EP2191697A1 - Operating device for illumination means having different operating parameters and a method for configuring the same - Google Patents

Abstract

The invention relates to a method for configuring an operating device (V) for illumination means (L), particularly an electronic ballast for gas discharge lamps, wherein different types of an illumination means (L) may be connected to the operating device (V). The method comprises the following steps: a) identifying a present connection configuration, selected from a plurality of possible connection configurations, b) determining the type of lamp based on the connection configuration identified, for example, using a table, and c) establishing the operating parameters for the type of lamp identified, which are stored in a table for each lamp type.

Description

 Operating device for lamps with different operating parameters and a method for configuring the same.

The invention relates to an operating device for lamps with different operating parameters, in particular electronic ballast for gas discharge lamps, and a method for configuring such a control gear.

Various types of gas discharge lamps have been developed in recent years. Not only do they differ in their external dimensions, they also require that certain type-specific operating parameters, such as lamp voltage, lamp current, preheat voltage, preheat current, preheat time, etc., be maintained. In order not to have to provide a special ballast for each lamp type, ballasts have been developed so that different types of lamps can be operated, the ballasts recognize the respective lamp type itself.

According to EP 1103165B1, the lamp type is detected by measuring the filament current flowing through the lamp filament. The current depends on the filament resistance and the filament voltage applied to the filament. When using a previously known filament voltage, the filament current is indicative of the filament resistance. For some lamp types, however, the difference in the filament currents or the filament resistances is very small. If measurement inaccuracies and manufacturing tolerances are taken into consideration, it has hitherto not been possible to identify the type of coil and thus the type of lamp with satisfactory reliability.

Furthermore, there are gas discharge lamps that differ only minimally and can be distinguished only with great effort. On the one hand, there are gas discharge lamps with different nominal power but the same or very similar helix. However, there are also gas discharge lamps with electrodes which are not preheated or whose filament current (preheating current) can not be detected.

The invention has for its object to provide an operating device for operating bulbs with different operating parameters, which waives a measurement of the lamp to be operated before its commissioning and externally by an authorized person with / the required parameters for the light source is configurable.

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

The features for achieving this object are specified in claim 1. Advantageous embodiments of the Control gear according to the invention are the subject of claims 2 to 8.

The invention further relates to a method for configuring this operating device, the steps of which are specified in claim 9 and further developed in claims 9 to 12.

While the above-mentioned claims relate to the generalized solution, the following statements are intended to make the invention understandable in other words chosen.

This results in the following sequence of method steps:

a) detecting an actual terminal configuration selected from a plurality of possible provided terminal configurations,

b) determining the type of lamp based on the recognized connection configuration, for example. By means of a table that assigns one of several possible lamp types of each possible connection configuration, and

c) Setting the operating parameters for the recognized lamp type, which are stored in a table for each lamp type.

The invention is based on the following finding:

The inventive operating device has several different, differently marked connections eg for the phase connection of the mains supply. Internally, the two terminals are each combined via a voltage detection device, which forwards information to the control unit of the electronic ballast via the selected mains connection, and connected to the internal line filter.

Now, if one of the two terminals is selected as the grid connection (i.e., connected to the grid), the electronic ballast starts its control unit internally after the grid is turned on. This checks the signals of the two voltage detection devices, which are each coupled to the power connections. Since there are several possibilities of feeding through the at least 2 available and selectable power connections, thus several configurations of the electronic ballast can be specified.

Depending on the signaling of the voltage detection devices, the control device can recognize the configuration selected by the user and set the internal operating parameters.

The invention further relates to a ballast for a gas discharge lamp, which operates according to the method described above. This ballast has the following features:

Memory means for a table in which a specific connection configuration is laid down for each lamp type, Measuring means for determining the selected connection configuration,

Comparing means for determining the lamp type by comparing the selected terminal configuration with the corresponding configuration stored in the table.

A refinement of the ballast may consist in providing means for setting at least one operating parameter for the determined lamp type.

The measuring means may comprise a voltage divider connected to the mains connection, from which a signal corresponding to the mains voltage is derived.

An embodiment of the invention will be described below with reference to the drawings.

Show it:

Fig. 1 pin assignment for an electronic

Ballast according to the invention;

2 shows a gas discharge lamp with associated

ballast; and

3 shows a block diagram of the network inputs for an electronic ballast according to the invention. Fig. 1 shows the pin assignment for an electronic ballast according to the invention.

