WO2006114175A2 - Parameterizable digital pfc (power factor correlation) - Google Patents

Abstract

A dimmable electronic ballast for at least one gas discharge lamp, particularly a fluorescent lamp, comprises a power factor correction (PFC), which is supplied with an input voltage, is controlled by a DC link voltage controller, and which serves to create a controlled DC link voltage, and comprises an inverter, which is supplied with the DC link voltage and which supplies the lamp. Dimming values for presetting a set lamp output are fed to the ballast. The DC link voltage controller has different properties at different applied dimming values.

Description

 Parameterizable digital PFC

The present invention relates to control gear for lamps, in particular to an electronic ballast for at least one gas discharge lamp, in particular a fluorescent lamp.

The input from the prior art known electronic ballasts usually forms a connected to a power supply

High frequency filter which is connected to a rectifier circuit. The supply voltage directed by the rectifier circuit is supplied to a smoothing circuit for generating an intermediate circuit voltage (bus voltage). An inverter fed with the intermediate circuit voltage finally generates a high-frequency alternating voltage, which is applied to the load circuit with the gas discharge lamp arranged therein. The operation with the high-frequency AC voltage, among other things, an increase in the luminous efficiency of the lamp result. By changing the operating frequency is also given the opportunity to operate the lamp in different levels of brightness (dimming).

The invention relates in particular to electronic ballasts with a smoothing circuit (English: Power Factor Correction, PFC), which the the Inverter supplied DC link voltage

(Bus voltage). Usually, the

DC link voltage regulated to a predetermined setpoint, which is done by a arranged within the smoothing circuit control circuit. This compares the current value of the intermediate circuit voltage as an actual value with an internally specified value and accordingly controls the energy consumption of the ballast and thus the value of the intermediate circuit voltage. A control of the energy consumption is usually carried out with the aid of a controllable switching element.

However, the switching operations of this smoothing circuit switching element can result in harmonics which "re-radiate" into the connected power supply, which means that the voltage and current at the input of the ballast diverge in phase and distortion occurs which results in the generation of harmonics generated by the ballast However, since the harmonics in the network can have a disruptive effect, standards usually require that during normal operation of the gas discharge lamp the harmonics generated by an electronic ballast only "re-radiate" below a certain level into the network. The smoothing circuit should therefore be designed so that a divergence of the voltage and the current in terms of their phase is avoided as possible.

From EP 1189490 Al a generic electronic ballast is known. In this known electronic ballast, the DC link voltage controller in different operating phases (preheat, ignition, normal operation) of Lamp different dynamic control characteristics. This is to ensure that the smoothing circuit in the various phases of operation of the lamp in each case for the corresponding operating phase has optimal properties.

The starting point of EP 1189490 A1 is accordingly an electronic ballast which is operated with constant supply voltage and constant power. So there is a non-dimmable electronic ballast.

The present invention has now set itself the task of extending the flexibility of the smoothing circuit (PFC) such that it is particularly fair in terms of requirements for a dimmable electronic ballast.

This object is achieved by the features in the independent claims. The dependent claims further form the central idea of the invention in a particularly advantageous manner.

According to a first aspect of the present invention, therefore, an electronic ballast is provided for at least one gas discharge lamp, in particular a fluorescent lamp. The ballast is supplied with an input voltage and has a smoothing circuit controlled by an intermediate circuit voltage regulator for generating a regulated DC link voltage and an inverter stored with the DC link voltage. At least one lamp can be connected to the inverter. In contrast to EP 1 189 490 A1, it is provided that the ballast external commands such as dimming, can be supplied. The DC link controller has properties that depend on the applied commands. In contrast to EP 1 189 490 A1, the properties of the DC link regulator are also possibly changed within the same operating state (preheating, ignition, normal operation), in particular when an external dimming value specification changes.

The external commands are to be distinguished in this respect from the "internal" operating states, which according to EP 1 189 490 A1 cause different characteristics of the smoothing circuit.

For this purpose, a controller can be assigned to the DC link controller, to which the external commands can be supplied and which transmits to the DC link controller dependent setpoints with respect to the dynamic characteristics or other properties of the DC link regulation.

Examples of these setpoints are, for example, values with regard to the DC link voltage, the time constants of the DC link controller and the permissible harmonics (THD).

A bidirectional communication can take place between the controller and the DC link controller in which the DC link controller transmits to the controller operating parameters of the smoothing circuit. These operating parameters can be, for example, the type and / or the level of the applied input voltage and / or the intermediate circuit voltage. The controller can be software controlled.

The controller may be connected to a memory in which a look-up table (LUT) is stored, the defined external commands, for example

Dimming values, corresponding setpoints for the

Assigns smoothing circuit. Alternatively, the controller can also determine the setpoint values for the DC link control, depending on the external commands, via implemented functions.

