DE19649788A1 - Measuring device for a loaded DC converter - Google Patents

Abstract

The present invention pertains to a measuring instrument for a loaded dc/dc converter which converts an input potential (13), based on a reference potential (12), into two output potentials different from the reference potential (12). The output potentials can be harnessed at load connectors (21, 22). A load (20) crossed by an output current (23) acts as a linkage between both load connectors (21, 22). The output current (23) is harnessed as follows: a current (14) flowing into the dc/dc converter (10) against the reference potential (12) is recorded as a measure (25) of the output current (23) as compared with the reference potential.

Description

State of the art

The invention relates to a measuring device for a loaded DC converter according to the genus of Main claim

From DE-OS 41 29 557 is a lighting circuit for known a vehicle discharge lamp, in which a DC boost circuit from a battery is fed. The voltage thus increased is the input variable for a high-frequency booster circuit, which has a Ignition circuit supplies the discharge lamp. The Booster circuit is as switched DC converter built, one of the two Output terminals are at the same input potential, namely on mass. The output current of the Booster circuit is via a Current measuring resistance detected in the ground line is arranged. The voltage drop across the measuring resistor is proportional to the output current and to ground.

However, one of the output terminals is on top of another Potential as mass, can be measured with this arrangement no measurement voltage received, inherently on ground is related. The invention is based on the object easy to process signal for the output current  to get a DC converter, both of which Output terminals are at different potentials than that Reference potential. The task is carried out by the in the Independent claim specified features solved.

Advantages of the invention

The measuring device according to the invention for a loaded DC voltage converter has the advantage that with generates a signal with low circuit complexity which is a measure of the potential Output current of the DC-DC converter is. On one elaborate reference to mass, as used in current measurements in the Output lines would be required, can be dispensed with will. The measurement signal obtained in this way can, for example without complex further processing of a current control respectively. In addition, the benefits that a bipolar output voltage of a DC-DC converter with brings, be used. For example, a higher efficiency can be achieved. The requirements for electrical components can withstand voltage also decrease because of the tension can be divided cheaply.

By those listed in the dependent claims Measures are advantageous developments of device according to the invention possible. In a advantageous training is the against that Reference potential flowing current through a resistor detected. The voltage thus obtained is proportional to Output current of the DC converter and on that Reference potential related. It is a suitable one Input variable for a control circuit.  

According to an expedient development of the invention Device is a capacitor in parallel with the measuring resistor switched to bridge the dynamic current pulses. The higher frequencies occurring in clocked operation Parts of the reference potential-related measurement signal are not more layered. The AC component of the against that Reference potential flowing measuring current is no longer at Measuring resistor on.

Further appropriate training from other dependent Claims emerge from the description.

As embodiments of the invention Figure 1 a schematic circuit diagram as well as possible in the Figs. 2 and 3 circuits are shown in Fig..

Description of the embodiments

A DC voltage converter 10 has, as an input variable, an input voltage 13 which is present at an input terminal 11 with respect to a reference potential 12 . A current 14 flows in the DC / DC converter 10 against the reference potential 12 . The DC-DC converter 10 delivers an output current 23 as an output quantity , which flows through a load 20 between a first output terminal 21 and a second output terminal 22 . As a further output variable, the DC-DC converter 10 supplies a measuring voltage 25 which is related to the reference potential 12 .

The DC-DC converter 10 of FIG. 2 applies a primary winding 33 of a transformer 29 which referred to the reference potential 12 input voltage 13. At the common potential of the primary winding 33 and the circuit breaker 32 , both a first smoothing capacitor 38 connected to a second reference potential 40 and the first output terminal 21 are supplied via a first diode 36 . One connection of a secondary winding 35 of the transformer 29 is connected via a second diode 37 to the reference potential 12 and a second connection of the secondary winding 35 both to the second output terminal 22 and to a second smoothing capacitor 39 connected to the reference potential 12 . The measuring current 14 flowing through the second diode 37 is detected by a measuring resistor 30 , to which a capacitor 31 is connected in parallel. Measuring resistor 30 and capacitor 31 are arranged between the second diode 37 and the reference potential 12 . The output variables and the corresponding circuitry correspond to FIG. 1.

The DC-DC converter 10 of FIG. 3 is constructed such that a first winding of a transformer 41 is applied 29 via a clocked power switch 32, referred to the reference potential 12 input voltage 13. Here, a first connection of a second winding 42 of the transformer 29 is at the common potential of the first winding 41 and the circuit breaker 32 . A second connection of the second winding 42 supplies, via a first diode 36, both a first smoothing capacitor 38 connected to a second reference potential 40 and the first output terminal 21 . A first connection of a third winding 43 of the transformer 29 is connected to the reference potential 12 via a second diode 37 , and a second connection of the third winding 43 is connected both to the second output terminal 22 and to a second smoothing capacitor 39 connected against the reference potential 12 . A series capacitor 44 is connected between the first connection of the third winding 43 and the second connection of the second winding 42 . To detect the current 14 flowing through the second diode 37 , the measuring resistor 30 is connected between this second diode 37 and the reference potential 12 , to which a capacitor 31 is connected in parallel. The output variables and the wiring correspond to FIG. 1.

