EP4000169A1 - Method and system with a dc link supported via a dc-to-dc converter from a stored energy source, and with a power pack - Google Patents

Abstract

The invention relates to a method and system for operating a system comprising a stored energy source and resistor, wherein, in order to discharge the stored energy source, an electrical power P that is constant over time is supplied to the resistor R continuously, in particular for a period T, in particular until the resistor is practically fully discharged, in particular with the period T being greater than the time constant of the temperature increase of the resistor R caused by a continuous electrical power, which is constant over time, supplied to the resistor.

Description

Method and system with a DC voltage intermediate circuit supported by a DC / DC converter from an energy store and a power supply unit

Description:

The invention relates to a method and a system with a DC voltage intermediate circuit supported by a DC / DC converter from an energy store and a power supply unit.

It is common knowledge that braking resistors are used to reduce the im

To reduce the energy generated by the generator operation of electric motors, so that dangerously high voltages are prevented.

The invention is therefore based on the object of making a system as safe as possible.

According to the invention, the object is achieved in the method according to the features specified in claim 1 or 2 and in the system according to the features specified in claim 12.

Important features of the invention in the method according to claim 1 for operating the system are that the system with a DC / DC converter from a

Energy storage supported DC voltage intermediate circuit and one from one

AC voltage supply network and a power supply unit that can be supplied from the intermediate circuit and that provides a low voltage, in particular 24 volts, is provided, the DC / DC converter being operated in such a way that the DC / DC converter at its first connection is in a first operating state, in particular and when the AC voltage supply network is operational, provides a first voltage,

- The DC / DC converter at its first connection in a second

Operating state, in particular and when a power failure is detected, i.e. failure of the AC voltage supply network, provides a second voltage, the first voltage being greater than a minimum voltage, wherein the second voltage is lower than the minimum voltage, in particular wherein one supplied from the first connection of the DC / DC converter

Inverter is switched off when the connection is present at this first connection

Voltage is less than the minimum voltage.

The advantage here is that the power supply unit will continue to provide the extra-low voltage for as long as possible after the power failure and thus supply the voltage supplied by the power supply unit

Signal electronics areas of the modules can be kept ready for operation. This increases security, since the monitoring and security functions carried out by the respective signal electronics areas are ready for operation for as long as possible.

Important features of the invention in the method according to claim 2 are that the system with a supply module, an inverter, a DC / DC converter, a

Energy storage and a power supply is designed, wherein the DC voltage side connection of the having a rectifier

Supply module is electrically connected in parallel to the DC voltage side connection of the inverter and to the first connection of the DC / DC converter, to the second connection of which the energy store is connected, the AC voltage side connection of the rectifier from one

AC voltage supply network is fed, with a low voltage, in particular 24 volts, being fed to the supply module, the DC / DC converter and the inverter from a first DC voltage side connection of the power supply unit, with an AC voltage side connection of the power supply unit from

AC voltage supply network is fed, with a second DC voltage side connection of the power supply parallel to

the DC voltage-side connection of the supply module is switched, wherein in a first operating state, in particular and when the AC voltage supply network is ready for operation, the DC / DC converter provides a first voltage at its first connection, with the DC / DC converter in a second operating state, in particular and when a network failure is detected, i.e. failure of the AC voltage supply network provides a second voltage at its first connection, the first voltage being greater than a minimum voltage, in particular 400 volts, the second voltage being less than the minimum voltage, the inverter being switched off when the voltage applied to its DC-side connection is lower than the minimum voltage.

The advantage here is that the power supply unit will continue to provide the extra-low voltage for as long as possible after the power failure and thus supply the voltage supplied by the power supply unit

Signal electronics areas of the modules can be kept ready for operation. This increases safety, since the monitoring and safety functions carried out by the respective signal electronics areas are ready for operation for as long as possible.

