DE102023201838B4 - Monitored power supply unit, in particular for supplying components of a fire or hazard alarm system - Google Patents

Abstract

The invention relates to a power supply unit (SV) with a power supply connection (OUT) for connecting power supply lines (SL) and with a monitoring device (UE) for the operating state of the connected power supply lines, the latter being connectable to a termination unit (EOL) at a remote line end. The monitoring device has a measuring device (ST; RM, DV, ADC) for detecting a current current value of an output current (I _OUT ) and a current voltage value of an output voltage (U _OUT ). It further comprises a pulse detector (PD) for detecting a cyclic current increase pulse (P) in the output current, a time synchronization device (AE, TI) for temporally adjusting the start and end time of a measuring window (MF) and an associated control unit (MC) set up to determine an average minimum (I _MIN ) and average maximum output current value (I _MAX ) from recorded output current values outside or within a respective measuring window and to output an error message (FM) for a creeping interruption if a differential current value (ΔI) from the average maximum and average minimum output current value falls below a comparison current value (SU).

Description

The invention relates to a power supply unit for providing an output current with a predeterminable output voltage at a power supply connection. The power supply connection is provided for connecting power supply lines and possibly signal lines. The power supply unit has a monitoring device for monitoring the operating state of the connected power supply lines. The latter can be connected to a termination unit (EOL) at a remote line end, i.e. at a line end opposite the power supply connection, and are provided for connecting and for supplying components that can be connected to it, in particular of a fire or hazard alarm system. The monitoring device also comprises a measuring device for recording a current current value of the output current and a current voltage value of the output voltage.

From the DE 10 2008 003 799 A1 A monitoring device for monitoring the operating state of supply and/or signal lines of a detection system is known, in particular a fire protection and/or hazard detection system. The monitoring device comprises a measuring device which is designed, connected and/or connectable to generate a measurement signal depending on the operating state in the supply and/or signal lines, and an evaluation device which is designed to evaluate the measurement signal and to output a monitoring signal based on the evaluation. The monitoring device also has a controllable signal source which is designed, connected and/or connectable to couple a test signal into the supply and/or signal lines, wherein the measurement signal comprises the system response of the supply and/or signal lines to the test signal.

From the DE 10 2008 048 930 A1 A method is known for testing a detection line with n detectors of a hazard alarm system fed with a constant line voltage in the idle state for impermissibly high resistance by measuring the current of the detection line terminated with an end module and comparing it with a target value and generating an error message if the target value is not reached. A test current that is at least equal to the current of a detector in the alarm state is periodically generated on the detection line by means of the end module during a test period.

From the EP 3 295 996 B1 a method for monitoring a triggering device of a fire extinguishing system is known, wherein the triggering device is connected to an extinguishing control center via a supply line, wherein the triggering device is triggered by the extinguishing control center by means of an electromechanical relay when a fire alarm is received, wherein a semiconductor switching element is connected in series with the relay in order to avoid false triggering of the triggering device due to a mechanical effect on the electromechanical relay, wherein triggering only occurs when both switching elements are triggered to close, and wherein the semiconductor switching element is repeatedly, in particular cyclically, triggered by the extinguishing control center in the event that no fire alarm is received in order to impress a test current for monitoring the connected triggering device via the supply line.

From the DE 10 2014 207 171 A1 A method for determining an internal resistance of a supply network for supplying energy to a personal protection device of a vehicle is known. The personal protection device includes a charging unit that is connected to the supply network by means of a primary interface and to an energy buffer for temporarily storing energy for activating personal protection means of the personal protection device and for supplying the personal protection device after disconnection from the supply network by means of a secondary interface. The method includes a step of impressing a first charging current value at the secondary interface and a step of detecting a first current and/or a first voltage at the primary interface during the impressing. The method includes a step of impressing a second charging current value that is different from the first charging current value at the secondary interface. The method includes a step of determining a second current and/or a second voltage at the primary interface during the impressing and a step of determining the internal resistance of the supply network using the detected first current and second current and/or using the first voltage and the second voltage.

