Information
-
Patent Grant
-
6741043
-
Patent Number
6,741,043
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Date Filed
Monday, September 30, 200222 years ago
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Date Issued
Tuesday, May 25, 200420 years ago
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Inventors
-
Original Assignees
-
Examiners
Agents
-
CPC
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US Classifications
Field of Search
US
- 315 224
- 315 225
- 315 291
- 315 307
- 315 219
- 315 312
- 315 318
- 315 324
- 315 209 R
- 315 308
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International Classifications
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Abstract
A ballast (100) having an inverter (110,120,122) and a direct current blocking capacitor (130) coupled in series with a ballast output (108) includes a control circuit (140) for providing adaptive end-of-lamp-life protection. During operation, control circuit executes the steps of measuring (208) and storing (210) a reference value for the voltage across the DC blocking capacitor (130), monitoring (308,310) the voltage across the DC blocking capacitor (130), and protecting (312) the inverter and lamp sockets in response to the voltage across the DC blocking capacitor departing from the reference value by more than a predetermined threshold amount.
Description
FIELD OF THE INVENTION
The present invention relates to the general subject of circuits for powering discharge lamps. More particularly, the present invention relates to a ballast with adaptive end-of-lamp-life protection.
BACKGROUND OF THE INVENTION
In electronic ballasts with a half-bridge type inverter and a direct-coupled output, it is common for a direct current (DC) blocking capacitor to be coupled in series with the lamp. During normal operation of the lamp, the voltage across the DC blocking capacitor (V
BLOCK
) is equal to approximately one-half of the DC rail voltage (V
DC
) that is supplied to the inverter. As the lamp approaches the end of its normal operating life, V
BLOCK
will tend to depart from its normal value of about V
DC
/2. Thus, a number of existing end-of-lamp-life protection circuits monitor V
BLOCK
as a reliable indicator of imminent lamp failure. A number of these circuits consider a lamp to be in a failure mode when V
BLOCK
departs from its normal value by more than a predetermined threshold amount.
In order to adequately protect the ballast from damage and avoid any possible overheating of the lamp sockets (the latter being a primary concern with small diameter lamps, such as T5 lamps), it is highly desirable that the predetermined threshold amount be suitably small in relation to the normal value of V
BLOCK
. As an example, in a ballast with V
DC
=450 volts, the normal value of V
BLOCK
is about V
DC
/2=225 volts. A typical protection circuit will consider the lamp to be in the failure mode if V
BLOCK
departs from its normal value of 225 volts by as little as 10 volts (i.e., 4%) in either direction; that is, the lamp is considered to be in the failure mode if V
BLOCK
either exceeds 235 volts or falls below 215 volts. In existing protection circuits, these minimum (i.e., 215 volts) and maximum (i.e., 235 volts) values are “designed in”; that is, they are specified on an a priori basis, regardless of the actual value of V
BLOCK
during normal operation.
The problem with setting such a tight band of detection (e.g., ±4%) on an a priori basis is that the tolerances of certain components in the ballast render such an approach unreliable at best. First, V
BLOCK
is generally monitored via a resistive voltage-divider network that is coupled in parallel with the DC blocking capacitor. The tolerances of the voltage-divider resistors are a first source of possible error. Secondly, the protection circuit itself generally includes a digital control circuit or microcontroller in which the supply voltage (V
CC
) can vary by as much as 5%. This introduces another possible source of detection error. Additionally, small differences in the dead-time and/or duty cycle at which the inverter switches are driven will cause V
BLOCK
to differ at least somewhat from its ideal normal value of V
DC
/2. Also, V
DC
itself has an associated tolerance (e.g., typically on the order of about 2% or so). Finally, each of the aforementioned sources of possible error is temperature-dependent to some extent, and may thus be aggravated by the often considerable changes in temperature that occur during operation of the ballast.
In order to avoid the detection problems arising from component tolerances, one would have to set a band of detection that is considerably less tight than in the above example. For instance, the band of detection would have to be increased to ±20 volts (rather than ±10 volts). Unfortunately, such “opening up” of the band of detection degrades the quality of protection afforded by the protection circuit, and may not even be an option for ballasts that operate certain types of lamps.