In addition or as an alternative to the dependence on the externally supplied commands, the characteristics of the DC link regulator may also be adjustable depending on the type and / or the level of the input voltage of the electronic ballast.

According to a further aspect of the present invention, an electronic ballast (EVG) is provided, in which the DC link controller receives set values for the operation of the smoothing circuit from a software-controlled controller. The addition of the software-controlled controller thus allows a much more flexible design of the electronic ballast in comparison to the prior art, which brings advantages in particular with dimmable but also with non-dimmable ballasts.

Finally, the invention also relates to an electronic ballast for at least one gas discharge lamp, in particular a fluorescent lamp, with one supplied with an input voltage and controlled by an intermediate circuit voltage regulator

Smoothing circuit (PFC) for generating a regulated DC DC bus voltage as well as one with the DC

DC link powered inverter, at the

Output is connected to a load circuit in which at least one lamp can be used, wherein - the intermediate circuit voltage controller directly or indirectly detects the output power of the load circuit, and the intermediate circuit voltage controller has properties that depend on the output power of the load circuit.

The invention further relates to lamps with such ballasts, to methods for operating an electronic ballast and a computer software program product to support such methods.

Finally, the invention also expressly relates to a microcontroller, as it can be used in such methods or ballasts.

Further features, advantages and features of the present invention will now be explained in more detail with reference to the single figure of the attached drawings and to a detailed embodiment in which:

1 shows a schematic representation of an electronic ballast for a fluorescent lamp with a digital DC link voltage controller.

In the schematic representation of the electronic ballast according to the invention shown in Fig. 1 was on the representation of the rectifier circuit, which is usually formed by a full-bridge rectifier omitted. The rectified mains voltage is supplied to the smoothing circuit, which is formed in the illustrated example by a boost converter, which consists of an inductor Ll, a diode Dl, a storage capacitor Cl and controlled by the DC link voltage regulator 1 switching elements in the form of a field effect transistor Sl. The intermediate circuit voltage V ₂ provided by the smoothing circuit is supplied to a load circuit 2 containing the inverter 7 and the load circuit 8 with the gas discharge lamp LA arranged therein, which can be a fluorescent lamp.

The operation of a boost converter is already known in principle and will therefore be summarized in the following only briefly. If the field effect transistor Sl is conductive, the current in the inductance Ll increases linearly. If, on the other hand, the field-effect transistor S1 is blocked, the current discharges into the storage capacitor C1, so that a DC voltage V _z consisting of a DC voltage with ripple ("modulation") is formed thereon It is also possible to influence the DC link voltage V ₂ applied to the storage capacitor C. It is possible to vary the power consumption by changing the switch-on time or the duty cycle T ₀ N of the switch S1. In the following, the intermediate circuit voltage controller 1, which is designed as a digital controller in the example shown, will now be explained in more detail. The current value of the intermediate circuit voltage V _z is first detected via the input line 9. As an alternative to this direct detection, however, the intermediate circuit voltage V _{z could} also be detected indirectly, for example via the input voltage. For digital further processing, this analog value of the intermediate circuit voltage Vz is converted by an analog-to-digital converter 2 into a digital value u (k). The conversion takes place in each clock cycle of the intermediate circuit voltage regulator 1, wherein the clock is predetermined by a central clock in the form of a fixed-frequency oscillator 3. In addition to the analog-to-digital converter 4, the clock signals of the clock generator 3 are also fed to a computer unit 5, which forms the core of the digital intermediate circuit voltage regulator 1, and to a control block 6 for driving the field-effect transistor Sl.

The arithmetic unit 5 serves to calculate a control value y (k) in each clock cycle, which is transmitted to the control block 6. This sets the control value y (k) in a signal for operating the field effect transistor Sl and thus controls its on-time. The switching of the field effect transistor Sl takes place at a time at which no current flows through the diode Dl, as a result, the switching losses are reduced. For this purpose, a detection winding L2, which is inductively coupled to the inductance Ll of the boost converter. Locks the field effect transistor Sl, the current through the inductance Ll drops continuously until it reaches the zero point at a certain time. This Time is detected by means of the detection coil L2 of the control block L6 and the field effect transistor Sl switched through while avoiding switching losses again. The control value y (k) specifies how long the field effect transistor S1 is turned on. By the duration of the power consumption of the ballast and thus the amount of the provided intermediate circuit voltage V _{z is} determined. However, it is also possible, instead of the switch-on time of the switch Sl, to change its duty cycle as a function of the current control value y (k).

