DE102008022198A1 - Type recognition of a gas discharge lamp to be operated with an electronic ballast - Google Patents

Abstract

The invention relates to a method for determining the type of gas discharge lamp (L) to be operated with an electronic ballast (V). According to said method, the coil voltage and the coil current are measured according to two successive times during the pre-heating phase. The heating power or the heating current is kept constant. From the measured current and voltage values, the cold resistance (Rcold) and the hot resistance (Rhot) are calculated and the differential resistance (Rdiff), that is normally independent of the starting temperature of the coil, is formed therefrom. In order to determine whether the gas discharge lamp is replaced by a substitution resistance (Rsub) for test purposes, it is tested whether the differential resistance (Rdiff) is lower than the substitution resistance (Rsub) and if this is the case, the hot resistance value (Rhot) is set as the differential resistance (Rdiff). With the aid of the thus defined differential resistance (Rdiff), the type of lamp is determined by comparing it to the stored reference values (level 1, level 2, level 3) in order to set corresponding operational parameters.

Description

The The invention relates to a method for determining the type of a an electronic ballast to be operated gas discharge lamp.

Such a method is according to EP 1519638 A1 known. In this known method, the voltage drop across a resistor located on the primary side of the heating transformer is measured at two different times during the preheating phase. The two voltage values thus determined are compared with reference voltage values stored in a memory to determine the lamp type.

After EP 1125477 B1 It is known to determine the filament resistance of the lamp to determine the lamp type by comparison with a reference resistance value stored in a register.

After EP 1103165 B1 the lamp type is identified by measuring the current flowing through the filament. The current is measured during the preheat phase at two consecutive times.

In the not yet published German patent application DE 10 2007 047 142.6 It is proposed to use the measured value of the helical resistance for determining the lamp type, although it is a prerequisite that the power supplied to the heating coil or the supplied helical current are kept constant during the preheating phase. As a result, the following advantageous effect is achieved: During the preheating phase, the coils heat up. With the heating also increases the coil resistance. For example, if the filament of a first type of lamp has the cold resistance R, it may double during the preheating phase, for example 2R. Now, if the filament of a second lamp type has the cold resistance 2R, its hot resistance would be 4R. During the preheating phase, therefore, there is a spreading of the resistance values to the effect that the distance or the difference of the hot resistances is twice as great as that of the cold resistances. Due to the greater distance of the hot resistors a more accurate determination of the lamp type is possible. However, as previously stated, the prerequisite for this is that the power supplied to the filaments or the filament current supplied to the filaments be kept constant during the preheating phase.

Based on the method described above ( EP 1519638 A1 ), the invention has for its object to provide a way to determine the lamp type.

Under "Lamp Type Detection" is Optionally also to understand that the number of parallel or serial by the operating device supplied gas discharge lamps can be determined with heating coils.

The Task is solved by the invention the combination of specified in the characterizing part of claim 1 Characteristics.

The Solution according to the invention takes over Principle of resistance measurement during during preheating time kept constant heating power or constant heating current. In addition to this measure, however, is off the measured hot resistance and the measured cold resistance the difference resistance is formed, which in any case then independent from the start temperature is when a helical voltage limit not yet used.

The optional detection of a substitution resistance as a substitute load can trigger a special behavior deviating from normal operation. On the one hand, deviating operating parameters can be used for this case be set for subsequent operation, where z. B. also the preheating time or the drainage behavior of the lamp start but it can also be changed by the TOE Operating parameters over the detected value of the substitution resistance for later operation, d. H. after the next Lamp start, be specified. This can be considered a kind of programming of the electronic ballast, whereby the respective types of can be given to recognizing lamps. An example it may be that an ECG the parameter sets for the combination of a 14 W and 24 W lamp as well as the Combination of a 21 W and 39 W lamp has saved. Depending on the specification through the once to be connected Rsub the ECG later between a 14 W and 24 W lamp or a 21 W and 39 W lamp.

The solution according to the invention allows the reference values for the differential resistances to cover a defined variation range for each lamp type. Thus, a determination of the lamp type is in any case possible if the determined differential resistance falls within one of these ranges of variation. If there is an undefined distance range between two variation ranges and a determined differential resistance falls within this distance range, the lamp type which was last recognized unambiguously can be selected for the determination. Alternatively, however, it is also possible to select the lamp type for the determination whose assigned variation range is adjacent to the distance range and Diffe covering resistance, which is smaller than the determined differential resistance.

further developments the process of the invention are the subject the dependent of claim 1 claims.

