anode, they
accumulate on the surface of the dielectric layer and
increasingly shield the electric field generated by the
external voltage.
In this connection, it should be noted that in the case
of the circuit variant illustrated in Figure 1, the
external voltage always has the same polarity, if an
anode is fixed in the discharge lamp L. As already
mentioned, however, this does not restrict the
invention to unipolar operating methods; rather, the
scope of the invention also includes bipolar methods
and illumination systems in which the polarity of the
external voltage alternates, that is to say the
electrodes are alternately operated in the anode role
and the cathode role. This will be explained with
reference to Figures 8 and 9.
To come back to the shielding, just described, of the
field generated by the external voltage, this is
effected with a time delay defined by various
parameters of the discharge lamp L (pressure and
composition of the discharge atmosphere, electrode
geometry, dimensions of the discharge volume ...) . This
shielding can then extinguish the discharge in the
discharge lamp L, even though the external voltage lies
above the required ignition voltage.
This can be discerned in the simplified diagram in
Figure 3, where the time t is plotted on the abscissa
and the voltage U is plotted on the ordinate. In this
case, the solid line shows the external voltage UL and
the broken line shows the internal voltage Ui which
results from the superposition of the external voltage
UL and the internal counterpolarization and corresponds
to the field actually prevailing in the discharge
medium.
In accordance with the previous description, the
external voltage UL, proceeding from the point a, has
risen rapidly toward negative values in the diagram in
Figure 3, while the internal voltage Ui, proceeding
from a, has increasingly decoupled from the external
voltage UL. The plasma ignites in the progression from
a to b. Even before the plasma ignition, there arises
an internal counterpolarization and thus a deviation of
the internal voltage Uj. from the external voltage UL. At
the point b, the internal voltage reverses in the time
derivative and, as a result of the increasing internal
counterpolarization, becomes smaller and smaller until
it reaches the value zero at c. In this example, the
internal voltage Ui reverses before the external
voltage UL reaches its maximum.
To afford a better understanding, the maximum of the
external voltage UL is depicted with a somewhat
exaggerated width. This is intended to illustrate that
field freedom prevails in the lamp and a discharge can
no longer be maintained while the external voltage UL
still has large values, possibly even the maximum
value.
In the equivalent circuit diagram from Figure 2, this
means that the discharge lamp L has changed over from a
load behavior as a time-dependent ohmic resistor R(t)
with the extinguishing of the discharge to a purely
capacitive behavior as_ a capacitor. This can be imaged
in the diagram in Figure 2 by a switching operation of
the model-like switch TL, which is to an extent
controlled by an ignition logic _ZL, of the discharge
lamp L. The capacitances Cl and C3 that are furthermore
depicted in the circuit diagram in Figure 2 are
capacitances of the electrodes and of the dielectric
layer applied at least on the anodes. In this case,
dielectric layers may also be present both on the
anodes and on the cathodes.
In the unignited or even no longer ignited state, the
discharge lamp L thus acts as a series circuit of
capacitors.
An essential aspect of the invention resides, then, in
coordinating the overall system (designated here as
illumination system) comprising the discharge lamp L
and the ballast in such a way that the time constant
which occurs with regard to the reaction of the
internal counterpolarization can be utilized for the
intended back ignition. This can be discerned in the
right-hand part in Figure 3, in which, as a result of
the drop in the external voltage UL, the internal
counterpolarization which is not decreasing in a
directly following manner then builds up an internal
voltage Ui which rises in the opposite direction, that
is to say toward positive voltages in Figure 3, to a
level above the ignition voltage limit. This is
manifested in the rise of the broken curve of the
internal voltage Ui between the points d and e.
After the drop in the external voltage UL, the internal
voltage, that is to say the internal
counterpolarization in this case of disappearing
external voltage UL, falls again from the point e to
the point f. In this case, the point where the external
voltage UL disappears need not necessarily coincide
with the maximum of the internal voltage Ui. All that
is essential is that the external voltage UL fall so
rapidly, and that the internal counterpolarization
react comparatively so slowly, that the ignition
voltage can be exceeded a further time in the opposite
direction.
In the equivalent circuit diagram for the discharge
lamp L as illustrated in Figure 2, the time profile
from d to f in Figure 3 signifies that the switch TL is
switched on again by the ignition logic ZL, but in this
case the time-dependent resistance R(t) assumes
formally negative values.
Figure 4 then illustrates how the illumination system
illustrated in Figure 1 achieves the fall in the
external voltage UL in the manner according to the
invention. The upper region of the figure illustrates
the control voltage Ust at the switch TQ in Figure 1,
that is to say the output signal Ust of the control
