AT17117U1 - Operating switching with selective capacitor switching and / or switching on, depending on the operating parameters - Google Patents

Abstract

Operating circuit (BS) for supplying at least one lighting system, comprising at least one capacitor circuit (CS1) with at least two capacitors (C1, CR), starting from which the at least one lighting system (L) can be supplied directly or indirectly, and a control circuit (SS), which is set up to detect an operating parameter (P) of at least one first capacitor (C1) of the at least two capacitors (C1, CR) and, depending on the detected operating parameter (P), to control a switch element (S1) of the capacitor circuit (CS1), wherein the switch element (S1) is designed to activate at least one second capacitor (CR) of the at least two capacitors (C1, CR) as an alternative or in addition to the at least one first capacitor (C1) as a function of the control (T1).

Description

description

OPERATING CIRCUIT WITH OPERATING PARAMETER DEPENDENT SELECTIVE CAPACITOR AND / OR CONNECTION

The invention relates to an operating circuit for supplying at least one lighting system with at least one LED, and to a lamp, an operating device and / or a ballast with the operating circuit.

The starting point of the invention is that in an operating circuit for the electrical supply of a load, in particular a lighting system, certain capacitive components such as capacitors in the operating circuit, e.g. a converter circuit, can define or limit the service life of the operating circuit. This is particularly true when electrolytic capacitors (ELKOs) are used as capacitive components, the functionality and capacitive performance (nominal capacity) of which depends on the operating time, i.e. in particular the frequency and duration of the capacitor's switch-on, and / or on environmental influences (e.g. temperature fluctuations).

Typically, an operating time of, for example, 50,000 to 150,000 hours, preferably 100,000 hours, can be assumed for an electrolytic capacitor. The use of such capacitors is disadvantageous in particular because the operating circuit can become unusable overall or its function can be restricted due to a deviation of a capacitor from the nominal capacitance.

In order to increase the total operating time of the operating circuit, the solution according to the invention provides to use a capacitor circuit in the operating circuit instead of a single capacitor, in addition to at least one first capacitor at least one second capacitor is provided, alternatively or in addition to the at least a first capacitor can be activated.

Thus, an electrically conductive path can be selectively established and / or interrupted via the at least one first capacitor and / or the at least one second capacitor. In the following, the establishment of the electrically conductive path via at least one capacitor is also referred to as the operational or active switching of the capacitor. The operational switching of the capacitor takes place according to the invention in particular on the basis of a parameter detected in or on the operating circuit, which is also referred to below as an operating parameter or status parameter.

Accordingly, a first capacitor and only in a second stage a further capacitance is actively connected in parallel to this in order to achieve a total capacitance, not every time a supply voltage is switched on to reduce the so-called inrush currents (starting current). This sequential switching of the capacitance values limits the power consumption of the devices when they are switched on. According to the invention, switching on and / or switching takes place as a function of a state parameter of a capacitor or a voltage stabilized by it or detected on it.

The invention consequently provides an operating circuit, an operating device and a lamp according to the independent claims. Developments of the invention are the subject of the dependent claims.

In a first aspect, an operating circuit for supplying at least one lighting system is provided, comprising at least one capacitor circuit with at least two capacitors, starting from which the at least one lighting system can be supplied directly or indirectly, and a control circuit which is configured to set an operating parameter to detect at least one first capacitor of the at least two capacitors, and to control at least one switch element of the capacitor circuit as a function of the detected operating parameter, the switch element being designed to have at least one second capacitor of the at least two depending on the control

Activate capacitors as an alternative or in addition to the at least one first capacitor.

The switch element can activate at least one capacitor when controlled by the control circuit, and optionally deactivate at least one other capacitor at the same time.

When controlled by the control circuit, the switch element can connect at least one second capacitor in parallel to the at least first capacitor.

The operating parameter can reflect an operating time, in particular a total operating time, of at least the first capacitor and / or at least the second capacitor, the total operating time preferably being the operating time from an initial activation of the at least one first capacitor and / or the at least one second capacitor .