The The invention further relates to a ballast for at least one gas discharge lamp for execution the method of the invention is suitable. The features of such a ballast are specified in claim 11.

The relating to claim 11 dependent claims advantageous developments of this ballast.

According to a development of the invention, the number of parallel and / or serially powered by the operating device gas discharge lamps of a certain type.

To For example, it checks whether the validated differential resistance corresponds to n times one of the several corridor areas. If yes, it can be concluded that n lamps of the lamp type are connected in series at the output of the operating device, which is assigned to this corridor area.

It can still be checked if the validated Difference resistance to 1 / n times one of the several corridor areas equivalent. If so, it can be concluded that n lamps of that Lamp type connected in parallel at the output of the control gear are assigned to this corridor area.

embodiments The invention will be described below with reference to the drawings.

It demonstrate:

1 a schematic block diagram of the ballast according to the invention;

2 a flow chart showing how the inventive method is practiced;

3 a graph of the dependence of the helical resistance of the preheating time for three different lamp types and the resulting three ranges of variation for the differential resistance of each of these three lamp types;

This in 1 shown ballast V is used to operate a gas discharge lamp L with two heating coils W1 and W2.

To generate the operating voltage for the lamp L is a rectifier 1 the mains voltage rectified and smoothed in a smoothing circuit. An inverter 3 generates an alternating voltage, which is a series resonant circuit 4 is supplied. The over the capacitor of the series resonant circuit 4 decreasing voltage is supplied to the lamp L as the operating voltage.

A programmer connected to a bus 14 specifies the start of a preheat phase for the lamp L. He gives to the block 8th a start signal. The block 8th generates the heating power or the filament current for the filaments W1 and W2 of the lamp L. The heating power or the filament current are kept constant during the preheating phase. The heating power or the filament current of the lamp L via a block 6 guided, which contains means for limiting the helical tension. A limitation of the filament voltage is required to avoid a transverse discharge between the individual sections of the heating coils. The helix current flowing through the "cold" helix W2 generates a voltage drop across the resistor R3, the helical current measuring means 7 to be led. At a voltage divider R1, R2, a voltage is further removed, which is a measure of the filament voltage at the "cold" coil W2. This becomes the helical voltage measuring equipment 9 fed.

The from the Wendelstrom measuring equipment 7 and the helical voltage measuring devices 9 continuously measured values are stored 15 fed. The memory 15 is from the programmer 14 controlled such that the measured values for the filament current and the filament voltage are stored at two consecutive times during the preheat phase. The stored measured values for the filament current and the filament voltage are from the memory 15 from a quotient generator 10 fed, which calculates the cold resistance and the hot resistance of the helix. These values are taken from the quotient generator 10 to the difference value generator 11 forwarded, which calculates the difference resistance.

The difference value generator 11 leads the difference resistance of a decision logic 13 to, in turn, with a memory 12 corresponds by a table for reference differential resistances is stored. The decision logic 13 Compare that in the block 11 calculated differential resistance with the reference values in the memory 12 stored table and determines the type of lamp L operated by the ballast V. The determined lamp type is determined by the decision logic 13 to the operating parameter setting means 5 reported, among other things, the heating current or the heating power reset, if the lamp L of a other type than the previously operated with the ballast V lamp. Further operating parameters may be the preheating time, the ignition voltage, the lamp burning voltage, the lamp current or else parameters for fault shutdowns. However, it is also possible to set operating parameters for the power factor correction circuit, such as, for example, the bus voltage or the dynamics of the control loop.

It should be noted in this regard that the individual blocks in 1 not necessarily be realized by hardware. Rather, it is also possible that the function of some blocks is realized by a corresponding software in a processor. The block diagram in 1 should only serve the better understanding.

The logical sequence of the individual method steps for determining the lamp type, ie the software representation of the invention, is described in 2 shown. This will be explained below.

The representation in 2 concerns the case that two ballasts are operated in parallel with one ballast. Of course, it also includes the possibility of working with only one lamp.

To At the beginning of the pre-heating phase of the two lamps, the cold resistances Rcold1 and Rcold2 measured. The two measured values become the absolute value the difference | Rdiff | calculated. After that, three cases distinguished. If | Rdiff | smaller than a first reference value Ref1 is, so that means that the two lamps of the same type are. It then continues in "Case 1".