What is needed, therefore, is a ballast with an end-of-lamp-life protection circuit that is capable of providing a tight band of detection and that is relatively insensitive to component tolerances and other sources of detection error. Such a ballast would represent a considerable advance over the prior art.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
describes a ballast with an end-of-lamp-life protection circuit, in accordance with a preferred embodiment of the present invention.
FIG. 2
is a flowchart describing the operation of the control circuit in the ballast described in
FIG. 1
, in accordance with a preferred embodiment of the present invention.
FIG. 3
is a flowchart further describing the operation of the control circuit in the ballast described in
FIG. 1
, in accordance with a preferred embodiment of the present invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
A ballast
100
for powering at least one gas discharge lamp
10
is described in FIG.
1
. Ballast
100
comprises a pair of input connections
102
,
104
, first and second output connection
106
,
108
, an inverter
110
,
120
,
122
with a series-resonant output circuit
124
,
126
, a direct current (DC) blocking capacitor
130
, and a control circuit
140
.
Input connections
102
,
104
are adapted to receive a source of alternating current, such as 277 volts (rms) at 60 hertz. Output connections
106
,
108
are adapted for connection to gas discharge lamp
10
. Direct current (DC) blocking capacitor
130
is coupled between second output connection
108
and circuit ground
30
.
Inverter
110
,
120
,
122
is operably coupled between input connections
102
,
104
and first output connection
106
, and includes an inverter drive circuit
110
for providing switching of inverter transistors
120
,
122
at a predetermined operating frequency. Inverter drive circuit
110
has a supply input
114
for receiving operating power (+V
CC
), and a protection input
112
. In response to application of a fault signal at protection input
112
, inverter drive circuit
110
takes protective action (e.g., terminating inverter switching or operating the inverter at a frequency that is substantially higher than the predetermined operating frequency) so as to prevent any damage to the inverter and the lamp sockets.
Control circuit
140
has a supply input
146
for receiving operating power (+VCC), a control input
142
that is operably coupled to DC blocking capacitor
130
, and a control output
144
that is coupled to the protection input
112
of inverter drive circuit
110
. Control circuit
140
is preferably implemented via a suitable programmable microcontroller that is programmed to operate in the following manner. Following initial application of power to ballast
100
, control circuit
140
measures the voltage across DC blocking capacitor
130
and stores that voltage as a reference value. Following each subsequent application of power to ballast
100
, control circuit
140
monitors the voltage across DC blocking capacitor
130
. If the measured voltage across DC blocking capacitor
130
departs from the stored reference value by more than a predetermined threshold amount (e.g., 10 volts), control circuit
140
provides the fault signal at control output
144
(and, therefore, at protection input
112
).
Because the actual voltage across DC blocking capacitor
130
is a rather high value (e.g., 225 volts), it is impractical to monitor or measure that voltage directly. Toward this end, ballast
100
further includes a resistive voltage-divider network comprising a first resistor
132
and a second resistor
134
. First resistor
132
is coupled between second output connection
108
and control input
142
of control circuit
140
. Second resistor
134
is coupled between control input
142
and circuit ground
30
. The voltage across second resistor
134
(e.g., 2.25 volts or so under normal operation) is a scaled down version of the voltage across DC blocking capacitor
130
. During operation, the voltage V
SENSE
across second resistor
134
is monitored and measured in lieu of the actual voltage across DC blocking capacitor
130
. Of course, the predetermined threshold amount is scaled down by the same factor (i.e., 0.1 volts instead of 10 volts). As an example, if the actual voltage across DC blocking capacitor
130
is normally 225 volts, resistors
132
,
134
can be selected such that the corresponding voltage V
SENSE
across resistor
134
is 2.25 volts. Correspondingly, if the allowable variation in the voltage across DC blocking capacitor
130
is ±10 volts, then V
THRESH
should be set at 0.1 volts.
Preferably, the reference value is measured and stored with a resistive load (e.g., 800 ohms) coupled between output connections
106
,
108
. This has the advantage of ensuring that the reference value is devoid of any asymmetry attributable to the load, and can be performed as part of the functional testing process during manufacture of the ballast. While it is possible to measure the reference value with an actual lamp (i.e., a lamp that is known to be good) coupled between output connections
106
,
108
, this is not preferred because there is usually no guarantee that the lamp will not be in an end-of-life condition at that time.