The operating parameter can reflect a physical parameter of the at least one first capacitor and / or of the at least one second capacitor and in particular a capacitance, preferably a residual capacitance, and / or an internal resistance.

The at least one first capacitor and / or the at least one second capacitor can stabilize a supply voltage of the at least one illuminant path.

The capacitor circuit can be a converter, in particular an AC / DC converter, a DC / DC converter, a rectifier, a clocked converter stage, in particular a flyback, buck, boost and / or buck-boost converter, for direct supply of the lighting system and / or a, preferably central, PFC circuit, preferably for a DC voltage network, be connected downstream.

The control circuit can monitor a ripple on the supply voltage, in particular a DC voltage, and in particular an increase in the ripple, preferably voltage peaks, and based on the monitoring, an impaired function of the at least one first capacitor and / or the at least one recognize second capacitor.

At least the first capacitor and / or at least the second capacitor can be an electrolytic capacitor.

In a further aspect, a lamp, a ballast, and / or an operating device with an operating circuit is provided, as described herein.

The invention will now also be described with a view to FIG.

1 shows an exemplary and schematic operating circuit BS, with at least one capacitor circuit CS1 with at least two capacitors C1, CR.

Starting from a voltage supply V, preferably an alternating voltage, at input connections E1, E2, an optional filter 10 is initially fed. The optional filter 20 can be, for example, an electromagnetic interference filter (EMI) filter. The optional filter 10 is also followed by an AC / DC converter 20, which converts an alternating voltage provided by the supply voltage V or the optional filter 10 into a direct voltage. It should be understood that, of course, a DC voltage can also be applied directly to the input connections E1, E2 of the operating circuit BS. In this case, the filter 10 and the AC / DC converter 20 can be omitted.

The AC / DC converter 20 below is now an exemplarily shown capacitor circuit CS1 connected to the at least one first capacitor C1 and / or the at least one second capacitor CR, which by means of a switch element, which is shown below as switch S1, can be operated alternately or selectively. The switch S1 is controlled via a control signal T1, the control signal T1 being able to be output in particular by a control circuit SS. The switch S1 can

connect the at least one second capacitor CR, for example by means of a switch arm, which is shown schematically in FIG. 1 by dash-dotted lines.

As is further shown in FIG. 1, the at least one first capacitor C1, which can serve, for example, as a filter or storage capacitor, is initially switched operationally. Based on a state detection and in particular the detection of a state parameter P by the control circuit SS, the control circuit SS can control the switch S1 or output the control signal T1. To this end, the control circuit SS can check whether a predefined threshold value is reached by a value of the state parameter P. If this is the case, the at least one second / redundant capacitor CR is operationally switched.

The state detection or the state parameter P, which can be evaluated by a control circuit SS of the operating circuit BS, is in particular an operating time of the at least one first capacitor C1. The state of the at least one first capacitor C1, which was initially activated or operationally switched, can be performed, for example, on the basis of a voltage ripple detected on the at least one first capacitor C1, an internal resistance of the at least one first capacitor C1 and / or a residual capacitance determined therefrom.

If the first capacitor C1 does not correctly stabilize a DC voltage VDC applied to it, i.e. in particular that a ripple on the DC voltage VDC increases, this can be detected by the control circuit SS using the state parameter P. Voltage peaks can then arise which can also damage or destroy other components of the operating circuit. Even if the at least one first capacitor C1 does not fail itself, it can happen that an incorrect functioning or a decreasing capacitance causes a failure of the operating circuit BS due to voltage peaks, with at least components of the operating circuit BS being destroyed, damaged or impaired in their function can be.

The first capacitor circuit CS $ S1 is followed by a clocked converter 30 in FIG. 1, which can be configured, for example, as a flyback, step-up converter or step-down converter (buck or boost converter) and / or a combination thereof.