device SE, the high level of USt corresponding to a
closed state of the switch TQ.
As a result of the switch TQ being closed, the forward
converter generates an induced voltage in the secondary
winding W2 and thus an external voltage UL across the
discharge lamp L. This corresponds to the sharp rise in
the central curve in Figure 4 toward negative values.
At the same time, the lamp current IL, represented in
the lower curve, rises in the negative direction
analogously to the representation of the internal
voltage Ui in Figure 3. This first negative peak of the
lamp current IL after the instant ti corresponds to the
first ignition.
According to the invention, the switch TQ is opened by
the control device SE in the region of the negative
maximum of the lamp voltage UL or, as also illustrated
for the sake of better clarity in Figure 4, somewhat
thereafter, at the instant t2 in Figure 4. As a result,
a primary-circuit-side current flow through the primary
winding Wl of the transformer T is interrupted and the
secondary circuit S is isolated. The secondary circuit
S then behaves as a resonant circuit essentially
comprising the inductance of the secondary winding W2
of the transformer T and a total capacitance comprising
the capacitances CI, C2 and C3 - illustrated in
Figure 2 - of the discharge lamp L and a capacitance of
the secondary winding W2.
The profile of the lamp voltage UL which follows the
instant t2 in Figure 4 is intended to represent a
flowing-back - corresponding to this free oscillation
of the secondary circuit S - of the charge which is
capacitively coupled with the external voltage UL
across the discharge lamp L, from the discharge lamp.L
through the secondary winding W2. This fall in the
external voltage UL corresponds to the right-hand
region of the model-like representation in Figure 3.
Accordingly, as a result of the remaining internal
counterpolarization in the discharge lamp L, an
internal voltage Ui arises which leads to a back
ignition of the discharge lamp L in the opposite
direction. This is shown by the second, now positive,
peak of the lamp current IL in Figure 4. Note that
despite unipolar external active-power impressing, a
fundamentally bipolar active-power conversion occurs in
the discharge lamp L itself.
After the back ignition, the sequence schematically
represented in Figure 4 begins anew with a renewed
switch-on of the switch TQ by the control device SE. In
this case, the invention is preferably directed toward
the case where the time which elapses until a renewed
switch-on of the switch TQ, that is to say a renewed
"first ignition", corresponds to a dead time in the
sense of the pulsed mode of operation considered here.
By contrast, the time between the first ignition and
the back ignition should be as short as possible. The
two ignition pulses in Figure 4 should then be rated as
uniform active power coupling-in in the sense of the
pulsed mode of operation.
This can be seen more clearly from the actual
measurement curves in Figures 5 and 6, which illustrate
the control voltages Ust at the switch TQ, the external
lamp voltage UL, which is inverted in Figure 6 compared
with Figures 3, 4 and 5, the lamp current IL, and also
the primary-circuit-side transformer current Iw1. A time
unit in the diagrams in Figures 5 and 6, i.e. the
distance between the dotted lines, is 2 |j.s, and so the
entire region illustrated is 20 µs.
The basic principle from Figure 4 is again apparent in
the illustration in Figure 5, thus an attenuated
harmonic is superposed on the external lamp voltage UL
and the lamp current IL in the region between the first
ignition and the back ignition. This effect is
parasitic, does not qualitatively interfere with the
principle according to the invention, and will not be
explained any further here.
Moreover, the lamp voltage is not constant at zero in
the dead time between a back ignition and the next
first ignition, but rather exhibits a slight residual
oscillation of an amount of energy remaining in the
secondary circuit S, with a relatively low frequency.
Incidentally, this frequency deviates from the
frequency of the back oscillation of the external lamp
voltage UL in the region of the back ignition because
the (model-like) time-dependent resistance R(t) from
Figure 2 is practically infinite in the region of the
dead time, or that is to say the switch TL is totally
open in this time. By contrast, the discharge lamp L
has a conducting phase in the region of the back
ignition. Moreover, its capacitance C2(t) is also
different in each case.
The similarity of the temporal profiles of the lamp
current IL and of the internal voltage Ui shows that the
current through the lamp is driven by the internal
voltage or by the field strength actually prevailing
internally. Apart from the processes - not resolved in
these figures - of ignition and extinction of the
discharges themselves and the time variability of the
discharge resistance, the internal voltage and the lamp
current are thus in a direct relationship.
In Figure 6, there can be seen on the primary winding
current IW1, in addition to the main pulse "triggering"
the first ignition in the starting region of the
conducting phase of the switch TQ, that is to say the
high-level phase of the voltage Ust, a second, smaller
pulse toward the opposite side. This effect is
attributed to an energy feedback in the remaining time
phase of the closed state of the switch TQ after the
first ignition, to be precise conveyed from the
secondary circuit S via the transformer T into the