From the EP 2 869 072 A1 A device for detecting the electrical energy of two single-phase or multi-phase electrical consumers is known. The device comprises a measuring device for detecting a current and a voltage of the consumers, a filter for separating the current into a test and measuring current, a calculation unit for calculating the electrical power consumed and/or electrical work consumed by the at least two consumers and for generating consumer-related Data and a storage unit for storing the consumer-related data. The measuring device comprises a current transformer with a coil resistance, a voltage source connected in parallel to the coil resistance of the current transformer for generating the test current in each measuring circuit for the consumers, a coupling resistor connected to the voltage source, a load resistor connected in parallel to the current transformer, and a measuring amplifier connected to the filter.

The components of the fire or hazard alarm system can be, for example, smoke detectors, burglar alarms or acoustic and/or optical alarm devices. The smoke detectors are in particular aspirating smoke detectors. The power supply lines can also be used for signal or data transmission, in particular between the components connected to the power supply lines. In this case, the power supply lines can also be referred to as power supply/transmission lines. The signals or data to be transmitted can then be modulated onto the power supply lines.

The power supply lines are typically sheathed and thus form a cable. The power supply units considered can also have several power supply connections, to each of which power supply lines with, if necessary, signal lines can be connected to supply the components connected to them. Preferably, only two power supply lines can be connected or are intended to be connected between a respective power supply connection of the power supply unit and a respective connection of a termination unit opposite it.

The individual power supply lines have a (ohmic) line resistance acting as a series resistance between the respective power supply connection and the respective connection on the termination unit. This is typically less than 1 Ω, typically less than 0.1 Ω. The (ohmic) insulation resistance acting as a parallel resistance between the individual power supply lines is more than 1 MΩ, typically more than 10 MΩ, due to the conductor insulation present between them.

The predeterminable or fixed output voltage is preferably in a range of 12 to 30 V. The power supply unit can be designed in terms of performance to provide a continuous current in the range of 1 to 5 A. The output voltage is preferably a direct voltage, in particular with a negligible harmonic component. Alternatively, it can also be an alternating voltage, such as with a frequency of 50 Hz or 60 Hz. Accordingly, the output current is then an alternating current. The measuring device is typically also required for the intended regulation and monitoring of the output voltage and the output current on the power supply unit. The power supply unit typically has a power pack for connecting the power supply unit to a public power supply network, such as a 230 V/50 Hz or 120 V/60 Hz power supply network. The power supply unit can also include an uninterruptible power supply with a buffer battery or a buffer accumulator.

The invention further relates to a power supply system, in particular for the electrical supply of components of a fire or hazard alarm system. The power supply system comprises a power supply unit according to the invention, a termination unit and power supply lines and possibly signal lines. The power supply lines can, as previously described, be used again for signal or data transmission. The power supply lines are connected between a power supply connection of the power supply unit and a connection of the termination unit. The termination unit is designed to couple a recurring, in particular cyclical test current into the supply lines to generate corresponding current increase pulses by means of a controllable test current source.

According to the VdS guidelines for fire alarm systems VdS 2541: 2022-05 (02) entitled "Energy supply devices, requirements and test methods", it is required that energy supply devices with power supply lines connected to them, especially those with a length of more than 10 m, are monitored for their functionality. In detail, it is required that the power supply lines are monitored for short circuits, interruptions (line breaks), creeping short circuits and creeping interruptions to ensure the electrical supply to the connected components. In the event of a fault, this must be signaled, for example, on the energy supply device.

While a short circuit or interruption is usually a short-term and then permanent line fault, creeping short circuits or interruptions only occur over the course of the power supply unit's operating life. A creeping interruption is therefore a slowly progressive increase in the line resistance of one, two or more wires. of the power supply lines. The reason for these slow changes is usually environmental influences, mainly moisture and gases, which lead to the oxidation of contact points of the copper wires or to a reduction in the insulating properties between the copper lines (creeping short circuit).

