WO2020070092A1 - Power supply having overcurrent capability - Google Patents

Abstract

The invention relates to a power supply (1) comprising: a converter unit (3) for providing an output power at the output of the power supply (1) by converting an input power at the input (2) of the power supply (1); and a detection unit (6) for detecting an event. The power supply (1) is designed to change the output power if an event triggering the change is detected. The power supply (1) is designed to variably adjust a boost output power and/or a boost intermediate time for providing the boost output power at the output of the power supply (1).

Description

 POWER SUPPLY WITH OVERCURRENT CAPABILITY

The invention relates to a power supply unit, such as a switched-mode power supply unit, with a converter unit for providing an output power at the output of the power supply unit by converting an input power at the input of the power supply unit and with a detection unit for detecting an event, the power supply unit being used for Change the output power is set up when an event triggering the change is detected.

Power supplies are devices for supplying energy by providing an output power that has a different output voltage and / or a different output current than is provided at the input of the power supply. The output voltage can be fixed and the output current can be limited to a maximum value. Such power supplies, in particular switched-mode power supplies, can be designed to supply a regulated direct voltage or a regulated direct current and to regulate the output power in the event of a fault, for example in the event of a short circuit. In the event of a malfunction, for example in the event of a short circuit, passive transformer power supplies provide an output current that is far above the nominal current, and which can be used to safely trip a downstream circuit breaker. When using switched-mode switching power supplies, however, the output current is limited to a value in the range of the nominal current, so that a downstream circuit breaker can no longer be tripped safely, as this usually causes a short-circuit current for a voltage that is far above the nominal current Tripping time required. There is therefore a risk that a faulty load circuit will be thermally overloaded. Power supplies are therefore available that have a short-term overcurrent capability in order to provide a predetermined higher boost output current than the actual nominal current for a fixed boost intermediate time in the event of a fault. The intermediate boost and the boost output current are dimensioned so that a circuit breaker trips safely and switches off a faulty load circuit.

The switching power supplies must then be regulated to the higher specified boost output current in order to ensure that the power supply still has sufficient thermal reserve at a maximum ambient temperature, continuous rated operation and the feeding in of a specified minimum value for the input voltage to deliver a temporary overcurrent (boost) without getting into the thermal shutdown.

DE 10 2005 031 833 B4 discloses such an electronic power supply device for supplying energy to a low-voltage load with a transformer, a device for detecting an electrical fault and a device assigned to the detection device for limiting the output current of the device to a first predetermined one Value. In response to the detection of an electrical fault, the output current is set for a predetermined time to a second predetermined value which is greater than the first predetermined value. This second predetermined value for the output current is set such that a protective device assigned to the device can be triggered safely. After a predetermined time has elapsed, the output current through the limiting device is limited to the first predetermined value.

Based on this, it is an object of the present invention to provide an improved power supply, in particular a switching power supply.

The problem is solved with the power supply with the features of claim 1. Advantageous embodiments are described in the subclaims. It is proposed that the power supply unit be designed for the variable setting of a boost output power and / or a boost intermediate time for the provision of the boost output power at the output of the power supply unit.

The level of the boost output power, such as, for example, the level of the output current, the output voltage and / or the time profile, for example by clocking the output power profile, is therefore not fixed, but is set variably. This ensures that the power supply is not overloaded by the boost output and can still be used optimally depending on the existing operating situation.

The power supply unit with a converter unit for providing an output power at the output of the power supply unit by converting an input power at the input of the power supply unit and with a detection unit for detecting an event can be set up to change the output power to a boost output power for the duration of the boost intermediate time if an event triggering the change is detected in order to provide the boost output power at the output of the power supply. The power supply unit can be set up to regulate the output power of the power supply unit to the nominal power or below the nominal power after the output power has been changed to the boost output power for the intermediate boost period. The power supply unit can be designed to vary the variably adjustable boost output power during the intermediate boost after the detection of an event triggering the change and before the output power is reduced to the rated power or below the rated power. The boost intermediate time is defined in such a way that it begins with the detection of the event triggering the change and ends with the first end of the provision of an increased boost output power, ie with the end, for example, of a temporary increase in the current limit to an increased maximum value that is above a current permissible current value as a limit. The intermediate boost ends as soon as the temporarily increased output power is no longer provided and the output power is again limited to a regular output power or beyond. The power supply unit can be set up to record an influencing variable in order to control the boost output power and / or the boost intermediate time by means of the influencing variable. The variable setting of the boost output power and / or the boost intermediate time takes place depending on the at least one recorded influence. The boost output power can thus be adapted, for example, to the specific operating point of the power supply that the power supply has at the time of detection of an event that triggers the change in the output power. In this way, the power reserves of the power supply unit can be used in the best possible way.