In an advantageous embodiment, sensors for power failure detection are in the

Supply module arranged. The advantage here is that the information about the

Power failure is directly recognizable on the AC voltage supply network and is medium

Data bus connection to the bus subscribers connected for data exchange can be reported, in particular also to the DC / DC converter, which then sets the operating state as a function of the information. It is therefore important that the measurement technology for detecting the power failure is located in a different device than in the DC / DC converter. This measurement technology is otherwise required for the function and mode of operation of the supply module, since it has a DC / DC converter arranged on the DC / DC connection of the rectifier of the supply module, so that the power flow from the rectifier into the intermediate circuit can be controlled.

In an advantageous embodiment, one is used to discharge the energy store

Resistance R, in particular braking resistance, electrical power P constant over time is supplied permanently, in particular during a period of time T, in particular until the resistor is practically completely discharged, in particular with the period of time T being greater than the time constant of the constant electrical power supplied to the resistor

Temperature rise in resistance R.

The advantage here is that power is not only applied to the resistor for a short time in order to lower the intermediate circuit voltage, but that the greatest possible power P is applied permanently. This power is preferably so great that the

Resistance is barely destroyed. Thus, the maximum permissible power can be permanently dissipated to the environment as heat. By means of this method according to the invention, the smallest possible resistance value can be used, that is to say rapid discharge of the energy store can be carried out. Such discharges are important in the case of transport and service.

In an advantageous embodiment, the voltage U present at a series circuit formed from the resistor and a controllable semiconductor switch, in particular a brake chopper, is detected, the series circuit being either fed directly from the voltage made available by the energy store or via a DC / DC Converter from the vom

Energy storage voltage provided is fed, the controllable semiconductor switch being supplied with a pulse-width-modulated control signal with a pulse-width modulation ratio that is dependent on the value of the detected voltage, in particular wherein the pulse-width modulation ratio is determined according to (1 / U) * (P * R) ^L 1 is. The advantage here is that, depending on the voltage, the

Pulse width modulation ratio is changed, in particular is increased when the voltage drops. In an advantageous embodiment, the controllable half-liter switch is permanently closed when the voltage U falls below a threshold value, in particular the threshold value (P * R) being ^L 1. This enables particularly fast deep discharge when the maximum power that can be fed to the resistor is in the permissible range. A

Pulse width modulation is then avoided.

In an advantageous embodiment, the system has a supply module comprising a mains-fed rectifier, the DC voltage side connection of which is connected to the DC voltage side connection of an inverter and to the first connection of a DC / DC converter, the second connection of the DC / DC converter to the the connection of the energy store providing the voltage U is connected, an electric motor, in particular a three-phase motor, being connected to the connection on the AC voltage side of the inverter. The advantage here is that the system has an energy storage device, which buffers the energy generated by the electric motor as a generator and thus when motor power is drawn from the intermediate circuit

Keeps power consumption from the AC voltage supply network small.

In an advantageous embodiment, a DC / DC converter is arranged between the DC voltage side connection of the rectifier and the DC voltage side connection of the supply module, which regulates the power flow from the rectifier to the resistor R and the controllable

Half liter switch formed series connection stops during the discharging of the

Energy storage, in particular so that on that power module on which the diodes of the

Rectifier and the controllable half liter switch are arranged integrated when

Discharge heat is generated either by the controllable semiconductor switch or alternatively by the diodes of the rectifier. The advantage here is that the power flow from the AC voltage supply network to the intermediate circuit can be interrupted. This is particularly important when unloading. In an advantageous embodiment, the inverter has a power module on which controllable semiconductor switches arranged in half bridges are arranged. The advantage here is that the controllable half-liter switches can be designed as circuit breakers and are nevertheless structurally integrated, that is, can be arranged on a common carrier.

In an advantageous embodiment, the power P is less than the maximum from

Electric motor via the inverter for connection of the DC voltage side

Inverter with regenerative operation of the electric motor regenerative power. The advantage here is that a permanently constant power can be dissipated by means of the energy store, but the excess energy in the generator operating mode

Energy storage must be stored.