The pin assignment of an electronic ballast shown here uses the method described for a high-pressure discharge lamp control gear. Since these lamps are not pre-heated and no measurement of the electrode resistance before ignition and thus before the start of the lamp is possible, the described method is very advantageous in these lamps to provide a way to provide the user with an electronic ballast for different lamps, which easily and quickly recognize the connected lamp or desired power.

In the example of FIG. 1, the ballast is provided with two terminal configurations, namely the options "Grid Power 1" and "Grid Power 2". Depending on where the phase of the grid is connected, the multi-lamp ballast sets itself with respect to the operating parameters on the lamp type with the power 1 or the power 2.

Different forms of selection are possible, which can also be combined with each other as desired:

Selection via the selection of the network terminal (eg as shown above) Selection via lamp terminal Selection via insertion of a jumper, i. a jumper (shorting plug or resistor),

- Dynamic switching via switch or relay - Bit combinations (if 2 phases are connected, the selection of a 3rd lamp type is possible)

Fig. 2 shows a gas discharge lamp L, which is connected to a trained according to the invention electronic ballast V. The ballast V includes a connected to the AC mains bridge rectifier 1, which rectifies the mains voltage, and a DC voltage intermediate circuit 2 supplies. The intermediate circuit 2 is a half-bridge inverter 3 connected downstream, containing two alternately clocked switch. The inverter 3 is followed by a pure resonant circuit, which consists of a choke and a capacitor. The lamp is connected in parallel with the capacitor. The circuit parts 1 to 4 are common and known in ballasts.

The ballast should now be designed so that with him fluorescent lamps L of different types can be operated. The individual types differ not only by external dimensions, but also by different operating parameters, such as lamp current, lamp voltage, filament voltage, filament current, ignition voltage, preheating time, etc.

Two voltage detectors 9, which are each coupled to the mains connections, determine which connection is contacted to mains voltage (to the phase conductor). The connection configuration determined by the voltage detectors 9 is supplied to comparison means 12 which compare it with the values stored in a table stored in memory means 11. The table contains for each with the Ballast to be operated lamp type an associated port configuration. This is compared with the determined connection configuration. The comparison means 12 then report the determined lamp type to the operating parameter setting means 5. Last then take the relevant settings on the ballast V before. By way of example, this is taken into account in FIG. 2 by the connection between the operating parameter setting means 5 and the inverter 3 and the helical-current regulator 8. Thus, the clock frequency and / or the cycle times of the two switches of the inverter and the filament current can be influenced in this way to set certain operating parameters. The Wendelstrom- controller 8 controls the Wendelstrom-generating means 6, which in turn supply the filament current to the filaments Wl and W2 of the lamp L.

In Fig. 3 is a concrete realization of the voltage detector. The electronic ballast has 2 different, differently marked connections (L1, L2) for the phase connection of the mains supply V _ma i _ns . Internally, the two terminals are each connected via a voltage detector (V_L1 and V_L2), which forwards information to the control unit of the electronic ballast via the selected mains connection and connected via an internal mains filter and a rectifier, which serves to decouple the two inputs.

The connection for the neutral conductor N can be simple and internally supplied to both input stages. If one of the two connections is now selected as the mains connection, the electronic ballast starts its control unit internally after switching on the network. This checks the signals of the two voltage detectors, which are each coupled to the power connections. Since there are several possibilities of feeding through the at least 2 existing and selectable mains connections, several configurations can therefore also be predefined for the electronic ballast (eg also the simultaneous use of both connections, described below as a bit combination). Depending on the signaling of the voltage detectors, the control device can recognize the configuration selected by the user and set the internal operating parameters.

The configuration via switched mains inputs can also be switched during operation, e.g. with a relay to transmit the electronic ballast further operating parameters or control values. For example, by switching a network access, an energy-saving function with a reduced light level can be achieved

When selecting the lamp terminal, the user has several options for connecting a lamp ready, where he can transmit the electronic ballast on the pin assignment information about the connected lamp. The electronic

Ballast then leads in a start phase before the actual lamp start a test measurement on one of the

Connections connected detector unit, which determines the occupied connections. Alternatively, only a single network connection can be present, at which information about the selected lamp type is transmitted via a selective connection and disconnection of the network. This signal at the mains connection is detected by the detector. In this embodiment, it may be necessary for an energy store to be present in the electronic ballast, which can maintain the supply and further operation of the control unit, the detector unit or the electronic ballast or parts thereof during the phases without mains supply. This signaling can be realized via a switching sequence, it can also be done via a relay such signaling.

