SE515566C2 - Procedure and device for controlling gas discharge lamps - Google Patents

Abstract

A method for controlling a drive unit for gas discharge lamps where applied power consists of a DC voltage applied to a converter stage which is adapted to convert the DC voltage to an AC voltage suitable for the lamp, wherein the AC voltage is applied to a lamp circuit that includes a lamp (2) and an inductance (3) connected in series with the lamp, and wherein there is provided a lamp ignition circuit (4). The invention is characterized in that there is connected in a current branch of the drive unit (1) common to both the AC voltage side and the DC voltage side a current measuring sensor (5) whose output signal is used to generate a first control signal (13) corresponding to the power supplied to the lamp circuit, and a second control signal (14) corresponding to the peak current of the lamp circuit or, alternatively, corresponding to the reactive power present in the lamp circuit; and in that a third control signal (17) which constitutes the dominant signal of the first (13) and the second (14) control signal or, alternatively, a function thereof, is caused to control the current supply to the lamp in a feedback system.

Description

20 25 30 515 0566 is hardly compensated with the most common drive device described above.

A third disadvantage is that detection of fault conditions of either the drive device or the lamp requires additional components to measure current and / or voltage in the lamp circuit.

In connection with the start of the use of electronic drive units, the above-mentioned second disadvantage has certainly been virtually eliminated by means of feedback control systems, but for the combination of the first and the second disadvantage and the combination of the second and the third disadvantage, respectively,> no suitable solution presented.

The present invention provides a method and apparatus that eliminates these disadvantages.

The present invention thus relates to a method for regulating a drive unit for gas discharge lamps where the supplied power consists of direct voltage which is applied to a converter stage, which is arranged to convert the direct voltage to an alternating voltage suitable for the lamp, which alternating voltage is applied to a lamp circuit. comprising a lamp and an inductance connected in series with the lamp and where an ignition circuit for the lamp is present, and is characterized in that in a current branch common to both AC and DC side a current measuring sensor is connected whose output signal is used partly to generate a first control signal corresponding to the power supplied in part to the second control signal lamp circuit, corresponding to the peak current of the lamp circuit, or alternatively corresponding to the reactive power present in the lamp circuit, and in that a third control signal constitutes the dominant of the first and second control signal, G \ ANSOKN95 \ 95032S2se.tr.doc, 2001-05-22 or alternative in the case of a function of these, is brought to control the power supply of the lamp in a feedback system.

Furthermore, the invention relates to a device of the type and with the main features stated in claim 10.

The invention is described in more detail below, partly in connection with an exemplary embodiment of the invention shown in the accompanying drawing, in which - figure 1 shows a block diagram of a drive device according to the invention - figure 2 shows an alternative embodiment - figure 3 shows a converter step according to a first embodiment - shape - figure 4 shows a converter step according to a second embodiment - figure 5 shows a control circuit.

Figure 1 shows a device for regulating a drive unit for gas discharge lamps where the supplied power consists of direct voltage which is applied to a converter stage 1, which is arranged to convert the direct voltage to an alternating voltage suitable for the lamp 2, series with the socket lamp 2 and a inductance 3 is connected in the lamp and where a known ignition circuit 4 for the lamp is present.

According to the invention, a current measuring sensor is connected in an AC voltage common to both and the direct voltage side of the drive unit, see Figures 3 and 4. The current measuring sensor is arranged to emit an output signal at its output 10. In the exemplary embodiments, the current measuring sensor 55 consists of an outlet. However, other current measuring principles can be used, such as for example "Sense-FET" transistors with current measuring output.

GÅANSOKN95 \ 9503252sc.lr.doc, 200l-05-22 which alternating voltage is applied to a lamp circuit inside 515 20 25 30 515 566 There is also a signal processing circuit 6 to which the said output signal 10 of the current sensor 5 is output to the input 11 of the signal processing circuit, see figure 5. The signal processing circuit 6 is arranged to form a first signal corresponding to the average value of the current, which is a measure of the power applied to the lamp, and a second signal corresponding to the peak value of the current, or alternatively corresponding to the current in the lamp circuit. existing reactive effect.

The signal corresponding to the average value of the signal is formed in an average value circuit 7, which may be an RC circuit. The signal corresponding to the peak value is formed in a peak value circuit 8. This signal can be a rectified average value. the mean value of the negative half periods is formed in a circuit 9 as a measure of the reactive power in the lamp circuit.

Signal processing circuit 6 further comprises a comparison circuit 12 arranged to compare the first 13 and the second 14 signals, respectively. The first signal 13 is amplified by a factor k, which is greater than 1, in an amplifier 15 since the peak value is always greater than. the mean. Assuming that the alternating voltage in the lamp circuit would be completely sinusoidal, k would be equal to the root from 2. The factor k can be varied, but should be in the range 1.3 to 1.5.