Based on this, it is an object of the present invention to provide a power supply unit that is particularly easy to monitor.

It is a further object of the invention to provide an improved power supply system with such a power supply unit, with power supply lines connected thereto and with a terminating unit at the line end of the power supply lines opposite the power supply unit.

The object of the invention is solved by the features of the main claim. Advantages and embodiments of the invention, which can be used individually or in combination with one another, are the subject of the dependent claims.

According to the invention, the monitoring device has a pulse detector for detecting a recurring, in particular cyclical, current increase pulse in the output current of the power supply unit. The monitoring device also comprises a (time) synchronization device for continuously adjusting the start and end times of a measurement window for detecting a current increase in successive current increase pulses. A control unit connected to the measuring device of the power supply unit is set up to determine an average minimum output current value from detected output current values outside of a respective measurement window, to determine an average maximum output current value from detected output current values within a respective measurement window and to output a (first) error message for a creeping interruption if a differential current value from the average maximum and the average minimum output current value falls below a comparison current value.

By recording and evaluating a repeated, in particular cyclical differential current value with the comparison current value, it is advantageously possible to reliably detect a creeping interruption that results from an increase in the line resistance over time in at least one of the power supply lines. The differential current value, which is the amount of the test current coupled in by the termination unit, also decreases over time, since the voltage drop across the increased line resistance means that a lower input voltage is now present at the termination unit connection. In the simplest case, in which the test current coupled into the power supply lines occurs through repeated, in particular cyclical switching on of a load resistor parallel to the termination unit connection, the amount of the test current also decreases as the available input voltage at the termination unit connection decreases.

The measurement-based determination of the average minimum and maximum output current values from the recorded output current values can be carried out, for example, using a low-pass filter with a time constant aligned to the period of the current increase pulses. This is preferably done "by software" if the measurement-based recording and evaluation is carried out using an A/D converter and a microcontroller as the control unit. For this purpose, a suitable recording and evaluation program including a digital mean value filter can be implemented on the microcontroller.

Another special advantage is that no further measurement data needs to be transmitted from the termination unit to the power supply unit via additional signal lines.

According to one embodiment, the time synchronization device is designed to adapt the start and end times of a measurement window and a measurement window period to a predetermined pulse length of a current increase pulse in a range from 10 ms to 200 ms, preferably from 50 ms to 100 ms, and to a predetermined period of the current increase pulses in a range from 1 s to 60 s, preferably in a range from 10 s to 30 s. The comparatively long pauses between two current increase pulses enable continuous calibration of the start and end times of a measurement window in order to compensate for changes in the pulse length and the period of the current increase pulses, e.g. due to temperature increases or aging effects on components of the termination unit.

According to a further embodiment, the duty cycle between the pulse length and the period duration of a current increase pulse is less than 1:50, in particular less than 1:100.

According to one embodiment, the maximum output current of the power supply unit is dimensioned to a nominal output current value I _N. It is the value in the correct operating state the differential current value to be expected from the connected power supply lines is set at 0.05 to 0.50 times, in particular 0.01 to 0.10 times the rated output current value I _N. In addition, the comparison current value is set at 0.5 to 0.95 times, in particular 0.8 times the specified differential current value.

This allows a comparatively high test current to be coupled into the power supply lines, which then leads to significant voltage drops at the typically very low line resistances of the respective power supply lines. The latter then in turn lead to a significant reduction in the amount of the test current.

According to a further embodiment, the control unit is designed to output a (second) error message for a creeping short circuit if the average minimum output current value exceeds a current limit value for a creeping short circuit. One reason for the increase in the average minimum output current value can be the decrease in the insulation resistance between two power supply lines.

According to one embodiment, the control unit is designed to output a (third) error message for an interruption if, after switching on the power supply unit or if the detection of a current increase pulse by means of the pulse detector fails to occur during operation of the power supply unit. In this case, the termination unit is no longer supplied with electricity. The termination unit is therefore no longer able to couple the recurring, preferably cyclical test current into the power supply lines.