The calculation of the control value y (k) takes place not only on the basis of the current actual value u (k) of the intermediate circuit voltage V _z , but also on the basis of the actual values and the control values in the previous clock cycles. Due to the digital properties, the control value y (k) is calculated according to a specific function, ideally after an infinite series. This infinite series consists of series members, which however in the present example are aborted after the third term in order to keep the effort for calculating the control value within an acceptable range. This means that the current control value y (k) is calculated, for example, using the following equation:

y (k) = al * y (k-l) + a2 * y (k-2) + bl * u (k) + b2 * u (k-l) + b3 * u (k-2)

Here, y (kl) and y (k-2) denote the values of the control value in the previous and pre-previous clock cycles, respectively, while the values u (kl) and u (k-2) denote the actual values in the previous and previous clock cycles, respectively , These individual values are weighted with the parameters al, a2 and bl to b3. As can be seen from the above equation, the parameters used to weight the individual row members determine the dynamic behavior of the DC link voltage regulator 1. Accordingly, by using different parameter sets for the control block 6 in calculating the control value y (k), the DC link voltage regulator 1 adapted to different requirements.

For this purpose, the arithmetic unit 5 of the DC link regulator 1 is assigned an integrated controller 10, which communicates bidirectionally with the arithmetic unit 5 of the intermediate-time regulator 1 (see reference numeral 11).

The controller 10 is connected to a memory 12. Via a digital interface 13, the controller 10 can receive digital commands, such as dimming value specifications, but also, for example, send status messages or error messages to a connected digital bus, for example with the DALI standard.

The DC link controller 1, the controller 10 with the interface 13 and the memory 12 may be embodied for example as an ASIC.

The software-controlled controller 10 thus receives externally supplied digital commands via the interface 13. Furthermore, the arithmetic unit 5 of the DC link regulator 1 can report back status information or operating parameters to it. Typical examples of this feedback from the arithmetic unit 5 of the DC link regulator to the controller 10 are the type and / or level of the applied input voltage and the current value of the DC link voltage V _z .

Depending on this incoming information (external commands, or feedback from the DC link controller,

Output power of the at least one lamp having load circuit) can now the controller 10 of the arithmetic unit 5 of the DC link controller 1 to transmit setpoints for the operation. These setpoints can, for example, affect the following parameters:

Bus voltage setpoint dependent on the input voltage,

- Dynamic characteristics of the DC link regulator:

The controller coefficients must be changed for small dimming values to adapt to the dynamics and stability requirements of the control.

- To improve the harmonics behavior

(THD), the T _0N ~ values for the switch can be preset and optimized from the table. The modulation of the T _0N values of the switch should be reduced for smaller input voltages.

Thus, according to the invention, the DC link controller 1 is set via software depending on externally supplied commands, such as dimming values or feedback from DC link controllers. Furthermore, the DC link regulator can be set to the output power of the load circuit containing the lamp. The external default value is in this case, for example, a signal from a controller for the power of the output circuit.

This setting is particularly important for dimmable electronic ballasts, which may experience static load changes due to variable lamp power compared to non-dimmable electronic ballasts. Thus, it must be possible for properties of the smoothing circuit to be changed even in an operating phase, in particular during operation of the lamp in the ignited state.

The maximum amplitude as well as the nature of the power supply (AC, DC) can be measured according to the invention either directly (for example via the voltage divider and an AD converter). Alternatively, they can be detected indirectly using the following mathematical function:

V _1n = V _z x T _of f / T _0n + T _off

T _Off is the switch-off _duration of switch S1 and T _{0n is} the switch-on time of this switch.

The assignment of the specifications for the DC link control by the controller 10, as shown in the figure, via a look-up table, which is stored in the memory 12 and the incoming commands via the digital interface are ready or Feedback from the DC link control the corresponding specifications for the DC link control assigns. Alternatively or additionally, however, the controller 10 may also determine these specifications via implemented functions.

The following scenarios should be mentioned as examples of the different requirements for the DC link control depending on the type and / or the input voltage:

- By recording the maximum value of the applied AC voltage can be decided on a specific geographical area (for example, Europe or USA). In turn, this indirect coverage of the geographic scope can be used to determine acceptable THD limits. Accordingly, then the specifications for the DC link control can be made such that the prevailing in the corresponding geographical area standards are met.

- The bus voltage setpoint specification can be adjusted depending on the height of the detected AC voltage, in principle, the rule applies that the bus voltage is set the higher, the higher the maximum amplitude of the applied AC voltage.

- When applying an AC supply voltage, an operation of the _{DC link} control can be specified, in which the ON time T _{0n of} the switch Sl is constant. In contrast, when applying a DC voltage may be provided that the _Switching time T _{0n of} the switch Sl is periodically changed ("Sweep Mode ,,).