The comparison circuit is arranged to control a switch 16, which is arranged to connect said first 13 and said second 14 signal to said converter stage 1. It is the dominant of the two compared signals 13, 14 which is used as a third control signal, which is applied the converter stage, via an input 18. The third control signal 17 is used as a control signal to control the power supply of the lamp 2.

Alternatively, in one embodiment said switch may be arranged so that the third signal 'consists of' a function. of 'the first and the second signal. In this case, the suitably mentioned comparison circuit and the said switch consist of a microprocessor arranged to receive the first and the second signal and arranged to output the third signal. depending on said function.

As an alternative to comparing the signals 13 and 14 from the circuits 7 and 8, the first signal 13 can instead be compared with an output signal 19, via a conductor indicated by dashed lines in Figure 5, from the circuit 9.

According to a preferred embodiment, the power supplied to the drive device consists of rectified alternating voltage which is supplied via conductor 20.

According to a first embodiment, shown in Fig. 1, said converter step 1 comprises a first converter stage 21 arranged to convert applied DC voltage 20 to a DC voltage 22 with another voltage level and comprises a second converter stage 23 arranged to convert the latter DC voltage to an alternating voltage applied to the lamp voltage. . The second converter stage is shown in Figures 3 and 4. is connected in the second converter stage. The said third control signal 17 is applied to the first converter stage 21 in order thereby to convert the applied direct voltage to a direct voltage of the desired level. The first converter stage comprises for this purpose a suitable known DC / DC converter.

According to a second embodiment, shown in figure 2, said converter step comprises a converter step 24 arranged fl to convert applied DC voltage 20 to an alternating voltage 25 with G \ ANSOKN9S \ 9503252sc Indø fi. 200 i -05-22 Current saturation sensor. 5 15 10 25 20 25 30 515 see the desired frequency applied to the lamp circuit. The current measuring sensor 5 is connected to the converter stage 24. The third control signal 17 is applied to a control circuit 26 arranged to generate the frequency to which the converter stage 24 is caused to convert the applied direct voltage. This frequency is delivered via conductor 27 to the converter stage 24. The control circuit 26 is of a suitably known type, such as a DC / AC converter with frequency control depending on a control signal.

In order to further accelerate the start-up process, in this embodiment the initially mentioned frequency can be made to be considerably lower than during the state of operation, whereby due to the series choke the lamp current is initially made to be considerably higher than in the state of operation.

Figure 3 shows an embodiment of the said second converter stage 23 and the said converter stage 24, respectively. The converter stage 32, 24 comprises a transformer 28 which converts the direct voltage 20 to a suitable alternating voltage using bridged semiconductor switches 29, 30 which alternately brought into the leading and non-leading states, respectively. In parallel over the semiconductor switches, diodes 31, 32 are connected which create a current path for the reactive power circulating in the lamp circuit due to the influence of the inductance.

Figure 4 shows an alternative, second embodiment of the converter stages 23, 24. This converter stage correspondingly has semiconductor switches 33, 34 over which diodes 35, 36 are connected.

In case the converter step in Figure 3 or 4 is used in the embodiment in Figure * 1, the semiconductor switches are controlled by means of a G \ ANSOKN95 \ 9503252sc Ir dOC. 2001-05-22 10 15 20 25 30 515 566 not shown oscillator which emits a suitable fixed frequency at which the semiconductor switches thus operate.

In the case where the converter steps in Figure 3 or 4 are used in the embodiment according to Figure 2, the frequency emitted via the conductor 27 is applied to the semiconductor switches so that they operate at this frequency.

In the description above, the drive unit has been described on the basis of conventional electronic components. For serial production of the drive unit, this can instead be realized with a device a digital comprising a microprocessor, signal processor or an integrated circuit specially developed for the purpose and suitable software.

During the start-up process, when the lamp's plasma has not reached a steady state, the lamp voltage is low and consequently this effect of this inductance. the lamp current. gene dominates becomes high compared to the state of continuity, but the power delivered to the lamp becomes low due to the low lamp voltage. However, the durability of the lamp is not limited at this stage by the maximum permissible lamp power, but rather by the maximum current to which the lamp can be exposed without affecting its expected service life.

The first signal 13 is compared with the second signal 14. If the second signal is larger than the first, there is a heating state, the second signal 14 being used as a control signal to the converter stage 1. In this case, the lamp is supplied with a higher current than that corresponding to the steady state. . This shortens the start-up process. When the temperature of the lamp rises, the lamp voltage also increases, the first signal 13 rising while the second signal 14 decreases G. \ ANSOKN95 \ 9503252sc.tr doc, 200l-05-22 70 15 20 25 30 515 566 the lamp circuit. When the first signal. becomes larger than. the second, the control signal to the converter stage 1 is switched to being the first signal 13, whereby the signal corresponding to the lamp power thus becomes a control signal.