According to a further embodiment, the control unit is configured to output a (fourth) error message for a short circuit if a currently detected current value for the output current exceeds a tripping current limit value for a short circuit, in particular several times in succession.

The object of the invention is further achieved with a power supply system, in particular for the electrical supply of components of a fire or hazard alarm system, with a power supply unit according to the invention, with a terminating unit and with power supply lines and possibly signal lines. The power supply lines are connected between a power supply connection of the power supply unit and a connection of the terminating unit. The terminating unit is designed to couple a recurring, in particular cyclical test current into the supply lines to generate corresponding current increase pulses by means of a controllable test current source.

According to one embodiment of the power supply system, the controllable test current source comprises a series circuit consisting of a load resistor and a controllable switching element. The series circuit is connected in parallel to the connection of the terminating unit. The switching element can be controlled by means of a pulse generator to generate the current increase pulses.

As an alternative to the previous embodiment, the controllable test current source is a constant current source that can be switched on or off or a constant power element that can be switched on or off.

Constant current sources, also called current regulators, are available as two-pole electronic components.

Constant power elements can be implemented, for example, by voltage regulators with corresponding feedback paths, such as by means of ohmic resistors, for a voltage applied to the voltage regulator and for a current flowing through the voltage regulator. Voltage regulators are typically three-pole components with a voltage input, a voltage output and a reference voltage input provided for the feedback for voltage regulation.

The constant current sources and constant power elements considered each act like a passive component and thus as an ohmic resistor. Consequently, they do not actively feed any supply current into the power supply lines, but instead place an electrical load on the input of the termination unit. Such constant current sources and constant power elements preferably have a minimum input voltage as a technical characteristic data, so that if the voltage applied to the constant current source or constant power element, in this case the input voltage at the terminal of the termination unit, falls below the set constant current or the set constant electrical power loss. The minimum input voltage can, for example, be set to 0.9 times, in particular 0.8 times, a nominal voltage value U _N for the predeterminable output voltage at the power supply connection of the power supply unit.

The pulse generator is a signal generator that repeatedly generates rectangular pulses, such as by means of a multivibrator. If the termination unit has a microcontroller, the control signals for the switching element can also be generated by means of a timer in the microcontroller. The control signals to be generated repeatedly are preferably cyclical. The controllable switching element is preferably a switching transistor, in particular a FET.

According to one embodiment, the pulse generator is designed to output control pulses for the switching element with a pulse length in the range of 10 ms to 200 ms, preferably in the range of 50 ms to 100 ms, and with a period duration in the range of 1 s to 60 s, preferably in the range of 10 s to 30 s.

In particular, the pulse generator is designed to output control pulses for the switching element with a duty cycle of less than 1:50, in particular less than 1:100.

According to a further embodiment, the maximum output current of the power supply unit is dimensioned to a nominal output current value I _N . The test current to be coupled into the power supply lines by the terminating unit comprises a maximum current value in a range of 0.05 to 0.50 times, in particular in a range of 0.01 to 0.10 times the nominal output current value I _N .

This allows a comparatively high test current to be coupled into the power supply lines, which then leads to significant voltage drops at the typically very low line resistances of the respective power supply lines. The latter then in turn lead to a significant reduction in the amount of the test current.

In particular, the test current to be coupled into the power supply lines by the termination unit has a maximum current value in a range from 0.05 to 1 A, in particular in a range from 0.1 to 0.5 A.

According to one embodiment, the load resistor, the constant current source and the constant power element are dimensioned with regard to their maximum permissible power loss such that the difference between an average temperature value of the load resistor, the current source and the constant power element and an ambient temperature value is less than 20°C, in particular less than 10°C.

This means that, particularly in conjunction with the set very small duty cycle of less than 1:50, and in particular less than 1:100, the component dimensions for the load resistor, the constant current source and the constant power element can be extremely compact. Additional cooling measures are not required for this.