If | R diff | greater than the first reference value Ref1 but smaller than a second reference value is Ref2, that means that, while lamps are ready, but not the same Type are. In this case, the path "Case 2" is taken. The result usually results in a lamp being replaced becomes.

Now the path "Case 1" should be pursued further, in which the further evaluation is carried out with that lamp is whose helix has the lower cold resistance.

It it goes without saying that you can get to that point in the flowchart as well comes when only one lamp is present. In this case is omitted the splitting of the cold resistances into two paths. Of the further course of the flowchart is anyway only on a differential resistance limited, be it the lamp with the helix with the lower one Cold resistance or the single lamp.

Of Furthermore, it is now checked whether the differential resistance Rdiff is less than a predefined substitution resistance Rsub. This case is given when the lamp is used for testing purposes such substitution resistance is replaced. If that is the Case is different, the cold resistance and the hot resistance Not. Therefore, if the decision is "yes" - the Difference resistance Rdiff equal to the hot resistance Rhot set.

in the A case of recognizing a substitution resistance value may be Special, deviates from normal operation behavior become. For example, may differ for this case Operating parameters set for subsequent operation where also the preheating time or the flow behavior of the Lamp starts can be changed, it can be Ballast but also operating parameters via the recognized value of the substitution resistance for the later operation, d. H. after the next lamp start, be specified. This can be considered a kind of programming of the ballast understood, with the respective types of recognizable Lamps can be specified. An example for may be that a ballast the parameter sets for the combination of a 14 W and 24 W lamp as well as the combination saved a 21 W and 39 W lamp. Depending on the specification by the value of the one-time substitution resistance can the ballast later between a 14 W and 24 W lamp or a 21 W and 39 W lamp differ and thus that deal with that problem, the 14W bulb and the 21W bulb can not be distinguished by their coils.

If the difference resistance Rdiff greater than the substitution resistance Rsub is, i. h., if - because a lamp used is - Rcold and Rhot sufficiently different, that is the result of the decision "no".

When Next, the decision is whether the differential resistance Rdiff less than a first stored resistance value "level 1 "is. If differential resistance Rdiff less than this Level is 1, so the decision is made that it is here is the lamp type 1.

If the difference resistance Rdiff between the already mentioned levels 1 and another higher level 2, so the decision is made that a lamp type 2 is present.

If the difference resistance Rdiff between the level 2 and another Level 3, then the decision is made that the lamp type 3 is present.

The terms "Level 1", "Level 2" and "Level 3" will be discussed below 3 explained in more detail.

Provided the differential resistance Rdiff falls within the mentioned limits and the lamp type can be determined by this, is with the Set the lamp parameters according to the determined lamp type continued.

If on the other hand, no area has been found in which the difference resistance Rdiff can be classified, so is saved with the last Value continued.

3 shows the course of the filament resistance in three different lamp types during the preheat phase, which takes 500 ms.

at the first helix is the cold resistance Rcold1 2 WW, and the hot resistance Rhot1 3.88 W, where WW stands for a resistance unit.

at the helix of the second lamp type is the cold resistance Rcold2 4 WW. He rises during the preheat phase on the Hot resistance Rhot2 with 14 WW on.

The The filament of the third lamp type starts with the cold resistor Rcold3 at 8 WW. This resistance increases during the preheat phase on the Rhot3 hot resistor with 40 WW.

you Detects how resistance values with thermal heating spread apart. The prerequisite is that the coils during the preheating always the same heat output or the same Heating current is supplied.

If the difference resistance is now formed in each case from the _hot resistance R _hot and the _cold resistance R _cold, the difference resistance Rdiff1 for the first lamp type is 1.88 W. The difference resistance Rdiff2 for the second lamp type is 10 W. The difference resistance Rdiff3 for the third Lamp type is 32 W.

The Spreading of the hot resistors Rhot1, Rhot2 and Rhot3 allows it for the differential resistors Rdiff1, Rdiff2 and Rdiff3 define ranges of variation that have a distance from each other. The variation ranges are with Hatch lines marked.

A sure identification is given in any case if the determined Difference resistance of the heating coil of a lamp in one of the three hatched Areas falls.

It However, that has proved to be a satisfactory provision of the lamp type is also possible, if one with the three drawn levels works. The first level "level 1 "is the cold resistance Rcold1 of the first lamp type identical. The second level "Level 2" is with the Hot resistor Rhot2 of the second lamp type identical. The third level "Level 3" is considerable Distance above the lamp resistor type Rhot3.