According to a preferred embodiment, the converter step is 23; 24 so arranged that when the control signal corresponding to the peak current of the lamp circuit, i.e. the second signal 14, constitutes control signal 17 to said converter stage, this is arranged to control the semiconductor switches 31, 32; 33, 34 so that the time during which the semiconductors are in a conducting state is shortened in order thereby to achieve a current limitation in the lamp circuit.

In addition to only regulating the lamp's power supply during the start-up process and during the continued condition, the control device according to the invention can provide information on whether a fault condition exists in the lamp circuit and on the nature of the fault.

According to a preferred embodiment, there is a time and detection circuit 37 arranged to be activated when the ignition circuit 4 of the lamp is activated. The time and detection circuit 37 is arranged to, after a predetermined time, which time corresponds to the lamp reaching a steady state, detect a fault state when said second control signal 14 is larger than said first control signal. 13. This fault is most likely caused by a short circuit in or adjacent to the lamp.

The detection circuit thus comprises a comparison circuit.

According to a further preferred embodiment, the time and detection circuit 37 is also arranged to detect a fault condition after a predetermined time when the said first G. \ ANSOKN95 \ 9503252sc.lstdoc. 2001-05-22 10 15 515 566 and the mentioned second control signal are both lower than a predetermined value. The predetermined value is close to zero, ie. when only current caused by circuit imperfections flows into the lamp circuit. This error is most likely caused by the lamp not being able to light. Alternatively, there is an electrical outage in the circuit.

A number of embodiments have been described above. It is obvious to the person skilled in the art that the various detailed solutions can be modified, but where the function of the invention is maintained. therefore, the present invention is not to be construed as limited to the above embodiments, but may be varied within the scope of the appended claims.

G. \ ANSOKN95 \ 9SOJ252sc. | R.doc, 200l-05-22

Claims (15)