In an advantageous embodiment, the pulse width modulation frequency is

Control signal during the supply of the power P, in particular during the

Time span T, changed, in particular as pulse width modulation frequency different in particular discrete values can be used in chronological succession. The advantage here is that the

Noise emission can be reduced or at least no monofrequency sound can be heard, but the sound energy can be divided into different frequencies. The sound impression is therefore more acceptable.

In an advantageous embodiment, the current I flowing through the resistor R is detected, the current resistance value of the braking resistor being determined from the time-averaged voltage provided via the brake chopper and the time-averaged current, in particular according to U / 1, and below Consideration of a characteristic curve which shows the temperature dependence of the

Braking resistor represents the current temperature T of the respective braking resistor is determined. The advantage here is that the temperature can be determined from the specific voltage and the specific current. In an advantageous embodiment, it is monitored whether the specific temperature T of the braking resistor exceeds a threshold value, in particular wherein an emergency shutdown of the brake chopper is carried out when it is exceeded. The advantage here is that a

Destruction of the braking resistor can be avoided.

In an advantageous embodiment, the specific temperature is regulated to a setpoint temperature in that the power P is set accordingly as the control value of a controller, in particular a PI controller. The advantage here is that even with changed

Ambient temperature maximum power can be dissipated from the energy storage device to the environment.

Important features of the system, in particular for carrying out the aforementioned method, are that the system is designed with a supply module, an inverter, a DC / DC converter, an energy store and a power supply unit, the DC voltage-side connection of the rectifier having

Supply module is electrically connected in parallel to the DC voltage side connection of the inverter and to the first connection of the DC / DC converter, to the second connection of which the energy store is connected, the AC voltage side connection of the rectifier from one

AC voltage supply network is fed, with a low voltage, in particular 24 volts, being fed to the supply module, the DC / DC converter and the inverter from a first DC voltage side connection of the power supply unit, with an AC voltage side connection of the power supply unit from

AC voltage supply network is fed, A second DC voltage-side connection of the power supply unit is connected in parallel to the DC-voltage side connection of the supply module, in particular so that the power supply unit can be supplied from the AC voltage supply network and / or via the DC / DC converter from the energy store, the DC / DC converter being so suitable It is designed that the DC / DC converter provides a first voltage at its first connection in a first operating state, in particular and when the AC voltage supply network is ready for operation, and the DC / DC converter in a second operating state, in particular and when a power failure is detected of the AC voltage supply network, provides a second voltage at its first connection, the first voltage being greater than a minimum voltage, in particular 400 volts, the second voltage being less than the minimum voltage, in particular the inverter being designed in such a way that the

Inverter is switched off when the voltage applied to its DC voltage-side connection is less than the minimum voltage.

The advantage here is that the power supply unit will continue to provide the extra-low voltage for as long as possible after the power failure and thus supply the voltage supplied by the power supply unit

Signal electronics areas of the modules can be kept ready for operation.

In an advantageous embodiment, sensors for power failure detection are in the

Supply module are arranged. The advantage here is that the information about the power failure can be recognized directly on the AC voltage supply network and is medium

Data bus connection to the bus subscribers connected for data exchange can be reported, in particular also to the DC / DC converter, which then sets the operating state as a function of the information. It is therefore important that the measurement technology for detecting the power failure is located in a different device than in the DC / DC converter. This measurement technology is otherwise used for the function and operation of the supply module is required, since this has a DC / DC converter arranged on the DC voltage side connection of the rectifier of the supply module, so that the power flow from the rectifier into the intermediate circuit can be controlled.