The clocked converter 30 is followed by a second capacitor circuit CS2, shown as an example, which essentially corresponds to the first capacitor circuit CS1. At least one further second / redundant capacitor CR2, which can be selectively activated, is connected in parallel to at least one further first capacitor C2. The second capacitor circuit CS2 has at least one second switch element, which is shown as switch S2 and which can be controlled by a control signal T2. In this case, the at least one further first capacitor C2 or the at least one further second capacitor CR2 can be selectively switched operationally by activating the switch S2 by the control signal T2.

The second capacitor circuit CS2 is then optionally connected downstream of output terminals A1 and A2 of the operating circuit BS, a light source line L, preferably an LED.

It should be understood that the first capacitor circuit CS1 and the second capacitor circuit CS2 can each be provided exclusively but also in addition. In particular, only one of the capacitor circuits CS1, CS2 can also be provided. The operating circuit BS shown can also have additional components. For example, the capacitor circuit CS1 can be used at the output of a rectifier, at the output of a clocked converter stage (as shown in FIG. 1 for the clocked converter 30 with the second converter circuit CS? 2) or as a voltage stabilizing element in a PFC circuit (for example in a central PFC circuit for a DC voltage grid).

In particular, it should be noted that in the operating circuit BS so always at least one capacitor C1, C2 of a capacitor circuit CS1, CS2 is active and at least one second capacitor CR, CR? is switched on alternatively or additionally in order to achieve a total capacity.

The total capacitance can in particular be fed to the control circuit SS as a state parameter P, so that the control circuit SS can monitor the total capacitance. If the control circuit SS detects that one capacitor is no longer sufficient to achieve the set value for the total capacitance, it either switches alternatively to the at least one second capacitor CR, CR2 or additionally switches it to an active or operative state.

In this respect, the switch S1 and / or the switch S2 is only switched when the control circuit SS detects, for example by comparing the total current capacity or a threshold value and a measured value or the state parameter P, that the threshold value has been reached or the Value for the total capacity has fallen below.

Alternatively or additionally, the control circuit SS can also monitor an operating time of the operating circuit or at least one capacitor. For this purpose, the control circuit SS can have a timer, for example, which preferably continuously increments the state parameter P. If a threshold value for the operating time or a predetermined value of the state parameter P is then reached, the control circuit SS can also operate a redundant capacitor CR, CR2 as an alternative or in addition.

In Fig. 1, the control circuit SS is shown, which exemplarily controls the first switch S1 via the control signal T1 and the second switch S2 via the control signal T2. Of course, the control circuit SS can also only output a control signal T1 / T2 if only one capacitor circuit CS1 / CS2 is provided in the operating circuit BS. The control signal T2 is therefore shown on the control circuit SS with a dashed arrow.

Of course, more than two capacitors can also be provided in a capacitor circuit CS1, CS2, which can be operationally switched alternately or simultaneously. The switches S1, S2 used must then be adapted accordingly. In addition, instead of individual capacitors C1, C2, CR, CR2, several capacitors can also be selectively switched to active or passive, which means that capacitors of lower capacitance can be used, for example, in order to achieve the same effect with cheaper components. For example, the capacitors C1, C2, CR, CR? 2 can each be implemented by several capacitors that can be connected in parallel and / or in series.

It can also be provided that, for example after reaching a threshold value for a detected state parameter P, in particular an operating period, a switchover to another or several other capacitors CR, CR? 2 takes place and when a further threshold value for the state parameter P or of a further state parameter P '(shown in FIG. 1 with a dashed arrow), switching back to the first capacitor C1, C2 takes place. This cyclical switching between capacitors or groups of capacitors is particularly advantageous because it prevents the capacitors from drying out, especially when using electrolytic capacitors.

Even when only two capacitors C1 / C2, CR / CR2 are used in a capacitor circuit CS1, CS2, one of the capacitors being provided as a second or as a redundant capacitor CR, CR2, cost savings can be achieved in that a higher Lifetime is achieved by combining the lifetimes of the at least two capacitors.