The power pack can have a temperature sensor for detecting the temperature of the power pack and / or the ambient temperature on the power pack. It can be set up as an influencing variable for setting the boost output power and / or the boost intermediate time depending on the detected operating and / or ambient temperature.

This means that the provision of the boost output power is matched to the current operating point of the power supply, which can be determined by the temperature. A thermal load on the power supply can be counteracted by the fact that the boost output power and / or the boost intermediate time is lower at a higher temperature than at a lower temperature.

The power supply unit can be set up as an influencing variable for detecting the electrical load at the output of the power supply unit and for setting the boost output power and / or the boost intermediate time as a function of the detected electrical load.

The electrical load at the output of the power pack can be determined, for example, by the output current. However, the output voltage can also be measured to determine an overload, which despite a constant voltage control leads to a reduction in the output voltage if the power supply unit can no longer provide the required constant voltage.

The detected electrical load is then a measure of the current operating point of the power supply, which is used to determine the boost output power and / or the intermediate boost time. The power supply unit can be set up as an influencing variable for detecting the level of the input voltage at the input of the power supply unit and for setting the boost output power and / or intermediate boost depending on the detected level of the input voltage. The input voltage at the input of the power supply is also a feature which determines the operating point of the power supply and can be used to determine the boost output power and / or boost intermediate time.

The power supply unit can be set up for recording operating parameters of electronic components of the power supply unit and for setting the boost output power and / or the intermediate boost time as a function of the recorded operating parameters of electronic components of the power supply unit. By monitoring operating parameters of at least one electronic component of the power supply, a feature for the operating point of the power supply can also be determined, which is used to determine the boost output power and / or the intermediate boost.

By taking such features into account for the current operating point of the power supply unit, it can be achieved that the power supply unit delivers a sufficient boost output power for a sufficient time without the power supply unit being overloaded.

In particular, the output power of the power supply unit can be increased via the nominal output power during the boost interval, in order to ensure, for example, briefly a higher output current than the nominal current for switching off a circuit breaker interacting with the power supply unit.

The power supply unit can be designed to vary the boost output power during the intermediate boost after the detection of an event triggering the change. The boost output power is thus not set to a constant value during the boost interval, but can vary during the boost interval. It is conceivable that the boost output power drops linearly or non-linearly, for example by lowering the boat output current. The boost output power can go from a maximum value to a nominal value or to fall above or below the nominal value. The change course for varying the boost output power can be an influencing variable preset in the power supply unit or supplied to the power supply unit from the outside.

The power supply unit can be set up for randomly setting the boost output power and / or boost intermediate time. A random generator, for example, is used as an influencing variable.

It is conceivable that the power supply unit has a signal generator for providing an alternating signal. Then the random setting of the boost output power and / or the intermediate boost time depends on the time of detection of the event triggering the regulation and the signal state of the alternating signal at this detection time and the following signal curve. The boost output power can then be varied as a function of this subsequent signal profile of the alternating signal. The intermediate boost can also depend on the alternating signal and can end when a predetermined signal level of the alternating signal is reached.

The power supply unit can be set up to set the output current and / or the output voltage and / or the current-time profile and / or the voltage-time profile of the boost output power. One or more of the aforementioned sizes can be set individually or in combination. The sizes not set can be kept constant. It is therefore advantageous if, in the case of a constant current source, the output current is regulated during the boost period to a boost output current which is set as a function of an influencing variable. However, it is also conceivable that the current and / or voltage-time profile of the boost output power is set, for example, by temporarily blanking out a signal or changing the frequency in the power supply unit.