70 15 20 25 30 515 566 10 Patent av A method for regulating a drive unit for gas discharge lamps, where the supplied power consists of direct voltage applied to a converter stage, which is arranged to convert the direct voltage to an alternating voltage suitable for the lamp, which alternating voltage is applied to a lamp circuit comprising a lamp (2). ) and an inductor (3) connected in series with the lamp and where there is an ignition circuit (4) for the lamp, characterized in that a current measuring sensor (5) is connected in a current branch common to both the AC and DC side. ) whose output signal is used partly to generate a first control signal (13) corresponding to the power supplied to the lamp circuit, partly a second control signal (14) against the peak current of the lamp circuit, or alternatively corresponding to the reactive power present in the lamp circuit, and by (17) constituting the dominant of the (14) a third control signal first (13) and the second control signal, or alternatively a function. of these, are caused to control the power supply of the lamp in a feedback system. k ä n n e t e c k n a t Method according to claim 1, a v, that the power supplied to the drive device (1) consists of rectified alternating voltage. Method according to claim 1 or 2, characterized in that a signal processing circuit (6) is present to which the output signal of the current sensor (5) is emitted, in that the signal processing circuit is caused to form a first control signal (13) corresponding to the average value of the current, which is a measure of the power applied to the lamp, partly a second control signal (14) and of that signal processing (15) corresponding to the peak value of the current, the loop circuit (6) comprises a comparison circuit in which G '\ ANSOKN95 \ 9503252sc trdcc. 2001-05-22 respondent 70 15 20 25 30 515 566 ll. the first and the second signal, respectively, are compared, the dominant signal being used as said third control signal (17). Method according to Claim 1 or 2, characterized in that a signal processing circuit (6) is present to which the output signal of the current sensor (5) is emitted, in that the signal processing circuit is caused to form a first control signal (13) which is a measured the (19) corresponding to the average value of the current, the power supplied to the lamp, and a second control signal corresponding to the reactive power present in the lamp circuit and comprising a comparison (19) of the signal processing circuit (6) circuit (15) in which the first ( 13) and the second control signal are compared, the dominant signal being used as said third control signal (17). A method according to claim 1, 2, 3 or 4, characterized in that said converter stage comprises a (21) direct voltage to a direct voltage with a different voltage level and (23) a drawing, first converter stage which is brought to supply comprises a second converter stage which is brought converting the latter DC voltage to an alternating voltage applied to the lamp circuit and by having the current measuring sensor (5) connected in the second converter stage (23), the third control signal (17), the first conversion stage (21) is applied to a direct voltage of the desired level. to thereby convert the applied DC voltage Method according to claim 1, 2, 3 or 4, characterized in that said converter step comprises one of, converter steps (24) which are caused to convert the supplied direct voltage to an alternating voltage of the desired frequency which is applied to the lamp circuit and by the current measuring sensor ( 5) there is in- G \ ANSOKN95 \ 9S03252se u 'cloc, 2001-0512 and in that it is applied and in that the third control (26) connected in the converter stage (17) a control circuit arranged to generate (24) the signal at the frequency to which the converter stage converts the applied direct voltage. A method according to any one of claims 1 to 6, characterized in that said converter step comprises semiconductor switches (31, 32; 33, 34) and in that when the control signal corresponding to the peak current of the lamp circuit, i.e. the second (14) signal, constitutes a control signal to the said converter stage, the control signal (17) is caused to act on the semiconductor switches (31, 32; 33, 34) so that the time during which the semiconductors are in a conducting state is shortened to thereby achieve a current limitation in the lamp circuit. A method according to any one of the preceding claims, characterized in that a time and detection circuit (37) is present which is preferably activated when the lamp ignition circuit (4) is activated and in that after a predetermined time a fault condition is detected when the said the second control signal (14) is larger than the said first (13) control signal. Method according to one of Claims 1 to 8, characterized in that a time and detection circuit (37) is present which is preferably activated when the lamp ignition circuit (4) is activated and in that after a predetermined time a fault condition is detected when said first (13) and said second (14) control signal Ébàda is lower than. a predetermined value. 10. Device for regulating a drive unit for gas discharge lamps, where the supplied power consists of direct voltage which is applied to a converter stage, which is arranged to convert O. \ ANSOKN9 $ \ 9503252sc tr dOC. 2001-05-22 is brought to 70 75 20 25 30 515 566 13 the DC voltage suitable for an alternating voltage for the lamp, which alternating voltage is applied to a lamp circuit comprising a lamp (2) and an inductance (3) an ignition circuit (4) for the lamp is present characterized in that in a current branch of the drive unit (1) common to both the alternating voltage and the direct voltage side, a current measuring sensor (5) is connected arranged to emit an output signal, in that a signal processing circuit (6) is present for said output signal of the current sensor, in that the signal processing circuit (6) is arranged to form a first signal (13) corresponding to the average value of the current, which is a measure of (14) the power applied to the lamp, and a second signal corresponding to the peak value of the current, or alternatively corresponding to the reactive power present in the lamp circuit, that the signal processing circuit comprises a comparison circuit (15) arranged to compare the first (13) and the second (14) signal, respectively, wherein the generator stage (21; 26) is arranged to receive the dominant of the two signals, or alternatively a function of these, constituting a third control (17) signal as a control signal for controlling the power supply of the lamp. k ä n n e t e c k n a d An apparatus according to claim 10, wherein said converter step comprises a first converter step (21) arranged to convert applied DC voltage to a DC voltage with. another voltage level and (23) to an alternating voltage applied to the lamp circuit and comprising a second converter stage arranged to convert the latter direct current measuring sensor (5) is connected in the second (23) and by the third control signal (17) (21) the converter stage, the first conversion stage is applied to thereby convert the applied direct voltage to a direct voltage of the desired level. G. \ ANSOKN95 \ 9S03252sc.lr.doc. 2001-05-22 connected in series with the lamp and there and by '10 15 20 25 30 515 566 14, Device according to claim 10, characterized in that said converter stage comprises a converter stage (24) arranged to convert applied DC voltage to an alternating voltage of the desired frequency which is applied to the lamp circuit and in that the current measuring sensor (5) is connected in the converter stage. 24) and in that the third control signal (17) is applied to a control circuit (26) arranged to generate the frequency to which (24) the converter stage is arranged to convert the applied direct voltage. 11 or 12, (23; 24) in- 13. l3. Device according to any one of claims 10, characterized in that said converter stage comprises semiconductor switches (31,32; 33,34) and in that when the control signal which corresponds to the peak current of the lamp circuit, i.e. second signal (14), constitutes a control signal (17) to said converter stage, this is arranged to control the semiconductor switches (31,32; 33,34) so that the time during which the semiconductors are in a conducting state is shortened in order thereby to achieve a current limitation. in the lamp circuit. k ä n n e - (37) Device according to any one of the preceding claims, i.e. a time and detection circuit is provided. to be activated preferably when the ignition circuit (4) of the lamp is activated and by the fact that the time is arranged to detect a fault condition after a predetermined time when said second control signal (14) is larger than said first (13) control signal. Device according to one of Claims 10 to 14, characterized in that a time and detection circuit (37), for example, is provided. to be activated preferably when the lamp ignition circuit (4) is activated and by the fact that the time and detection circuit is arranged to detect a G '\ ANSOKN95 \ 9503252sc.lr dOC after a predetermined time. And the detection circuit condition when the first (13) and the said second (14) control signal are both lower than a predetermined value. G: \ ANSOKN95 \ 9503252sc.u'.doc, 200 | -05> 22