primary circuit P. This energy feedback corresponds to
a back induction by the charge already draining from
the discharge lamp L, as can be seen from the already
discernible fall in the signal UL. After the maximum of
the primary winding current IW1, its derivative
reverses, so that the induced voltage across the
primary winding W1 changes its polarity.
This effect does not, in principle, interfere with the
invention but should preferably not be excessively
pronounced. It is represented in Figure 6 basically
only to afford a better understanding.
Although the back oscillation of the external lamp
voltage UL initially corresponds to a largely free
oscillation of the isolated secondary circuit S, it is
then greatly attenuated by the back ignition. The
attenuation by the back ignition considerably reduces
the energy transported by the back oscillation to the
transformer T in the sense of magnetization of the
transformer T. This effect corresponds to the
demagnetization of the transformer T by the back
ignition in the sense of the invention. This
dissipative process distinctly reduces the energy
(including the remnants energy of the transformer core)
which is capacitively stored to an extent unavoidably
in the secondary circuit S in the discharge lamp L
during the first ignition, thereby obviating the need
for additional demagnetization circuits.
Figure 7 shows a further example - differing from
Figures 5 and 6 - of a possible time profile of the
external lamp voltage UL and of the lamp current IL
according to the invention. In order to be able to
represent a few periods of the operating method, time
intervals of 5 µs between the dotted lines have been
chosen in Figure 7. This example in Figure 7
illustrates two essential points. Firstly, a very much
smoother structure of the negative peak of the voltage
UL can be discerned. This means that in this case the
switch TQ was opened very much nearer the negative
maximum of the external lamp voltage UL, i.e. the
relatively wide shoulder in the voltage profiles UL in
Figures 4, 5 and 6 toward the back oscillation turns
out narrower. In principle, the switch TQ can even be
opened before the possible negative maximum of UL has
been reached.
Accordingly, the peaks of the respective first ignition
and back ignition in the lamp current IL lie closer
together and are separated from one another by no
discernible region of smaller currents. As a result,
this example illustrates that, in the case of the
invention, the active power coupling-in can in practice
be closely contracted despite, in principle, separate
forward and back ignitions, so that a uniform active
power pulse results from this in the sense of the
pulsed active power coupling-in.
Secondly, the strong sinusoidal fundamentals of the two
curves illustrated in Figure 7 are conspicuous, which
are phase-shifted by p/2 relative to one another. This
involves, in comparison with the residual oscillation
of the secondary circuit S already explained with
reference to Figure 5, a very much more pronounced,
largely active-power-free residual oscillation in the
secondary circuit S in which an amount of residual
energy which "is left behind" by the back ignition
oscillates between the discharge lamp L as capacitor
and the secondary winding W2 as inductance. Figure 7 is
intended to illustrate that such residual oscillations,
even though they are disadvantageous, do not interfere
with the basic principle of the invention for as long
as the associated amplitudes or edge steepnesses of the
external lamp voltage do not lead to undesirable
ignitions in the actual dead time.
Figure 8 shows a schematic circuit diagram which
largely corresponds to Figure 1. In this case, however,
an exemplary embodiment which is designed for a bipolar
operating method is shown. Thus, external voltage
pulses of alternating polarity are applied to the
discharge lamp L. To that end, the transformer T has
two primary windings depicted with opposite winding
senses in Figure 8. Each of the primary windings is
electrically connected in series with an assigned
switching transistor TQ with a dedicated control device
SE. Of course, the two control devices can also be
understood as two functions of a uniform control
device; all that is intended to be symbolized is that
the two primary windings are clocked alternately rather
than jointly. As a result of the winding sense reversal
between the two primary windings, the transformer T,
upon the clocking of the primary windings, in each case
generates voltage pulses of opposite polarity in the
secondary circuit S. For the rest, the function
corresponds entirely to the previous exemplary
embodiment illustrated in Figure 1. In summary, in the
case of the circuit from Figure 1, the assembly
comprising the primary winding W1, the switch TQ and
the control device SE is doubly embodied, a sign
inversion being effected by the winding sense.
Figure 9 shows corresponding real measurement curves of
the external lamp voltage UL and of the lamp current IL.
Great qualitative similarities with the curve profiles
in Figure 7 are apparent. However, it can be seen both
from the ignition pulses of the external lamp voltage
and from the lamp current pulses of forward ignition
and back ignition that a bipolar operating method is
involved. In contrast to the lamp current curve from
Figure 7, in this case the back ignition pulse is
formed with a somewhat higher amplitude than the
forward ignition pulse. However, there is no
fundamental relationship with the bipolar operating