With is the distance arrows shown on the right in the illustration represented by dashed lines, that the determination areas for the relevant lamp type over the lower one range not defined to the next level.

The above the shaded areas going beyond identification zones are not mandatory, but have been selected case-specifically. It is essential that the hatched areas, ie the variation areas for the differential resistances an identification allow the lamp type with great certainty.

In the case of lamp type 3, however, it would be conceivable that - with corresponding prior heating - the cold resistance Rcold3 increases so much in the course of the preheating time of 500 ms that the hot resistance Rhot3 is far above the value (40 WW) which is in 3 specified. With the assumed constant heating power or the constant helical current, however, this would mean that transverse discharges occur between the individual sections of the helix because the voltage between these sections becomes too high. Here, therefore, the effect of the helical voltage limit sets in connection with block 6 in 1 was explained. The limitation of the heating voltage causes the hot resistor Rhot3 can not rise to the theoretical value described above, but is limited.

As explained above is the validated according to the invention Difference resistance of the heating coil compared with predetermined areas. According to a development of the invention, this approach also be used to calculate the number in parallel and / or serially the control gear supplied gas discharge lamps. Also in such a multi-lamp application can continue on the used lamp type are closed (ie the associated Operating parameters, for example for the preheating, ignition and / or burning operation are set), as long as a uniform Lamp type is used.

For this purpose, it is more precisely checked whether the validated differential resistance corresponds to n times one of the several corridor ranges. If so, can be concluded that n lamps of that lamp type are connected in series at the output of the operating device, which is assigned to this corridor area.

It will continue to check if the validated differential resistance which corresponds to 1 / n times one of the several corridor areas. If yes, it can be concluded that n lamps of the lamp type are connected in parallel at the output of the operating device, which is assigned to this corridor area.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 1519638 A1 [0002, 0006]
• - EP 1125477 B1 [0003]
• - EP 1103165 B1 [0004]
• - DE 102007047142 [0005]

Claims (21)