The power supply unit can be set up to control the output power for the boost intermediate time after the output power has been regulated to the boost output Regulate the power supply to the nominal power or even to a value below the nominal power, which may include completely switching off the power supply. The variable setting of the boost output power and / or the boost intermediate time can take place automatically, ie without user intervention.

The setting of the boost output power and / or the intermediate boost time can depend on a higher-level energy management control center. If a plurality of power supply units is connected, it is conceivable that several power supply units simultaneously activate the boost functionality, which can lead, for example, to energy bottlenecks and / or the triggering of a central fuse. The variable setting of the boost output power and / or the boost intermediate time can be coordinated by a higher-level energy management control center in order to avoid undesirable effects caused by simultaneous boost events

To prevent power supplies. The higher-level energy management control center can limit the boost function to a selected power supply unit, for example, if it is requested by several power supply units. It is conceivable that the variable setting of the boost output power and / or the intermediate boost in a power supply unit only takes place when the power supply unit transmits a release request to the higher-level energy management control center and a release from the higher-level energy management control center has received.

The invention is explained in more detail below on the basis of an exemplary embodiment with the accompanying drawings. Show it:

Figure 1 - block diagram of a power supply with a control unit for variable

 Setting a boost output power;

 Figure 2 - Time course of the output current of the power supply with a variably set boost output current during an intermediate boost;

 FIG. 3 - time profile of the output current of the power supply unit for another profile of the boost output current during an intermediate boost; Figure 4 - Diagram of the output current of the power supply with variable boost

Output current during two different boost intermediate times depending on an alternating signal.

FIG. 1 shows a block diagram of a power supply unit 1, which can be designed, for example, as a switching power supply. A switched-mode power supply has a rectifier on the input side, possibly with a line filter and smoothing capacitors for interference suppression and sieving of the input power, and a subsequent switching unit with power transistors for generating a switched voltage at an intermediate frequency, which is fed into a subsequent power transformer. The output power of the power transformer is then fed to a rectifier for rectification and screening in order to provide a DC voltage at the output of the power supply unit, preferably with a constant output voltage and a limitation to a maximum output current. However, a constant current source with provision of a constant output current and variable output voltage, which is limited to a maximum voltage value, or the like, is also conceivable.

Such a switched-mode power supply also has a control unit for controlling the switching unit in order to keep the output power within predetermined limit values.

With such a known circuit arrangement, for example, an output power is provided at the output of the power supply unit 1 by converting an input power at the input 2 of the power supply unit 1. Such electronics is shown in summary in FIG. 1 as converter unit 3. The specific circuit structure is not important here. Other configurations of the converter unit 3 are also conceivable than the above-described basic, exemplary construction for a switching power supply.

The power supply unit 1 also has a control unit 4, which is connected downstream of the converter unit 3, for example, and is designed for variable setting of a boost output power for a boost intermediate time at the output of the power supply unit 1. A load 5 is connected to the output of the power supply 1. Due to a temporary or persistent overload or in the event of a short circuit, the power requested by the power supply unit 1 can lead to an overload of the power supply unit 1. It is conceivable that such an overload results in a thermal overload of the power supply 1. However, an overload due to a short circuit at the output of the power supply 1 is also conceivable, which requires the power supply 1 to be curtailed.

The converter unit 3 is set up regularly to react to such load changes in the load 5 connected to the output of the power supply unit 1 or to fluctuations in the input 2 of the power supply unit 1.

The power supply unit 1 has a detection unit 6 for detecting an event that is to trigger a change in the output power of the power supply unit 1. For this purpose, the detection unit 6 is connected to the control unit 4 in order to transmit a detected event to the control unit 4 and to cause the control unit 4 to change the output power of the power supply unit 1.

To this end, the power supply unit in this exemplary embodiment shown is set up, for example, by the control unit 4 in order to variably set the output power of the power supply unit 1. After detection of an event by the detection unit 6, the output power of the power supply unit 1 is briefly increased to a boost output power for a brief interim boost in order to provide sufficient current to trigger power protection devices subsequently connected to the power supply unit 1 , which is above the rated current of the power supply 1. However, other settings for the boost output power are also conceivable. The boost output power and / or the intermediate boost time are not predefined here, but are set variably with the control unit 4 as a function of an influencing variable.