The signaling via a selective connection and disconnection of the network can take place both via the network input directly and via a further network input with a detector unit.

Such an electronic ballast is thus not bound to a specific type of gas discharge lamp. Particularly advantageous is the described method for a control gear for high pressure discharge lamps.

Claims

Claims :

1. operating device (V) for light sources (L) with different operating parameters, in particular electronic ballast for gas discharge lamps, comprising: - connection means for connecting the

Operating device to at least one external voltage source (mains),

- Energy conversion means (1-4,6,8) for converting the energy supplied by the external power source (network) in a form suitable for supplying to the operating device (V) to be operated light source (L) by adapting the operating parameters, and

Means for connecting the illuminant to the operating device, characterized by

- Configuration means for selecting one of several possible identifiers for the / the desired operating parameters of the operating device (V) to be operated bulb

(L) and for transmitting the identifier to the operating device (V), preferably by a person authorized to configure the operating device (V),

- Evaluation means (9) for evaluating the identifier by comparing the same with the values of a stored in the operating device (V) table, and - Control means (5, 8, 6) for influencing the energy conversion means such that they adjust the / the required operating parameters for the operating device (V) to be operated light source (L) according to the evaluation result.

2. Operating device according to claim 1, characterized in that the configuration means are realized by a plurality of mutually decoupled terminal terminals (L1, L2, N) for at least two poles of the external electrical voltage source (network).

3. Operating device according to claim 1, characterized in that the configuration means are realized by a plurality of mutually decoupled connection terminals for the two connection elements of the operating device (V) to be operated light source (L).

4. Operating device according to claim 2 or 3, characterized in that each of the plurality of terminal terminals is connected via a decoupling network with a voltage divider, wherein the voltage at the Teilerabgriff the identifier for the / the operating parameters of the with the operating device (V) operating light source (L) represents.

5. Operating device according to claim 4, characterized in that the decoupling network for each of the plurality of terminal terminals includes a separate bridge rectifier.

6. Operating device according to claim 2 or 3, characterized in that the configuration means a jumper (jumper) with resistors and / or

Includes shorting plugs, by means of which a minority of the plurality of connection terminals for the realization of the individual identifiers can be connected.

7. Operating device according to claim 1, characterized in that the configuration means comprise a switch or a relay.

8. Operating device according to claim 1, characterized in that the configuration means are designed so that they allow a temporary interruption of the connection to the external voltage source.

9. A method for configuring an operating device (V) for light sources (L), in particular an electronic ballast (V) for gas discharge lamps (L), wherein the operating device (V) different types of a light source (L) can be connected with different operating parameters, characterized by the following steps:

a) selecting one of a plurality of possible identifiers for the desired operating parameter of the illuminant (L) to be operated with the operating device (V) by a person authorized to configure the operating device (V),

b) transmission of the selected identifier to the operating device (V),

c) automatic determination of the type of lamp by the operating device (V) based on a in the

Operating device (V) stored table by comparing the table values with the transmitted identifier,

d) automatic setting of the operating parameter (s) by the operating device (V) on the basis of the comparison result.

10. The method according to claim 9, characterized in that the individual identifiers are realized by different connection configurations at the input or at the output of the operating device (V).

11. The method according to claim 10, characterized in that the different connection configurations are realized by

- Selection of two of several power terminals,

- Selection of two of several lamp terminals,

- appropriate setting of resistors or short-circuit plugs in a jumper,

- Switching a switch or relay, and / or

- Combination of several available network sources.

12. The method according to claim 9, characterized in that the individual identifiers are realized by different network interruptions at the input of the operating device (V).

13. A method of configuring multi-lamp ECGs designed to operate different power gas discharge lamps (L), comprising the steps of: providing multiple terminal configurations;

Connection of one of the several connection configurations,

- internal measurement in the ECG to detect which connection configuration is actually connected, and

Operation of the associated gas discharge lamp (L) with operating parameters determined by the Depend on connection configuration.

14. Operating device for lamps, in particular electronic ballast for

Gas discharge lamps, comprising

- different configurable connections,

- memory means (11) for a table in which a specific connection configuration is laid down for each lamp type,

Measuring means (9) for determining the selected connection configuration,

- Comparison means (12) for determining the lamp type by comparing the selected terminal configuration with the corresponding stored in the table configuration.

15. Electronic control unit, in particular implemented as an integrated circuit, which is designed to carry out a method according to one of claims 9 to 13.