In an advantageous embodiment, the system has a supply module comprising a mains-fed rectifier, the DC-side connection of which is connected to the DC-side connection of an inverter of the system and to the first DC-side connection of a DC / DC converter of the system, the second DC-side connection being the DC / DC converter with the

Energy storage, in particular accumulator arrangement and / or

Double-layer capacitor arrangement and / or ultracap arrangement, is connected, wherein an electric motor, in particular three-phase motor, is connected to the AC voltage side connection of the inverter. The advantage here is that for

Transport purposes or maintenance purposes, the energy storage can be discharged. This discharge can be carried out quickly because a very low ohmic resistance value can be used. This is because, by detecting the voltage applied to the series circuit, a constant power can be dissipated to the resistor by means of an appropriately suitable pulse width modulation, and rapid discharge can also be carried out at low voltages.

In an advantageous embodiment, a DC / DC converter is arranged between the DC voltage side connection of the rectifier and the DC voltage side connection of the supply module. The advantage here is that the power flow from the rectifier to the intermediate circuit can be influenced, in particular switched off. In addition, the voltage level present at the DC voltage-side connection of the rectifier is different from the intermediate circuit level, i.e. from the voltage level at

DC-side connection of the inverter or the supply module.

In an advantageous embodiment, a controllable semiconductor switch connected in series with the braking resistor is arranged in the housing of the DC / DC converter. The advantage here is that the controllable semiconductor switch can be designed to be integrated with the other electronics of the DC / DC converter and can then also be used for heat dissipation. In an advantageous embodiment, a controllable semiconductor switch connected in series with the braking resistor is integrated on a power module which has diodes and / or controllable semiconductor switches arranged in half bridges. The advantage here is that the rectifier is integrated with the controllable semiconductor switch and designed to be heat-dissipated together. However, since the power flow from the rectifier to the intermediate circuit is stopped, in particular separated, by the converter when the energy store is discharged by means of the resistor, in particular the braking resistor, the power losses of the diodes of the rectifier and the power loss of the controllable semiconductor switch occur only alternatively.

In an advantageous embodiment, the power module is arranged in the housing of the inverter or of the supply module. The advantage here is that the controllable

Semiconductor switch can be arranged integrated in the power module and thus the cooling of the controllable power module can be carried out with the cooling of the power module, in particular by means of a heat sink, which dissipates the heat loss of the controllable semiconductor switches of the inverter arranged in half bridges and the controllable semiconductor switch assigned to the resistor to the environment.

Further advantages result from the subclaims. The invention is not restricted to the combination of features of the claims. For the person skilled in the art, there are further sensible possible combinations of claims and / or individual claims

Claim features and / or features of the description and / or the figures, in particular from the task and / or the task posed by comparison with the prior art.

The invention will now be explained in more detail with reference to schematic figures:

A system according to the invention is shown schematically in FIG.

As shown in the figure, a supply module 1 fed by an AC voltage supply network 8 provides a unipolar voltage at its connection on the DC voltage side.

The DC voltage-side connection of an inverter 2 is connected to this connection, with a three-phase voltage from an electric motor 4, in particular from an electric motor 4, from the inverter 2 at the AC voltage-side connection of the inverter 2

AC motor, in particular three-phase motor, is made available.

The inverter is controlled by control electronics 3. In particular, the control electronics 3 generate pulse-width-modulated control signals for the controllable semiconductor switches of the inverter, which are arranged in half-bridges connected in parallel to one another, this parallel connection of half-bridges being able to be fed from the unipolar voltage.

Structurally, these semiconductor switches, in particular six controllable semiconductor switches, are integrated on a module on which a further controllable semiconductor switch is also integrated, which can be referred to as a brake chopper.

The brake chopper is connected in series with a resistor which can be referred to as a braking resistor (7, 12), this series connection also being able to be fed from the unipolar voltage.

A connection of a DC / DC converter 5 is also connected to the connection on the DC voltage side of the supply module 1, so that this DC / DC converter 5 is connected in parallel to the inverter 2.

An energy store 6 is connected to the other connection of the DC / DC converter 5. The DC / DC converter 5 thus enables a power flow from the energy store 6 to the intermediate circuit having unipolar voltage or vice versa, even if the amount of the unipolar voltage is very different from the amount of the voltage applied to the energy store 6.