Finally, according to a further embodiment, the terminating unit is designed to prevent the coupling of the test current into the supply lines if an input voltage applied to the connection of the terminating unit falls below 0.9 times, in particular 0.8 times, a nominal voltage value U _N for the predefinable output voltage at the power supply connection of the power supply unit.

• 1 ein Funktionsschema einer beispielhaften Stromversorgungsanlage mit Stromversorgungseinheit, Abschlusseinheit und dazwischen angeschlossenen Stromversorgungsleitungen gemäss der Erfindung, und
• 2 beispielhaft den Verlauf eines von einer Stromversorgungseinheit stammenden Ausgangsstroms mit Stromerhöhungspulsen gemäss der Erfindung.

Further advantages, features and details of the invention emerge from the following description, in which embodiments of the invention are described in detail with reference to the drawings. The features mentioned in the claims and in the description can each be essential to the invention individually or in any combination. They show schematically:

• 1 a functional diagram of an exemplary power supply system with power supply unit, termination unit and power supply lines connected therebetween according to the invention, and
• 2 by way of example, the course of an output current originating from a power supply unit with current increase pulses according to the invention.

1 shows a functional diagram of an exemplary power supply system SVA with power supply unit SV, termination unit EOL and power supply lines SL connected between them according to the invention.

The left part of the 1 The power supply unit SV according to the invention shown has a mains-side input IN for a mains input voltage U _N , such as 230V/50 Hz. A downstream power supply unit NT converts the mains input voltage U _N into a potential-free output direct voltage U _OUT , whereby the voltages dropped across the very low-resistance fuse SI as short-circuit protection and the very low-resistance measuring resistor RM are negligible. A battery symbol in the block for the power supply unit NT symbolizes that the power supply unit NT can also be implemented as an uninterruptible power supply. The reference symbol GND designates a reference potential or the ground of the power supply unit SV. This reference potential GND and the positive output voltage are therefore present at an output-side power supply connection OUT. U _OUT . The two-pole power supply connection OUT can be a terminal, for example.

I _OUT designates an output current, or in this case output direct current, which the power supply unit SV provides. This also flows in the opposite direction through the measuring resistor RM, which is intended for the metrological recording of a current output current value. For this purpose, for example, a differential amplifier DV with high gain is connected to the measuring resistor RM. The output signal of the differential amplifier DV is low-pass filtered using a filter F1 and then fed to an A/D converter ADC to convert the analog measurement signal into a digital output current value. An output-side voltage divider ST converts the applied output voltage into a proportionally low divider voltage, which is fed to another A/D converter ADC after filtering using a second low-pass filter F2. The two A/D converters ADC are already an integrated component of a control unit MC implemented as a microcontroller.

Thus, as previously described, a monitoring device UE of the power supply unit SV has a measuring device ST; RM, DV, ADC for recording a current current value of the output current I _OUT and a current voltage value of the output voltage U _OUT . The recorded current and voltage values are usually also required for the voltage and current regulation of the power supply unit SV.

In the right part of the 1 The EOL termination unit is shown in detail, which is also referred to as an end-of-line device in technical terms. This has an input INE for connecting the EOL termination unit to two power supply lines SL. The INE input can be designed as a terminal or socket, for example. An input voltage designated U _EOL is present at the INE input. This input voltage U _EOL is related to a reference ground M of the EOL termination unit and is not identical to the reference potential GND of the power supply unit SV. The EOL termination unit also includes a test current source REF, implemented as an ohmic resistor, which can be cyclically connected to the INE input of the EOL termination unit via a switching element S. With the parallel connection, a test current I _REF is cyclically coupled into the power supply lines SL. If there are two power supply lines SL, as shown in the middle part of the 1 shown, electrical consumers L1, L2, Ln are switched on, then, assuming a constant electrical load from consumers L1, L2, Ln, the current value of the output current I _OUT provided by the power supply unit SV increases by the cyclically coupled test current I _REF . In other words, the total output current I _OUT of the power supply unit SV increases due to the additional, cyclically switched on load in the form of the load resistor REF. In the present example, the load resistor REF is switched on by means of a controllable switching element S, which is controlled by a pulse generator designated TI via an OR gate OD. In parallel, the load resistor REF can be switched on by means of a voltage detector SD in order to signal to the power supply unit SV by means of an increase in current that a sufficiently high input voltage U _EOL is present at the terminating unit EOL.