Claims

Claims: 1. Electronic ballast for at least one gas discharge lamp, in particular a fluorescent lamp, with a supplied with an input voltage and controlled by a DC link voltage regulator smoothing circuit (PFC) for generating a regulated DC link voltage and a DC DC link voltage supplied inverter, at its output Load circuit is connected, in which at least one lamp can be used, wherein - the ballast external commands are supplied, and - the DC link controller has properties that depend on the applied commands. 2. Ballast according to claim 1, characterized in that it is a dimmable ballast, the external dimming values can be fed. 3. Ballast according to claim 1 or 2, wherein the DC link controller is associated with a controller to which the external commands can be fed and the DC link controller of the currently applied commands related setpoints. of dynamic properties. 4. Ballast according to claim 2, wherein the controller with respect to the DC link controller setpoints. transmitted to at least one of the DC link voltage, time constants of the DC link and permissible harmonics (THD). 5. Ballast according to one of claims 2 or 3, wherein the DC link controller transmits the controller operating parameters of the smoothing circuit (PFC). 6. Ballast according to claim 4, wherein the DC link controller the controller information regarding the type of applied input voltage, the level of the adjacent Input voltage and / or the DC link voltage transmitted. 7. Ballast according to one of claims 2 to 4, wherein the controller is software-controlled. 8. Ballast according to one of claims 2 to 6, wherein the controller is connected to a memory in which a comparison table is stored, the defined external commands assigning set values for the smoothing circuit. 9. Ballast according to one of the preceding Claims in which the intermediate circuit regulator is designed as a logic circuit. 10. Ballast according to one of the preceding claims, in which properties of the DC link controller are adjustable depending on the input voltage. 11. Ballast according to one of the preceding claims, wherein the external commands with respect to information. the output power of the load circuit are. 12. Electronic ballast for at least one gas discharge lamp, in particular fluorescent lamp, with a supplied with an input voltage and controlled by a DC link voltage regulator smoothing circuit (PFC) for generating a regulated DC link voltage and fed with the DC link voltage Inverter, to whose output a load circuit is connected, in which at least one lamp can be used, wherein - the DC link voltage controller directly or indirectly detects the output power of the load circuit, and - The intermediate circuit voltage controller has properties that depend on the output power of the load circuit. 13. Electronic ballast for at least one gas discharge lamp, in particular fluorescent lamp, with a supplied with an input voltage and controlled by an intermediate circuit voltage regulator smoothing circuit (PFC) for generating a regulated DC link voltage and a DC DC link-powered inverter, at the output of a the lamp containing load circuit is connected, wherein - The DC link controller is designed as a logic circuit, and - A software-controlled controller supplies the DC link controller setpoints for the operation of the smoothing circuit. 14.Vorschaltgerät according to claim 13, wherein the controller the setpoint values pending transmitted from the controller dimming values transmitted to the intermediate circuit controller. 15. Ballast according to claim 13 or 14, wherein the controller transmits the DC link controller setpoints depending on the type and / or level of the input voltage. 16. Ballast according to claim 15, wherein the controller increases the setpoint value for the DC link voltage at higher input voltages. 17. Ballast according to one of claims 12 to 16, wherein the intermediate circuit controller transmits the controller at least one operating value of the smoothing circuit. 18. Luminaire, comprising at least one gas discharge lamp and a ballast according to one of the preceding claims. 19. A method for operating a dimmable electronic ballast for at least one gas discharge lamp, in particular fluorescent lamp, with a supplied with an input voltage and a DC link voltage regulator controlled smoothing circuit (PFC) for generating a regulated DC link voltage and a DC DC link powered inverter supplying the lamp, wherein - The ballast dimming values for specifying a target lamp power are supplied, and - The DC link controller has different properties for different applied dimming values. 20. A method for operating an electronic ballast for at least one gas discharge lamp, in particular fluorescent lamp, with a supplied with an input voltage and by a DC link controller • controlled smoothing circuit (PFC) for generating a regulated DC link voltage and a DC link voltage supplied with the inverter which supplies the lamp, being - The DC link controller is designed as a logic circuit, and - A software-controlled controller supplies the DC link controller setpoints for the operation of the smoothing circuit. 21. A method for operating a dimmable electronic ballast for at least one gas discharge lamp, in particular fluorescent lamp, with a supplied with an input voltage and controlled by an intermediate circuit voltage regulator smoothing circuit (PFC) for generating a regulated DC link voltage and fed with the DC link voltage Inverter which supplies the lamp, wherein - the DC link regulator directly or indirectly detects the output power of the at least one lamp, and - characteristics of the DC link regulator Properties are adjusted depending on the output power. A computer software program product comprising a method as claimed in any one of claims 19 to 21 when run on a computing device. 23. Microcontroller, characterized in that it is designed to support a method according to one of claims 19 to 21.