Because the reference value is determined by an actual measurement rather than on an a priori basis, ballast
100
and control circuit
140
provide an adaptive scheme that allows for a tight band of fault detection that is devoid of any errors due to component tolerances.
Flowcharts that describe the preferred operation of ballast
100
and control circuit
140
are given in
FIGS. 2 and 3
.
FIG. 2
describes a preferred routine
200
by which the reference value V
REF
of the voltage across DC blocking capacitor
130
is measured and stored. At step
202
, the ballast output is connected to a resistive load. At step
202
, AC power is applied to the ballast. After waiting for a first predetermined period of time t
1
(step
206
) in order to allow the ballast to achieve stable operation, the voltage V
SENSE
across the lower divider resistor (i.e., resistor
134
in
FIG. 1
) is measured. At step
210
, the reference voltage V
REF
is set equal to the measured value of V
SENSE
, and stored accordingly.
FIG. 3
describes a preferred routine
300
by which the voltage across DC blocking capacitor
130
is monitored for an end-of-lamp-life condition. At step
302
, the ballast output is connected to a lamp load. At step
302
, AC power is applied to the ballast. After waiting for a second predetermined period of time t
2
(step
306
) in order to allow the ballast to ignite the lamp and achieve stable operation, the voltage V
SENSE
across the lower divider resistor (i.e., resistor
134
in
FIG. 1
) is measured. At step
310
, the measured value of V
SENSE
is compared with V
REF
and the predetermined threshold voltage V
THRESH
. As long as V
SENSE
is within the limits assigned for normal operation, no protective action will be taken and V
SENSE
will continue to be monitored. If, on the other hand, V
SENSE
either exceeds V
REF
+V
THRESH
or falls below V
REF
−V
THRESH
, then appropriate protective action that consists of either shutting down the inverter or shifting the inverter to a low power mode (i.e., operating the inverter at a frequency that is substantially higher than the normal operating frequency) will be taken at step
312
.
Although the present invention has been described with reference to certain preferred embodiments, numerous modifications and variations can be made by those skilled in the art without departing from the novel spirit and scope of this invention. For example, the principles of the present invention are equally applicable to those ballasts wherein the DC blocking capacitor is not necessarily ground-referenced as in
FIG. 1
(e.g., ballasts in which the DC blocking capacitor is coupled between resonant inductor
124
and first output connection
106
).
Claims
- 1. A ballast for powering at least one gas discharge lamp, comprising:a pair of input connections adapted to receive a source of alternating current; first and second output connections adapted for connection to the gas discharge lamp; an inverter operably coupled between the input connections and the first output connection, the inverter including an inverter drive circuit for providing inverter switching at a predetermined operating frequency, the inverter drive circuit having a protection input and being operable, in response to application of a fault signal at the protection input, to take protective action; a direct current (DC) blocking capacitor coupled between the second output connection and circuit ground; a control circuit having a control input operably coupled to the DC blocking capacitor, and a control output coupled to the protection input of the inverter drive circuit, wherein the control circuit is operable: (i) following initial application of power to the ballast, to measure the voltage across The DC blocking capacitor and to store that voltage as a reference value; and (ii) following each subsequent application of power to the ballast: (a) to monitor the voltage across the DC blocking capacitor; and (b) in response to the voltage across the DC blocking capacitor departing from the reference value by more than a predetermined threshold amount, to provide the fault signal at the control output.
- 2. The ballast of claim 1, further comprising:a first resistor coupled between the second output connection and the control input of the control circuit; and a second resistor coupled between the control input of the control circuit and circuit ground.
- 3. The ballast of claim 2, wherein the voltage across the second resistor is monitored and measured in lieu of the voltage across the DC blocking capacitor.
- 4. The ballast of claim 1, wherein the predetermined threshold amount is on the order of about ten volts.
- 5. The ballast of claim 1, wherein the reference value is measured with a resistive load coupled between the first and second output connections.
- 6. The ballast of claim 1, when the inverter drive circuit is operable to protective action that includes one of:terminating inverter switching; and operating the inverter at a frequency that is substantially higher than the predetermined operating frequency.
US Referenced Citations (3)
Number |
Name |
Date |
Kind |
5869935 |
Sodhi |
Feb 1999 |
A |
6362575 |
Chang et al. |
Mar 2002 |
B1 |
6366032 |
Allison et al. |
Apr 2002 |
B1 |