The energy store 6 is as an electrolytic capacitor arrangement

Double-layer capacitor arrangement and / or preferably designed as a storage battery arrangement.

The supply module 1 can be implemented as a mains-fed rectifier. However, a DC / DC converter is preferably arranged between the mains-fed rectifier and the DC voltage-side connection of the supply module 1, so that the power flow from the AC voltage supply network 8 into the intermediate circuit can be controlled.

The rectifier in turn preferably has a module on which the diodes of the rectifier are integrated and on which a further controllable semiconductor switch is also integrated, which can be referred to as a brake chopper.

The brake chopper is connected in series with a further resistor 13, which can be referred to as a braking resistor, this series connection also being able to be fed from the DC voltage-side connection of the rectifier.

The DC / DC converter 5 also includes a further controllable semiconductor switch that is integrated, which can be referred to as a brake chopper.

This brake chopper is connected in series with a further resistor 7, which can be referred to as a braking resistor, this series connection also being able to be fed from the DC voltage-side connection of the rectifier or from the voltage applied to the energy store 6.

This means that several brake choppers can be provided in the system.

According to the invention, the security of the system is increased by a discharge of the

Energy storage is controlled executable. This is important not only when the energy store 6 is being transported, but also when the system is being serviced when the energy store is to be discharged. Discharging is also important for special types of energy storage if a memory effect is to be prevented. For example, NiCd batteries are regularly discharged over time.

Discharging takes place in such a way that the brake chopper of the respective braking resistor (7, 12, 13) is controlled depending on the unipolar voltage or on the voltage U applied to the series circuit formed by the braking resistor and the associated brake chopper in such a way that the respective braking resistor R a constant power is continuously supplied.

This electrical power P supplied to the respective braking resistor permanently until the energy store is practically completely discharged is specified as high as possible. It is therefore preferably the same as the rated power of the braking resistor R.

For this purpose, the voltage U is recorded and the respective brake chopper is preferably controlled with a pulse width modulation ratio (1 / U) * (P * R) ^L 1. In this way, the power supplied to the respective braking resistor remains constant even when the voltage U drops.

In particular, the nominal power, that is to say also the power P, is less than that in the generator operation of the electric motor from the electric motor 4 via the inverter 2

regenerative power.

The ohmic resistance of the respective braking resistor R can therefore be selected to be very small and therefore a practically complete discharge can be achieved in a short time.

If the voltage falls below a threshold value, the pulse width modulation can even be replaced by permanently closing the controllable switch. In this way, a particularly fast total discharge is made possible. As soon as the voltage falls below a second, even smaller threshold value, the switch is then opened again in order to protect the battery cells against destruction. In the manner described, energy from the intermediate circuit is via the

Braking resistors (7, 12, 13) convertible into heat.

If the series circuit formed from the braking resistor 7 and the brake chopper assigned to it is fed directly from the voltage applied to the energy store, deep discharging of the energy store is made possible in a simple manner because the DC / DC converter 5 cannot work without a minimum voltage and thus below the

Minimum voltage no discharge through the braking resistors 12 and 13 can be carried out.

Because the series circuit formed from the respective brake chopper and the braking resistor 12 or 13 is only indirectly via the DC / DC converter 5 of the

Energy storage supplied.

When the energy store 6 is discharged, the supply module 1 does not conduct any electrical power from the AC voltage supply network to the intermediate circuit.

According to the invention is a power supply 9 that on the one hand consists of the

AC voltage supply network 8 can also be supplied from the other hand

Intermediate circuit can be supplied, i.e. from a DC voltage. A supply is thus still available even in the event of a power failure, since energy can still be supplied to the intermediate circuit from the energy store 6 via the DC / DC converter 5.