The exemplary embodiments of the device according to the invention work for a loaded DC converter as follows:

The DC-DC converter 10 converts an input voltage 13 related to the reference potential 12 into two output potentials, which can be tapped at the output terminals 21 , 22 . The input voltage 13 supplies, for example, a battery, ground 12 being used as the reference potential.

Basic circuit arrangements of the DC / DC converter 10 are known. With clocked voltage transformers, energy is stored in a component for the purpose of increasing or reducing the voltage. The required voltage conversion is achieved by appropriate connection and dimensioning of the components.

The load 20 is connected between the two output terminals 21 , 22 . For example, a gas discharge lamp arranged in a motor vehicle serves as load 20 . The DC / DC converter 10 supplies both an ignition and a control circuit. The load 20 is not connected to the reference potential 12 .

As a further output variable, the DC-DC converter 10 supplies a measuring voltage 25 which is related to the reference potential 12 . This measuring voltage 25 represents a measure of the output current 23 which flows through the load 20 . The measuring voltage 20 is obtained by detecting a current 14 flowing against the reference potential 12 .

The circuit arrangement according to FIG. 2 is based in principle on a bipolar flyback converter. The energy transmission takes place through the transformer 29 , which is formed by the primary winding 33 and the secondary winding 35 . This transformer 39 is clocked on the primary side via the circuit breaker 32 . A power MOS transistor, for example, is suitable as the power switch 32 . The bipolar flyback converter according to FIG. 2 differs from a conventional flyback converter in that the first output terminal 21 is supplied via the first diode 36 on the primary side. The load 20 is supplied with energy when the circuit breaker 32 is open. When the circuit breaker 32 is closed, the transformer 29 acts as an intermediate store, that is to say it charges itself with magnetic energy.

When the circuit breaker 32 is closed, the input voltage 13 is present on the primary winding 33 . The current flowing through the primary winding 33 induces a voltage on the secondary winding 35 . The polarity of the secondary winding 35 is such that the second diode 37 is polarized in the reverse direction at this time. Thus, no current 14 flows against the reference potential 12 while the circuit breaker 32 is closed. The current flowing through the primary winding 33 flows against the reference potential 12 , so that the load 20 is not energized via the first diode 36 .

If the circuit breaker 32 is opened, the voltage induced on the secondary winding 35 changes its polarity and builds up. The second diode 37 is thus operated in the forward direction, which is why a pulsating direct current can flow through it. On the primary side, the load 20 is supplied with the output current 23 via the first diode 36 . The first smoothing capacitor 38 filters out the higher-frequency AC components, so that a DC current flows in the load 20 .

The current 14 flowing through the second diode 37 during this phase is thus a measure of the output current 23 flowing through the load 20 . Because of the desired reference potential reference, however, it is not the output current 23 that is detected directly via a measuring resistor, but rather the current 14 flowing through the second diode 37 . The measuring resistor 30 , which is connected between the second diode 37 and the reference potential 12 , is used for this purpose. The measuring resistor 30 should be chosen to have a low resistance in order to avoid unnecessary losses. Its value is in the upper milliohm range, for example 100 mΩ. The capacitor 31 connected in parallel with the measuring resistor 30 bridges the measuring resistor 30 for pulsating DC components. Thus, only the DC component of the current 14 is detected by the measuring resistor 30 . The measuring voltage 25 dropping across the measuring resistor 30 is thus a reference potential-related measure for the output current 23 . The capacitance 31 is to be selected, for example, in the micro farad range.

It would also be conceivable if the current flowing in the line lying at reference potential 12 is detected as current 14 . The measuring resistor 30 is to be arranged, for example, between the circuit breaker 32 and the diode 37 .

The circuit arrangement shown in FIG. 3 has a similar arrangement to that described above. It differs in that the first winding 41 is followed by the second winding 42 , which is connected to the third winding 43 via the series capacitor 44 . In principle, the circuit arrangement according to FIG. 3 works like a conventional flyback converter, which means that the load 20 is supplied with energy when the circuit breaker 32 is open. The series capacitor 44 is charged when the circuit breaker 32 is open, as a result of which a potential difference between the second winding 42 and the third winding 43 arises. When the circuit breaker 32 is closed, a current flows against the reference potential 12 through the first winding 41 . No current flows through the second diode 36 when the circuit breaker 32 is closed, since the diode is polarized in the reverse direction. When the circuit breaker 32 is closed, the second smoothing capacitor 39 and the series capacitor 44 are virtually parallel. The energy stored in the series capacitor 44 is transferred to the second series capacitor 39 . The output current 23 flows into the capacitors 38 , 39 , 44 during this time.