The two in the middle part of the 1 The power supply lines SL shown can be combined with a sheath to form a power supply cable. RL symbolically designates the line resistances of the two power supply lines SL that are present or effective in sections and which together form a total line resistance. The ohmic values of the individual line resistances are typically different from one another and depend on the respective line length between the connections OUT, INE and the connections of the consumers L1, L2, Ln to the two power supply lines SL. The voltage drop across the total line resistance corresponds to the product of the output current I _OUT and the voltage difference between the output voltage U _OUT and the input voltage U _EOL applied to the termination unit EOL. A significant decrease in the input voltage U _EOL at the termination unit EOL is therefore an indication of a possibly impermissible increase in the total line resistance. However, a lower input voltage U _EOL at the termination unit EOL also causes the magnitude of the test current I _REF to decrease at a constant load resistance REF and can be detected according to the invention using the power supply unit SV. If the cyclically impressed increase in the test current I _REF is reduced in an inadmissible manner, an error message indicating a creeping interruption can be output using the power supply unit SV.

According to the invention, the monitoring device UE now has a pulse detector PD already implemented as software in the microcontroller MC for detecting a recurring, in particular cyclical, current increase pulse in the output current I _OUT of the power supply unit SV (see also 2 ). The monitoring device UE also includes a time synchronization device AE, TI implemented as software in the microcontroller MC for the continuous temporal adjustment of the start and end time of a measurement window MF for the detection of a current increase in successive the following current increase pulses P. The time synchronization device AE, TI is implemented by a timer TI as an integrated hardware component of the microcontroller MC and by a software evaluation function block AE in the microcontroller MC. The suitably programmed software on the microcontroller MC ensures that a respective measurement window for the detection of a current increase in successive current increase pulses is time-tracked and is therefore always synchronous with a virtual time base VZ of the termination unit EOL shown on the right.

Furthermore, according to the invention, the control unit MC or the microcontroller connected to the measuring device ST; RM, DV, ADC is now set up to determine an average minimum output current value from recorded output current values outside of a respective measuring window and to determine an average maximum output current value from recorded output current values within a respective measuring window. Finally, the microcontroller MC is set up to output an error message FM for a creeping interruption if a differential current value from the average maximum and the average minimum output current value falls below a comparison current value SU. In the present example, the comparison current value SU is stored as a digital value in a non-volatile memory of the microcontroller MC. The error message FM is output here, for example, via a potential-free switching contact S.

2 shows, by way of example, the temporal progression V _IOUT of an output current I _OUT originating from a power supply unit SV with current increase pulses P according to the invention. Plotted over the time axis t, two current increase pulses P can be seen as examples, which increase an average minimum current value I _MIN each by a differential current value ΔI to an average maximum current value I _MIN of the output current I _OUT . MF designates a measuring window which is tracked over time according to the invention, within which the associated measured values of the output current I _OUT are recorded and, after mathematical averaging using software on the microcontroller MC, form the average maximum current value I _MAX . Complementary in time to this, the associated measured values of the output current I _OUT are recorded outside the respective measuring window MF. Again after mathematical averaging, the average minimum current value I _MIN of the output _current I _OUT then results.

TP denotes the period of the cyclical current increase pulses P and PL denotes the associated pulse length of a current increase pulse P. TT denotes a temporal tolerance window within which the period TP can change from current increase pulse P to current increase pulse P. BF denotes an example of an observation window which, as a kind of "catch window", is set in software to an expected current detection pulse P including the subsequent measurement-related detection and processing.

Finally, I _SI/2 refers to a current limit value I _SI/2 for a creeping short circuit that is set and determined by measurement during the commissioning of a power supply system SVA, which here corresponds, for example, to half the tripping current value I _SI for a short circuit. The current limit value I _SI/2 for a creeping short circuit is dimensioned such that it is above the average minimum current value I _MIN by a safety margin.