For this purpose, the control unit 4 can be connected, for example, to a temperature sensor 7, which measures the operating temperature of the power supply and / or the ambient temperature in the vicinity of the power supply 1. It is also conceivable that several temperature sensors 7 are present, for example for measuring the operating temperature in the interior of the power supply and for measuring the ambient temperature in the exterior of the power supply 1. The at least one recorded temperature value then serves as an influencing variable in order to determine the boost output power and / or the intermediate boost time. This means that the boost output or intermediate boost can be set lower at a higher temperature than at a lower temperature. A high temperature signals a working point of the power supply 1 at which there is only little heat capacity until the power supply 1 is overloaded. In order not to overload the power supply unit 1, the additional power demanded by the power supply unit 1 by changing the output power is set to a level that is adapted to the current operating point of the power supply unit 1.

An important feature for the operating point of the power supply 1 is the temperature. However, further features can also be the utilization of the power supply unit 1 and the level of the input voltage, as well as the ambient temperature. However, these features are reflected in the result in the operating temperature of the power supply unit 1 itself, so that the detection of the operating temperature of the power supply unit 1 with a single temperature sensor 7 is sufficient in itself to variably adapt the boost output power and / or the boost intermediate time at the operating point of the power supply 1.

The power supply unit 1 can optionally have a signal generator 8 for generating an alternating signal or a random signal. It is conceivable in this variant that the setting of the boost output power and / or the intermediate boost time is random is set. This ensures statistically that overloading of the power supply 1 is largely prevented. The alternating signal then serves as an influencing variable for the variable setting of the boost output power and / or boost intermediate time.

FIG. 2 shows a diagram of the output current I in the unit Ampere A over the time t in seconds. It can be seen that the output current I is initially regulated to the nominal current I NENN. After an event triggering a change in the output current is detected, a boost intermediate time begins. During this period, the boost output current I and thus the boost output power are changed. In the exemplary embodiment shown, the output current I initially rises to a maximum value IMAX and is then linearly reduced to the nominal value I NENN until the end of the boost intermediate time tßoosT. The boost output power is therefore not set to a fixed value, but variable by regulating the output current. This can prevent the power supply 1 from being overloaded.

Figure 3 shows a diagram of the output current I of the power supply 1 over time t. The boost output current during the boost intermediate time tßoosT is linearly reduced from a defined maximum value I MAX during the boost intermediate time to a value that results from the boost intermediate time and the steepness of the characteristic curve of the boost output current . In contrast to the variant in FIG. 2, the output power of the power supply unit 1 does not have to be in the range of the nominal current INENN again at the end of the boost intermediate time, but can be above or below it if necessary. After the boost output power has expired, the output current I of the power supply unit 1 can be regulated again to the nominal current I NENN.

FIG. 4 shows a diagram of the output current I of the power supply unit 1 in ampere A over the time t in seconds with two events for changing the output power I which are detected in succession. It can be seen that a signal S (t) alternating over the time t is present is. This signal S (t) can have the shape of a sawtooth curve, for example. Other regular, irregular or even random curve shapes are also conceivable. It becomes clear that after the detection of an event, a boost intermediate time tßoosTj, tßoosT_2 starts. The output current I of the power supply 1 is then adapted in accordance with the following waveforms of the alternating signal S (t) until the alternating signal S (t) assumes a characteristic value which signals the end of the boost intermediate time tßoosT. For example, in the case of the sawtooth curve, this can be the falling edge back to the starting point, which is assumed as the value for the nominal current I NENN.

It can be seen that for the second event, the beginning of the boost intermediate time tßoosT2 falls in a time of the alternating signal S (t) at which the alternating signal S (t) increased more than in the first event and fell closer to the loin edge is considered to be the first event with the boost split timer.

As a result, the boost interval tßoosT2 for the second event is shorter than in the first event outlined. The amplitude of the output current I follows the curve shape, starting from the output value at the beginning of the boost intermediate time tßoosT, without being dependent on its amplitude.