Thus, the power supply 9 is within a period of time after the occurrence of the power failure

Low voltage, in particular 24 volts, can be provided. The time span is limited, however, by the energy which is present in the storage device 6 and, if necessary, by further power sinks arranged on the intermediate circuit.

With the extra-low voltage provided by the power supply unit 9, at least part of the

Signal electronics area, can be supplied by components of the system, such as part of the signal electronics of the supply module 1, part of the signal electronics of the DC / DC converter 5, the signal electronics 3 of the inverter 2, a higher-level controller 10 and other consumers that can be fed by the low voltage .

There is no power failure in normal operation. Then the DC / DC converter 5 sets the am

Energy store 6 provided voltage to the first required in the intermediate circuit Voltage, i.e. nominal intermediate circuit voltage, up or down if necessary. This first voltage is greater than a minimum voltage, in particular 400 volts.

The inverter 2 is switched off below the minimum voltage.

On the network side, sensors are attached to the supply module 1, in particular means for detecting the phase voltages of the three-phase network

AC voltage supply network. The signal electronics of the supply module 1 also functions as an evaluation unit for the signals from these sensors arranged on the supply module 1 on the network side. As soon as a power failure is detected, corresponding information is reported to the other bus participants via the data bus

DC / DC converters implemented by bus subscribers 5

If a power failure is detected, the DC / DC converter 5 continues to provide the

The intermediate circuit nominal voltage is available to the intermediate circuit until the inverter 2 is in a safe state, in particular that supplied by the inverter 2

Electric motor 4 is braked.

After receiving the information about the attainment of the safe state, the DC / DC converter 5 only provides a second voltage to the intermediate circuit, which is smaller than that

Minimum voltage is. For example, the second voltage is slightly more than 24 volts, so that 24 volts can be made available by the power pack.

The power consumed by the system is preferably determined by signal electronics of the DC / DC converter 5 from the current flowing from the DC / DC converter 5 into the intermediate circuit and the voltage detected at the intermediate circuit, and from this, taking into account the charging energy currently available in the memory 6 the respective remaining runtime is determined, the remaining runtime being the time in which the power supply unit is still able to provide the second voltage to the intermediate circuit.

In further exemplary embodiments according to the invention, no DC / DC converter 5 is provided, but the energy store 6 is connected directly to the intermediate circuit. In this case, below the minimum voltage, i.e. when the inverter 2 is switched off, the The residual energy of the energy store 6 is made available as completely as possible to the power supply unit 9, so that the low voltage can be provided by the power supply unit 9 for as long as possible.

In further exemplary embodiments according to the invention, the current flowing through the respective braking resistor is detected and from that via the braking chopper

provided, time-averaged voltage as well as the recorded and time-averaged current determines the current resistance value of the braking resistor and below

Taking into account a characteristic that represents the temperature dependency of the braking resistor, determines the current temperature of the respective braking resistor.

Thus, on the one hand, it can be monitored whether the temperature of the braking resistor exceeds a threshold value and whether an emergency shutdown of the brake chopper is necessary. On the other hand, an output adapted to the specific temperature can alternatively be set. This means that the power P follows the temperature. Thus a change is the

Ambient temperature or deterioration of the braking resistor to the

The surrounding heat transfer resistance can be taken into account.

In further exemplary embodiments according to the invention, there is no constant

Pulse width modulation frequency used, but the pulse width modulation frequency is changed over time or continuously. In this way, less disruptive noise emission can be brought about.