List of reference symbols

ADC

analog/digital converter

AE

evaluation block

BF

observation window

DV

differential amplifier

EOL

termination unit, end-of-line device

F1, F2

filter, low-pass

FM

Error message

GND

reference potential of the power supply device

IN

input, mains input

INE

connection of the final unit

IOUT

output current, DC output current

Imax

maximum output current with test current

IMIN

minimum output current without test current

IREF

test current, DC reference current,

ISI

tripping current limit

ISI/2

Current limit for creeping short circuit, half tripping current value

L1, L2, Ln

electrical load, consumer

M

Reference potential of the monitoring device, ground

MC

control unit, microcontroller

MF

measuring window

NT

power supply, voltage source

OD

OR function block, gate

OUT

output-side power supply connection

P

current increase pulse

PD

pulse detector

PL

pulse length

REF

test current source, load resistance, current source, constant power element

RL

line resistance

RM

measuring resistor, shunt

S

switching element, FET

SD

voltage detector

S.I.

backup

SL

power supply line

ST

voltage divider

SU

comparison current value,

sv

power supply unit, power supply device

SVA

power supply system

t

time, timeline

TB

duration of the observation window

TI

pulse generator, timer

TP

Period of the test current, period of the current increase pulse

TT

tolerance window

UE

monitoring device

UOUT

output voltage, DC output voltage

UEOL

input voltage at the termination unit

U.N.

input voltage, mains voltage

VIOUT

temporal course of the output current

VZ

virtual time base

ΔI

differential current value

Claims (15)