method in this case.
In the manner illustrated, the invention utilizes the
specific properties of a discharge lamp L with
dielectically impeded electrodes in order to provide an
extremely simple electronic ballast which nevertheless
has outstanding operating properties. What is essential
in this case is the particular switching behavior of
the switch TQ on account of the control by the control
device SE. Furthermore, a significant part is played by
the suitable coordination of the electrical engineering
quantities and of the switching behavior with the
respective lamp parameters. Therefore, the invention
relates not only to the operating method but also to
the correspondingly coordinated illumination system and
also to a ballast provided with the control device
according to the invention.
In addition to the simple structure of the ballast, the
latter also has a quite considerably smaller structural
volume and smaller weight than the comparable prior art
because not only are fewer components used but also a
design for smaller power levels is possible, in
particular on the side of the primary circuit P.
In a construction example, the small structural size
led to a volume which can be accommodated in a housing
construction similar to a matchbox. This affords
considerable advantages with regard to installation
possibilities in flat screens, in which the discharge
lamps considered here are of major interest as
backlighting systems. An essential advantage of such
flat screens consists precisely in their small
structural size in comparison with conventional
electron beam tubes, but said small structural size
consequently also leaves only a small volume for
installing a backlighting system. In this case, the
flat radiators with dielectically impeded discharges
which can typically be made very flat can be used
highly advantageously in conjunction with the ballasts
according to the invention.
In addition to the possible application as an
illumination system for a flat screen, a further
example shall be presented here. In this respect,
reference is made to DE 197 18 395 CI, whose disclosure
content is incorporated here with regard to the
structures, the properties of the copying lamp
described therein, and also the application
possibilities thereof. The copying lamp represented in
principle therein was tested with the following
concrete data in the case of an illumination system
according to the invention. With a rod-type copying
lamp having a length of 30 cm and an external diameter
of 8 mm with a tube wall of 0.6 mm, a flashover
distance of 6.5 mm resulted for the dielectically
impeded discharges. The dielectric barriers each had a
thickness of approximately 170 |im and were composed of
glass solder on which, as on the remaining wall, TiO2
and luminescent material were deposited. The TiO2 is
recessed in the region of an aperture. With a filling
of 160 Torr xenon, an average lamp power of 11 W
resulted using a unipolar electronic ballast according
to the invention, having the following components:
three ceramic multilayer capacitors each of 10 µF were
used as storage capacitors CQ of the source Q supplied
with 12 V DC voltage. The switch TQ was an RFP 70 N 80
transistor. The transformer was a double EFD 15, N 87
with a four-chamber coil former and a turns ratio of
1:70. In the manner just described, work was carried
out with a center tap on the secondary side, which is
not illustrated in Figure 1 for the sake of simplicity.
A very lightweight and compact electronic ballast with
a volume of a matchbox was produced, which, moreover,
exhibited a very good electromagnetic compatibility
both with regard to radiation from the secondary
circuit and with regard to back perturbation into the
power supply system.
In the case of the copying lamp considered here, the
essential advantage is that the electronic ballast can
travel with the holding device for the copying lamp
itself during copying operation, that is to say can be
mounted directly beside the copying lamp. By virtue of
the considerably reduced lead lengths and by virtue of
the resultant immobility of the leads, significant
advantages are produced with regard to the safety,
durability and reliability of the high-voltage lines
between the electronic ballast and the copying lamp.
The lead capacitances are also reduced as a result, for
which reason the electronic ballast in conjunction with
the low capacitance of the copying lamp itself can
generate a very good pulse shape.
The obviation of the need to mount a moving high-
voltage line means that many conventionally necessary
components are also omitted and the assembly outlay
when producing a copier is thus considerably reduced.
Analogous advantages also apply to other applications
of such linear radiators in the context of document
illumination in fax machines, scanners, etc.
A further essential area of application for the
invention is in the field of the electrical supply of
flat radiators for dielectrically impeded discharges.
In this respect, reference is made to W098/43277. The
disclosure content of this application is incorporated
here by reference.
We claim :
1. Operating method for a discharge lamp (L) having a dielectric layer
between at least one electrode and a discharge medium
using a ballast having a power supplied primary circuit (P), a secondary
circuit (S) containing the discharge lamp (L), and also a transformer (T)
which connects the primary circuit (P) to the secondary circuit (S),
in which method a voltage pulse is impressed on the secondary circuit (S)