Method for determining the type of gas discharge lamp (L) to be operated with an electronic ballast (V), comprising the following steps: a) preheating at least one heating coil (W1, W2), b) directly or indirectly measuring the coil voltage (U _W ) at least two different times, c) determining the lamp type by comparing measured values with stored reference values, characterized in that d1) during the measurement between the two times the filament current or the heating power supplied to the filament is kept constant up to a predetermined limiting heating power, or d2) At the beginning of the preheating phase, a predetermined heating power or a predetermined heating current is measured. e) additionally the heating current is measured, f) from the measured values of the filament voltage and the filament current at the first time the cold resistance (Rcold) and at the second time the hot resistance (Rhot) are calculated, g) from the hot resistance (Rhot) and the Cold resistance (Rcold) of the differential resistance (Rdiff) is calculated, wherein - if the difference resistance (Rdiff) is less than a predefined resistance value (Rsub) - set for the differential resistance (Rdiff) of the hot resistance value (Rhot), and h) as with the stored reference values to be compared measured value of the difference resistance (Rdiff) determined according to point g) is used to determine the lamp type. Method according to claim 1, characterized, that the reference values for the differential resistors (Rdiff) for each lamp type a specified range of variation cover, that - if the determined difference resistance (Rdiff) falls within a range of variation - this variation range assigned lamp type is selected, that if There is a distance between two ranges of variation and a determined difference resistance (Rdiff) falls in this distance range - the one Lamp type is selected for determination, the last unique has been recognized or alternatively, the lamp type is selected for determination whose assigned range of variation is adjacent to the distance range and differential resistances covering, which are smaller than the determined differential resistance (Rdiff). Method according to claim 1, characterized in that that step (d1) is realized by controlling the helical current. Method according to one of claims 1 to 3, characterized by the further step: i) Adjust at least one operating parameter for the determined Lamp type. A method according to any one of claims 1 to 4, characterized in that sets of reference values stored for different preheating values, such as filament current, filament voltage or heating power apply. Method according to one of claims 1 to 5, characterized characterized in that - if with the ballast (V) several lamps (L1, L2) to be operated - a Check is made to see if the lamps of the same Type are. Method according to Claim 6, characterized that to carry out the test on lamp types equality the difference of the cold resistances (Rcold) of two each Lamps (L1, L2) formed and with a first reference value (Rref1) is compared and that inequality is detected when the Difference is greater than the first reference value. Method according to one of claims 1 to 7, characterized in that - if with the ballast (V) several lamps (L1, L2) to be operated - one Examination is then made, if at a lamp a fraction of a heating coil is present, whose voltage drop for calculation of the helical resistance (Rcold, Rhot) is measured. Method according to claim 8, characterized in that that to carry out the test on helical break the difference of the cold resistances (Rcold) of two each Lamps (L1, L2) formed and with a second reference value (Rref2) is compared, and that a Wendlebruch is determined when the difference is greater than the second reference value is. Method according to claim 9, characterized that - if the measurement of the heating currents at several with the ballast (V) operated lamps (L1, L2) via a common resistance (R3) occurs - when diagnosed Breakage of a heating coil (W1b, W2b) the calculated spiral resistances (Rcold, Rhot) according to the proportion of the broken heating coil on the total number of heating coils, their heating current through the measuring resistor (R3) is reduced. Method for the detection of the number of parallel and / or serially supplied at the output of a control gear gas discharge lamps with heating coils, wherein the number is carried out on the basis of a differential resistance, the resistance difference between a measurement at a first temperature and a comparatively higher temperature. The method of claim 11, wherein checked whether the differential resistance is n times one of several Corresponding corridor ranges, where in the positive case it is concluded that n lamps of the lamp type in Series are connected at the output of the operating device, the assigned to this corridor area. The method of claim 11 or 12, wherein checked whether the differential resistance is 1 / n times one of several Corresponding corridor ranges, where in the positive case it is concluded that n lamps of that type of lamp parallel are interconnected at the output of the operating device, this Corridor area is assigned. Integrated circuit, in particular ASIC, used for Carrying out a method according to one of the preceding Claims is designed. Ballast (V) for at least one gas discharge lamp (L) with two heating coils (W1, W2), comprising: - means ( 8th ) for generating and a constant filament current or a constant heating voltage and for applying at least one of the two heating coils (W1, W2) with the constant heating current or the constant heating power, - measuring means ( 9 ) for directly or indirectly measuring the voltage drop across the helix (W1, W2), - programmer means ( 14 ), which determine two different times during the preheat phase, at which the voltage drop across the coil (W1, W2) is measured, - means ( 7 ) for measuring the filament current, - storage means ( 15 ) for storing the measured values of the voltage drop across the helix (W1, W2) and the helical current flowing through the helix to the two of the programmer means ( 14 ) given times, - means ( 10 ) for calculating the coil resistances (Rcold, Rhot) to the two of the programmer means ( 14 ) predetermined times by quotient formation from the stored values for the measured filament current and the measured voltage drop across the filament (W1, W2), - storage means ( 12 ) for a table in which a reference differential resistance value is stored for each lamp type for a given filament current or heating power, 12 ) for determining the lamp type by comparing the calculated differential resistance (Rdiff) with that in the memory means ( 12 ) reference differential resistance values. Ballast according to claim 15, further characterized by - means ( 5 ) for setting at least one operating parameter for the determined lamp type. Ballast according to one of Claims 15 or 16, characterized in that the means ( 8th ) for generating a constant filament current or a constant heating power a regulator ( 8th ) for the helical flow or the heating power. Ballast according to one of claims 15 to 17, characterized in that the measuring means ( 9 ) for directly or indirectly measuring the voltage drop across the coil (W1, W2) acted upon by the predetermined constant filament current or the predetermined constant heating power and comprise a voltage divider (R1, R2) connected in parallel with the heating filament. Ballast according to one of claims 15 to 18, characterized in that for measuring the filament current ( 8th ) with the heating coil (W1, W2) a measuring resistor (R3) is connected in series, and that the voltage drop across this measuring resistor is used as the measured value for the helical current. Ballast according to claim 19, characterized that - if with the ballast two or more Lamps (L1, L2) are operated - by a heating coil (W1b, W1b) of each of the lamps flowing helical current through the measuring resistor (R3) is guided. Ballast according to one of Claims 15 to 20, characterized in that, if a heating coil (W1b, W2b) is fractured by the means ( 10 ) calculated of the coil resistance (Rcold, Rhot) corresponding to the proportion of the broken heating coil to the total number of heating coils whose heating current is passed through the measuring resistor (R3), is reduced.