Power supply unit (SV) for providing an output current (I _OUT ) with a predeterminable output voltage (U _OUT ) at a power supply connection (OUT), wherein the power supply connection (OUT) is provided for connecting power supply lines (SL) and possibly signal lines, wherein the power supply unit (SV) has a monitoring device (UE) for monitoring the operating state of the connected power supply lines (SL), wherein the power supply lines (SL) can be connected to a termination unit (EOL) at a remote line end and are provided for connecting and for feeding components that can be connected to them, in particular of a fire or hazard alarm system, wherein the monitoring device (UE) of the power supply unit (SV) has - a measuring device (ST; RM, DV, ADC) for recording a current current value of the output current (I _OUT ) and a current voltage value of the output voltage (U _OUT ), - a pulse detector (PD) for detecting a recurring, in particular cyclical Current increase pulse (P) in the output current (I _OUT ) of the power supply unit (SV), - a time synchronization device (AE, TI) for the continuous temporal adjustment of the start and end time of a measuring window (MF) for the detection of a current increase in successive current increase pulses (P), and - a control unit (MC) connected to the measuring device (ST; RM, DV, ADC) set up to determine an average minimum output current value (I _MIN ) from detected output current values outside of a respective measuring window (MF), to determine an average maximum output current value (I _MAX ) from detected output current values within a respective measuring window (MF) and to issue an error message (FM) for a creeping interruption if a differential current value (ΔI) from the average maximum and the average minimum output current value (I _MAX , I _MIN ) falls below a comparison current value (SU). Power supply unit (SV) according to Claim 1 , wherein the time synchronization device (AE, TI) is designed to adapt the start and end time of a measuring window (MF) and a measuring window period to a predetermined pulse length (PL) of a current increase pulse (P) in a range from 10 ms to 200 ms, preferably from 50 ms to 100 ms, and to a predetermined period duration (TP) of the current increase pulses (P) in a range from 1 s to 60 s, preferably in a range from 10 s to 30 s. Power supply unit (SV) according to Claim 1 or 2 , where the duty cycle between the pulse length (PL) and the period (TP) of a current increase pulse (P) is less than 1:50, in particular less than 1:100. Power supply unit (SV) according to one of the preceding claims, wherein the maximum output current (I _OUT ) of the power supply unit (SV) is dimensioned to a nominal output current value I _N , wherein the differential current value (ΔI) to be expected in the proper operating state of the connected power supply lines (SL) is set to 0.05 to 0.50 times, in particular to 0.01 to 0.10 times the nominal output current value I _N and wherein the comparison current value (SU) is set to 0.5 to 0.95 times, in particular to 0.8 times the predetermined differential current value (ΔI). Power supply unit (SV) according to one of the preceding claims, wherein the control unit (MC) is configured to output an error message (FM) for a creeping short circuit if the average minimum output current value (I _MIN ) exceeds a current limit value for a creeping short circuit (I _SI/2 ). Power supply unit (SV) according to one of the preceding claims, wherein the control unit (MC) is configured to output an error message (FM) for an interruption if, after switching on the power supply unit (SV) or if, during operation of the power supply unit (SV), the detection of a current increase pulse (P) by means of the pulse detector (PD) fails. Power supply unit (SV) according to one of the preceding claims, wherein the control unit (MC) is configured to output an error message (FM) for a short circuit if a currently detected current value for the output current (I _OUT ) exceeds a tripping current limit value for a short circuit (I _SI ), in particular several times in succession. Power supply system (SVA), in particular for the electrical supply of components of a fire or hazard alarm system, with a power supply unit (SV) according to one of the preceding claims, with a terminating unit (EOL) and with power supply lines (SL) and optionally signal lines, wherein the power supply lines (SL) are connected between a power supply connection (OUT) of the power supply unit (SV) and a connection (INE) of the terminating unit (EOL), and wherein the terminating unit (EOL) is set up to couple a recurring, in particular cyclical test current (I _REF ) into the supply lines (SL) by means of a controllable test current source (REF) for generating corresponding current increase pulses (P). Power supply system (SVA) according to claim 8 , wherein the controllable test current source (REF) comprises a series circuit comprising a load resistor (REF) and a controllable switching element (S), wherein the series circuit is connected in parallel to the connection (INE) of the termination unit (EOL), and wherein the switching element (S) can be controlled by means of a pulse generator (TI) for generating the current increase pulses (P). Power supply system (SVA) according to claim 8 , wherein the controllable test current source (REF) is a constant current source that can be switched on or off or a constant power element that can be switched on or off, and wherein the switching element (S) can be controlled by means of a pulse generator (TI) for generating the current increase pulses (P). Power supply system (SVA) according to claim 9 or 10 , wherein the pulse generator (TI) is designed to output control pulses for the switching element (S) with a pulse length (PL) in the range of 10 ms to 200 ms, preferably in the range of 50 ms to 100 ms, and with a period duration (TP) in the range of 1 s to 60 s, preferably in the range of 10 s to 30 s. Power supply system (SVA) according to claim 11 , wherein the pulse generator (TI) is designed to output control pulses for the switching element (S) with a duty cycle of less than 1:50, in particular less than 1:100. Power supply system (SVA) according to one of the Claims 8 until 12 , wherein the maximum output current (I _OUT ) of the power supply unit (SV) is dimensioned to a nominal output current value I _N and wherein the test current (I _REF ) to be coupled into the power supply lines (SL) by the termination unit (EOL) has a maximum current value in a range of 0.05 to 0.50 times, in particular in a range of 0.01 to 0.10 times the nominal output current value I _N. Power supply system (SVA) according to one of the Claims 8 until 13 , wherein the test current (I _REF ) to be coupled into the power supply lines (SL) by the termination unit (EOL) has a maximum current value in a range from 0.05 to 1 A, in particular in a range from 0.1 to 0.5 A. Power supply system (SVA) according to one of the Claims 8 until 14 , wherein the termination unit (EOL) is designed to prevent the coupling of the test current (I _REF ) into the supply lines (SL) if an input voltage (U _EOL ) applied to the terminal (INE) of the termination unit (EOL) exceeds 0.9 times, in particular 0.8 times, times a nominal voltage value U _N for the predeterminable output voltage (U _OUT ) at the power supply connection (OUT) of the power supply unit (SV).

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