List of reference symbols

I supply module

2 inverters

3 control electronics

4 electric motor

5 DC / DC converters

6 energy storage

7 braking resistor

8 AC voltage supply network

9 double-sided power supply unit

10 higher-level control

I I bus subscribers, especially consumers 12 braking resistor

Claims

Patent claims:

1. A method for operating a system with a DC voltage intermediate circuit supported by a DC / DC converter from an energy store and one from one

AC voltage supply network and power supply unit which can be supplied from the intermediate circuit and which provides a low voltage, in particular 24 volts, characterized in that the DC / DC converter is operated in such a way that the DC / DC converter at its first connection is in a first operating state, in particular and when the AC voltage supply network is operational, provides a first voltage,

- The DC / DC converter at its first connection in a second

Operating state, in particular and when a power failure is detected, i.e. failure of the AC voltage supply network, provides a second voltage, the first voltage being greater than a minimum voltage, the second voltage being less than the minimum voltage, in particular being one from the first connection of the DC / DC -Converter supplied

Inverter is switched off when the connection is present at this first connection

Voltage is less than the minimum voltage.

2. A method for operating a system with a supply module, an inverter, a DC / DC converter, an energy store and a power supply unit, the DC voltage-side connection of the rectifier having

Supply module is electrically connected in parallel to the DC voltage side connection of the inverter and to the first connection of the DC / DC converter, to the second connection of which the energy store is connected, the AC voltage side connection of the rectifier from one

AC voltage supply network is fed, with a low voltage, in particular 24 volts, being fed to the supply module, the DC / DC converter and the inverter from a first DC voltage side connection of the power supply unit, with an AC voltage side connection of the power supply unit from

AC voltage supply network is fed, with a second DC voltage side connection of the power supply parallel to

DC-side connection of the supply module is connected, the DC / DC converter is designed so that in a first operating state, in particular and when it is ready for operation

AC voltage supply network, the DC / DC converter provides a first voltage at its first connection, and in a second operating state, in particular and when a power failure is detected, i.e. failure of the AC voltage supply network, the DC / DC converter provides a second voltage at its first connection, with the first voltage is greater than a minimum voltage, in particular 400 volts, the second voltage being less than the minimum voltage, wherein the inverter is switched off when the voltage applied to its DC voltage-side connection is less than the minimum voltage.

3. The method according to claim 1 or 2,

characterized in that

Sensors for power failure detection are arranged in the supply module and the supply module is connected to the DC / DC converter for data exchange.

4. The method according to claim 1, 2 or 3,

characterized in that

To discharge the energy store, a temporally constant electrical power P is continuously supplied to the resistor R, in particular during a period of time T, in particular until the resistor is practically completely discharged, in particular where the period of time T is greater than the time constant of the one supplied to the resistor caused constant electrical continuous power

Temperature rise in resistance R.

5. The method according to claim 1 or 2,

characterized in that

the voltage U present at a series circuit formed by the resistor and a controllable semiconductor switch, in particular a brake chopper, is detected, the series circuit being fed either directly from the voltage made available by the energy store or via a DC / DC converter from the

Energy storage voltage provided is fed, the controllable semiconductor switch being supplied with a pulse-width-modulated control signal with a pulse-width modulation ratio that is dependent on the value of the detected voltage, in particular wherein the pulse-width modulation ratio is determined according to (1 / U) * (P * R) ^L 1 is, in particular wherein said controllable half liter switch is permanently closed when the voltage U falls below a threshold value, in particular wherein the threshold value (P * R) ^{L _1/2.}

6. The method according to any one of the preceding claims,

characterized in that

the system has a supply module comprising a mains-fed rectifier, the DC voltage side connection of which is connected to the DC voltage side connection of an inverter and to the first connection of a DC / DC converter, the second connection of the DC / DC converter to the connection providing the voltage U of the energy store is connected, with an electric motor, in particular three-phase motor, being connected to the AC voltage side connection of the inverter.

7. The method according to any one of the preceding claims,

characterized in that

between the DC voltage side connection of the rectifier and the

A DC / DC converter is arranged on the DC voltage-side connection of the supply module, which controls the power flow from the rectifier to the resistor R and the controllable

Half liter switch formed series connection stops during the discharging of the

Energy storage, in particular so that on that power module on which the diodes of the

Rectifier and the controllable half liter switch are arranged integrated when

Discharge heat is generated either by the controllable semiconductor switch or alternatively by the diodes of the rectifier.