When the circuit breaker 32 is open, the polarities of the windings 41 , 42 , 43 change . In this way, a voltage builds up on the third winding 43 , whereupon the second diode 37 becomes conductive. An output current 23 flows through the load 20 via the first diode 36 , and the current 14 flows through the second diode 37 against the reference potential 12 . At the same time, the series capacitor 44 is charged. The charging current flows through the second diode 37 .

When the circuit breaker 32 is open, magnetic energy is transmitted. The voltage drop across the third winding 43 charges the second smoothing capacitor 39 .

The windings 41 , 42 , 43 must be well coupled for this. The number of turns of the first winding 41 and the second winding 42 should together give the number of turns of the third winding 43 .

The capacitance of the series capacitor 44 depends on the dimensioning of the on and off times of the circuit breaker 32 , because in the switched-on state the series capacitor 44 is connected in parallel with the second smoothing capacitor 39 and thus energy is transmitted.

The current 14 flowing through the second diode 37 is also detected by the measuring resistor 30 , to which the capacitor 31 is connected in parallel, analogously to the circuit arrangement according to FIG. 2. The measuring voltage 25 thus obtained is related to the reference potential 12 .

It is also conceivable if the current flowing in the line at reference potential 12 is detected as current 14 . The measuring resistor 30 is to be arranged, for example, between the circuit breaker 32 and the diode 37 .

The reference potential-related measuring principle is not restricted to the circuit arrangements according to FIG. 2 or 3. For example, the tap that supplies the first diode 36 , among other things, could take place between the first and second windings 41 , 42 . The measuring device is also not limited to flyback converters, so that, for example, forward converters or other known direct voltage converters, which supply 12 different output potentials from the reference potential, can also be equipped with this measuring method.

Claims (8)

1. Measuring device for a loaded DC converter ( 10 ), which converts an input voltage ( 13 ) related to a reference potential ( 12 ) into at least two output potentials different from the reference potential ( 12 ), which can be tapped at output terminals ( 21 , 22 ), one Load ( 20 ) through which an output current ( 23 ) flows, connects the output terminals ( 21 , 22 ) and this output current ( 23 ) is detected, characterized in that a current flowing in the DC-DC converter ( 10 ) against the reference potential ( 12 ) ( 14 ) is recorded as a reference-related measure ( 25 ) for the output current ( 23 ) 2. Apparatus according to claim 1, characterized in that the current ( 14 ) flowing against the reference potential ( 12 ) is detected via a measuring resistor ( 30 ). 3. Apparatus according to claim 2, characterized in that the measuring resistor ( 30 ), a capacitor ( 31 ) is connected in parallel to bridge the dynamic current pulses. 4. Device according to one of the preceding claims, characterized in that to a primary winding ( 33 ) of a transformer ( 29 ) via a clocked power switch ( 32 ) is applied to the reference potential ( 12 ) related input voltage ( 13 ) that at the common Potential of the primary winding ( 33 ) and the circuit breaker ( 32 ) is supplied via a first diode ( 36 ) to both a first smoothing capacitor ( 38 ) connected to a second reference potential ( 40 ) and the first output terminal ( 21 ) that a first connection of a secondary winding ( 35 ) of the transformer ( 29 ) via a second diode ( 37 ) with the reference potential ( 12 ) and a second connection of the secondary winding ( 35 ) both with the second output terminal ( 22 ) and with a second one connected to the reference potential ( 12 ) Smoothing capacitor ( 39 ) are connected. 5. Device according to one of the preceding claims 1 to 3, characterized in that the input voltage ( 13 ) related to the reference potential ( 12 ) is applied to a first winding ( 41 ) of a transformer ( 29 ) via a clocked power switch ( 32 ), that a first connection of a second winding ( 42 ) of the transformer ( 29 ) is at the common potential of the first winding ( 41 ) and the circuit breaker ( 32 ), while a second connection of the second winding ( 42 ) via a first diode ( 36 ) Both a first smoothing capacitor ( 38 ) connected to a second reference potential ( 40 ) and the first output terminal ( 21 ) ensure that a first connection of a third winding ( 43 ) of the transformer ( 29 ) via a second diode ( 37 ) with the reference potential ( 12 ) and a second connection of the third winding ( 43 ) both with the second output terminal ( 22 ) and with one against the reference potential ( 12 ) connected second smoothing capacitor ( 39 ) and that a series capacitor ( 44 ) is connected between the first connection of the third winding ( 43 ) and the second connection of the second winding ( 42 ). 6. Device according to one of claims 4 or 5, characterized in that the measuring resistor ( 30 ), in parallel with the capacitor ( 31 ), connects the second diode ( 37 ) to the reference potential ( 12 ). 7. Device according to one of claims 4 or 5, characterized in that the measuring resistor ( 30 ), in parallel with the capacitor ( 31 ), is connected between the second diode ( 37 ) and the circuit breaker ( 32 ). 8. Device according to one of the preceding claims, characterized by the use at a Gas discharge lamp.