However, it is also conceivable that the output current I is set as a function of the amplitude of the alternating signal S (t) during the boost intermediate time tßoosT. Then the output current I for the first event in the boost intermediate time tßoosTj would first make a small jump starting from the nominal current I NENN. For the second event for the boost intermediate tßoosT_2, the amplitude of the output current I would have a significantly larger increase at the beginning of the boost intermediate. This not only determines the boost intermediate time tßoosT variable and randomly depending on the time of detection of an event and the associated time in the curve of the alternating signal S (t). Rather, the boost output power, such as the boost output current in the present case, is then determined variably and randomly as a function of the curve shape of the alternating signal S (t) and of the time of detection of an event in the curve shape.

Claims

Claims

1. Power supply unit (1) with a converter unit (3) for providing an output power at the output (2) of the power supply unit (1) by converting an input power at the input of the power supply unit (1) and with a detection unit (6) for de - detection of an event, the power supply unit (1) being set up to change the output power when an event triggering the change is detected,

 characterized in that

 the power supply unit (1) is designed for the variable setting of a boost output power and / or a boost intermediate time for providing the boost output power at the output of the power supply unit (1).

2. Power supply unit (1) with a converter unit (3) for providing an output power at the output (2) of the power supply unit (1) by converting an input power at the input of the power supply unit (1) and with a detection unit (6) for de - Detection of an event, the power supply unit (1) being set up to change the output power to a boost output power for the duration of a boost intermediate time when an event triggering the change is detected by the boost output power at the output of the power supply unit (1), and the power supply unit (1) is set up to regulate the output power of the power supply unit (1) to the nominal power or below the nominal power after the change in the output power to the boost output power for the intermediate boost , characterized in that the power supply unit (1) for varying the variably adjustable boost output power during the boost interval triggers the change after the detection event and before the output power is reduced to the nominal power.

3. Power supply (1) according to claim 1 or 2, characterized in that the power supply (1) has a temperature sensor (7) for detecting the temperature of the power supply (1) or the ambient temperature on the power supply (1) and for setting the boost Output power and / or intermediate boost depending on the detected operating and / or ambient temperature is set up as an influencing variable for the variable setting.

4. Power supply (1) according to claim 1, 2 or 3, characterized in that the

 Power supply unit (1) for detecting the electrical load at the output of the power supply unit (1) and for setting the boost output power and / or intermediate boost time is set up as an influencing variable for variable setting as a function of the detected electrical load.

5. Power supply unit (1) according to one of the preceding claims, characterized in that the power supply unit (1) for detecting the level of the input voltage at the input of the power supply unit (1) and for setting the boost output power and / or the intermediate boost time is set up as an influencing variable for variable setting depending on the input voltage detected.

6. Power supply unit (1) according to one of the preceding claims, characterized in that the power supply unit for detecting operating parameters of electronic components of the power supply unit (1) and for setting the boost output power and / or intermediate boost time as a function of the detected operating parameters - Meters is set up as an influencing variable for variable setting.

7. Power supply unit (1) according to one of the preceding claims, characterized in that the power supply unit (1) is designed to vary the boost output power during the boost interval after the detection of an event triggering the change.

8. Power supply unit (1) according to one of the preceding claims, characterized in that the power supply unit (1) is set up for randomly setting the boost output power and / or intermediate boost time.

Power supply unit (1) according to Claim 8, characterized in that the power supply unit has a signal generator (8) for generating an alternating signal (S (t)) and for randomly setting the boost output power and / or intermediate boost time depending on the alternating signal generated by the signal generator and the time of detection of the event triggering the curtailment is set up as an influencing variable for the variable setting.

10. Power supply unit (1) according to one of the preceding claims, characterized in that the power supply unit (1) is set up for setting the current and / or the voltage and / or the current-time profile and / or the voltage-time profile of the boost output power.

1 1 power supply unit (1) according to one of the preceding claims, characterized in that the power supply unit (1) is set up to change the output power to the boost output power for the boost intermediate time after the change in the output power (1) to the nominal power or below the nominal power.

12. Power supply unit (1) according to one of the preceding claims, characterized in that the variable setting of the boost output power and / or the intermediate boost takes place automatically.

13. Power supply unit (1) according to one of the preceding claims, characterized in that the setting of the boost output power and / or the intermediate boost time is dependent on a higher-level energy management control center.