8. The method according to any one of the preceding claims,

characterized in that

the inverter has a power module on which controllable semiconductor switches arranged in half bridges are arranged, and / or that the power P is less than the maximum power that can be fed back from the electric motor via the inverter to the DC-side connection of the inverter in generator operation of the electric motor, and / or that the pulse width modulation frequency of the control signal is changed during the supply of the power P, in particular during the time period T, in particular different, in particular discrete values are used as the pulse width modulation frequency in chronological succession.

9. The method according to any one of the preceding claims,

characterized in that

the current I flowing through the resistor R is detected, the current resistance value of the braking resistor being determined from the time-averaged voltage provided via the brake chopper and the time-averaged current, in particular according to U / 1, and taking into account a characteristic curve, which is the temperature dependence of the

Braking resistor represents the current temperature T of the respective braking resistor is determined.

10. The method according to any one of the preceding claims,

characterized in that

it is monitored whether the specific temperature T of the braking resistor exceeds a threshold value, in particular wherein an emergency shutdown of the brake chopper is carried out after it is exceeded.

11. The method according to any one of the preceding claims,

characterized in that

the specific temperature is regulated down to a target temperature in that the power P is set accordingly as a control value of a controller, in particular a PI controller.

12. System, in particular for performing a method according to one of the preceding claims, with a supply module, an inverter, a DC / DC converter, a

Energy store and a power supply unit, the DC voltage side connection of the rectifier having

Supply module is electrically connected in parallel to the DC voltage side connection of the inverter and to the first connection of the DC / DC converter, to the second connection of which the energy store is connected, the AC voltage side connection of the rectifier from one

AC voltage supply network is fed, with a low voltage, in particular 24 volts, being fed to the supply module, the DC / DC converter and the inverter from a first DC voltage side connection of the power supply unit, with an AC voltage side connection of the power supply unit from

AC voltage supply network is fed, with a second DC voltage side connection of the power supply parallel to

DC voltage-side connection of the supply module is switched, in particular so that the power pack can be supplied from the AC voltage supply network and / or via the DC / DC converter from the energy store, the DC / DC converter being designed so that the DC / DC Converter in a first operating state, in particular and when the AC voltage supply network is ready for operation, provides a first voltage at its first connection, and the DC / DC converter provides a second voltage at its first connection in a second operating state, in particular and when a power failure is detected, i.e. failure of the AC voltage supply network, the first voltage being greater than a minimum voltage, in particular 400 volts, the second voltage is smaller than the minimum voltage, in particular wherein the inverter is designed in such a way that the

Inverter is switched off when the voltage applied to its DC voltage-side connection is less than the minimum voltage.

13. System according to one of the preceding claims,

characterized in that

Sensors for power failure detection are arranged in the supply module and that

The supply module is connected to the DC / DC converter for data exchange.

14. System according to one of the preceding claims,

characterized in that

the system has a supply module comprising a mains-fed rectifier, the DC voltage side connection of which is connected to the DC voltage side connection of an inverter of the system and to the first DC voltage side connection of a DC / DC converter of the system, the second DC voltage side connection of the DC / DC converter with the

Energy storage, in particular accumulator arrangement and / or

Double-layer capacitor arrangement and / or ultracap arrangement, is connected, wherein an electric motor, in particular three-phase motor, is connected to the AC voltage side connection of the inverter.

15. System according to one of the preceding claims,

characterized in that

between the DC voltage side connection of the rectifier and the

A DC / DC converter is arranged on the DC-side connection of the supply module, and / or that a controllable semiconductor switch connected in series with the braking resistor is arranged in the housing of the DC / DC converter, and / or that a controllable semiconductor switch connected in series with the braking resistor is integrated on a power module, which has diodes arranged in half bridges and / or controllable semiconductor switches, and / or that the power module is arranged in the housing of the inverter or of the supply module.