The switches S1, S2 can generally be designed as switch elements, in particular as transistors, and preferably as bipolar and / or field effect transistors (FET, MOSFET, ...). The control circuit SS can be designed as an integrated circuit (IC), application-specific integrated circuit (ASIC), and / or as a microcontroller (uC). The state parameter P and / or the further state parameter P 'can be fed to the control circuit from outside, i.e. from outside the operating circuit BS, or it can be detected in the operating circuit BS.

If the operating circuit BS is part of an operating device, a ballast, a lamp and / or a building technology device, the at least one state parameter

P, P 'can also be recorded on / in other circuit parts of the ballast, the luminaire and / or the building technology device, or can be retrieved from external memories. The control circuit SS preferably has a data memory for storing recorded and / or retrieved values and / or the threshold values or is functionally connected to such a data memory.

Essentially, each capacitor of a circuit can be replaced by a capacitor circuit CS1 in order to increase the service life of the circuit.

Claims (10)

Expectations 1. Operating circuit (BS) for supplying at least one lighting system, comprising at least one capacitor circuit (CS1) with at least two capacitors (C1, CR), starting from which the at least one lighting system (L) can be supplied directly or indirectly, and a control circuit (SS ), which is set up to detect an operating parameter (P) of at least one first capacitor (C1) of the at least two capacitors (C1, CR) and, depending on the detected operating parameter (P), a switch element (S1) of the capacitor circuit (CS1) the switch element (S1) is designed to activate at least one second capacitor (CR) of the at least two capacitors (C1, CR) as an alternative or in addition to the at least one first capacitor (C1) as a function of the control (T1) . 2. Operating circuit (BS) according to claim 1, wherein the switch element (S1) when activated (T1) by the control circuit (SS) activates the at least one second capacitor (CR), and at the same time deactivates the at least one first capacitor (C1). 3. Operating circuit (BS) according to claim 1 or 2, wherein the switch element switches the at least one second capacitor (CR) to the at least one first capacitor (C1) in parallel when controlled (T1) by the control circuit (SS). 4. Operating circuit (BS) according to one of the preceding claims, wherein the operating parameter (P) reflects an operating time, in particular a total operating time, of at least the first capacitor and / or at least the second capacitor, the total operating time preferably the operating time from an initial activation of the at least a first capacitor (C1) and / or the at least one second capacitor (CR). 5. Operating circuit (BS) according to one of the preceding claims, wherein the operating parameter (P) reflects a physical parameter of the at least one first capacitor (C1) and / or of the at least one second capacitor (CR) and in particular a capacitance, preferably a residual capacitance, and / or an internal resistance. 6. Operating circuit (BS) according to one of the preceding claims, wherein the at least one first capacitor (C1) and / or the at least one second capacitor (CR) is set up to stabilize a supply voltage (VDC) of the at least one illuminant line (L) . 7. Operating circuit (BS) according to one of the preceding claims, wherein the capacitor circuit (CS1) has a converter, in particular an AC / DC converter (30), a DC / DC converter, a Gileichrichter, a clocked converter stage, in particular a flyback, buck -, Boost and / or Buck-Boost converter, preferably for the direct supply of the lighting system and / or a, preferably central, PFC circuit, preferably for a DC voltage network, is connected downstream. 8. Operating circuit (BS) according to one of the preceding claims, wherein the control circuit (SS) is set up to monitor a ripple on the supply voltage, in particular a DC voltage, and in particular an increase in the ripple, preferably voltage peaks, and based on the monitoring to recognize an impaired function of at least the at least one first capacitor (CS1) and / or the at least one second capacitor (CS2). 9. Operating circuit (BS) according to one of the preceding claims, wherein the at least one first capacitor (C1) and / or the at least one second capacitor (CR) is an electrolytic capacitor. 10. Light or operating device with an operating circuit according to one of the preceding claims. 1 sheet of drawings