from the primary circuit (P) via the transformer (T), which voltage pulse
leads to an external voltage (UL) effecting an ignition across the discharge
lamp (L), and to an internal counterpolarization in the discharge lamp (L),
characterized in that, after the voltage pulse has been impressed, the
secondary circuit(S) performs an oscillation through which the charge is
withdrawn again from the discharge lamp (L), until the counterpolarization
leads to the back ignition, and the voltage pulse is impressed from the
primary circuit (P) into the secondary circuit (S) according to the forward
converter principle.
2. Operating method as claimed in Claim 1, wherein the transformer (T) of
the electronic ballast is demagnetized by the back ignition.
3. Operating method as claimed in Claim 1 or 2 wherein the secondary
circuit (S) is isolated as a resonant circuit after the ignition by the external
voltage (UL).
4. Operating method as claimed in one of the preceding claims, wherein the
frequency of the oscillation of the secondary circuit (S) is so high that the
ignition by the external voltage (UL) and the back ignition act as a uniform
active power puke of a pulsed active power coupling in method.
5. Operating method as claimed in one of the preceding claims, wherein the
frequency of the oscillation of the secondary circuit (S) is so low that the
period of time between the ignition by the external voltage (14) and the
back ignition acts as the dead time of a pulsed active power coupling-in
method.
6. Operating method as claimed in one of the preceding claims, wherein,
after the ignition by the external voltage (UL), the primary-circuit-side
current flow (IW1) through the transformer (T) is interrupted so early that
a feeding-back of energy from the secondary circuit (S) into the primary
circuit (P) essentially does not happen.
7. Operating method as claimed in one of the preceding claims, wherein the
primary circuit (P) is supplied with power from a source (Q) with a
ceramic multilayer capacitor (Cq) as storage capacitor.
8. Operating method as claimed in one of the preceding claims, wherein the
electronic ballast is clocked by a switch (TQ) in the primary circuit (P).
9. Operating method as claimed in one of the preceding claims, wherein, in
the secondary circuit (S), a center tap of the transformer (T) is used as
reference-earth potential.
10. Operating method as claimed in one of the preceding claims, wherein the
ballast is designed to apply to the discharge lamp (L) external voltage
(UL) having a sign which alternates from voltage pulse to voltage pulse.
11. Operating method as claimed in Claim 10, wherein the direction of the
primary-circuit-side current (IW1)in the transfbrmer(T) alternates from
voltage pulse to voltage pulse.
12. Operating method as claimed in Claim 11, wherein the transformer has
two primary-circuit-side windings (W1) which are respectively assigned to
one of the two current directions.
13. Operating method as claimed in Claims 8 and 11, wherein the primary
circuit has two switches (TQ), which respectively clock the current through
one of the two windings (W1).
14.Operating method as claimed in one of Claims 11 to 13, wherein the
primary circuit is euppliad from an alternating-currant courca which
alternately charges two storage capacitors in a half-cycle by half-cycle
manner, each storage capacitor respectively being assigned to one of the
two current directions.
15. Ballast for a discharge lamp (L) having a dielectric layer between at least
one electrode and a discharge medium,
having a power-supplied primary circuit (P), a secondary circuit (S) for the
discharge lamp(L) and also a transformer (T) which connect the primary
circuit (P) to the secondary circuit (S),
the ballast being a forward converter for impressing a voltage pulse from
the primary circuit (P) via the transformer (T) to the secondary circuit (S)
in order to produce at the discharge lamp (L) an external voltage
(UL)efrecting an ignition and an internal counterpolarization,
characterized in that the ballast has, in the primary circuit (P), a
switching device (TQ,SE) which is designed for interrupting, after the
ignition, the primary-side current flow (Iw1) through the transformer (T)
for the purpose of isolating the secondary circuit (S), in order to allow an
oscillation of the secondary circuit (S), in order to withdraw the charge
effecting the external voltage (Ul) across the discharge lamp (L) and to
lead to a back ignition by virtue of the internal counterpolarization in the
discharge lamp (L).
16.Ballast as claimed in Claim 15, wherein the primary circuit (P) is supplied
with power from a source (Q) with a ceramic multilayer capacitor (Cq) as
storage capacitor.
17.Ballast as claimed in Claim 15 or 16, wherein the transformer (T) has a
center tap in the secondary circuit side.
18. Ballast as claimed in one of the claims 15 to 17, designed for a method as
claimed in one of Claims 1-14.
19.Illumination system having a discharge lamp (L) having a dielectric layer
between at least one electrode and a discharge medium and ballast as
claimed in one of Claims 15 to 18.
20.Illumination system as claimed in Claim 19, designed to the effect that the
transformer (T) of the ballast is demagnetized by the back ignition.
21.Illumination system as claimed in Claim 19 or 20, wherein the natural
frequency of the secondary circuit (S) is at least 100 kHz.
22.Illumination system as claimed In Claim 19 or 20, wherein the natural
frequency of the secondary circuit (S) is at most 33 kHz.

Documents:

in-pct-2001-235-kol-abstract.pdf

in-pct-2001-235-kol-claims.pdf

in-pct-2001-235-kol-correspondence.pdf

in-pct-2001-235-kol-description (complete).pdf

in-pct-2001-235-kol-drawings.pdf

in-pct-2001-235-kol-examination report.pdf

in-pct-2001-235-kol-form 1.pdf

in-pct-2001-235-kol-form 18.pdf

in-pct-2001-235-kol-form 2.pdf

in-pct-2001-235-kol-form 3.pdf

in-pct-2001-235-kol-form 5.pdf

in-pct-2001-235-kol-gpa.pdf

in-pct-2001-235-kol-granted-abstract.pdf

in-pct-2001-235-kol-granted-claims.pdf

in-pct-2001-235-kol-granted-description (complete).pdf

in-pct-2001-235-kol-granted-drawings.pdf

in-pct-2001-235-kol-granted-form 1.pdf

in-pct-2001-235-kol-granted-form 2.pdf

in-pct-2001-235-kol-granted-specification.pdf

in-pct-2001-235-kol-petition under rule 137.pdf

in-pct-2001-235-kol-petition under rule 138.pdf

in-pct-2001-235-kol-priority document.pdf

in-pct-2001-235-kol-reply to examination report.pdf

in-pct-2001-235-kol-specification.pdf

in-pct-2001-235-kol-translated copy of priority document.pdf


Patent Number 247352
Indian Patent Application Number IN/PCT/2001/235/KOL
PG Journal Number 13/2011
Publication Date 01-Apr-2011
Grant Date 31-Mar-2011
Date of Filing 28-Feb-2001
Name of Patentee PATENT-TREUHAND- GESELLSCHAFT FUR ELEKTRISCHE GLUHLAMPEN MBH
Applicant Address HELLABRUNNER, STRASSE 1, D-81543, MUNCHEN
Inventors:
# Inventor's Name Inventor's Address
1 HITZSCHKE LOTHAR THEODOR-ALT-STRASSE 6, D-81737 MUNCHEN
2 WAMMES KLAUS BACHSTRASSE 34, D-67577 ALSHEIM
3 VOLLKOMMER FRANK NEURIEDERSTRASSE 18, D-82131 BUCHENDORF
PCT International Classification Number H05B 41/28
PCT International Application Number PCT/DE1999/02680
PCT International Filing date 1999-08-26
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 19839329.6 1998-08-28 Germany