WO2013135492A1

WO2013135492A1 - Server system and input circuit

Info

Publication number: WO2013135492A1
Application number: PCT/EP2013/054042
Authority: WO
Inventors: Manfred Götz
Original assignee: Fujitsu Technology Solutions Intellectual Property Gmbh
Priority date: 2012-03-14
Filing date: 2013-02-28
Publication date: 2013-09-19
Also published as: DE102012102159B3

Abstract

The invention relates to a server system (10, 30) comprising a housing (18) for accommodating a plurality of servers (11) and at least two servers (11), wherein each of the servers (11) has at least one power supply unit (12) and an input circuit (15). The server system (10, 30) has at least one secondary voltage supply line (17) arranged in the housing (18), wherein the power supply units (12) of the at least two servers (11) are set up to generate a secondary DC supply voltage from at least one primary AC supply voltage and to pass said DC supply voltage to the at least one secondary voltage supply line (17) arranged in the housing (18). The input circuits (15) of the at least two servers (11) each have a power limitation element (25) for limiting a maximum power consumption of the associated server (11) and are set up to receive an operating voltage for the particular server (11) from the at least one secondary voltage supply line (17) arranged in the housing (18). The invention also relates to an input circuit (15) for a server (11).

Description

description

Server system and input circuit The invention relates to a server system comprising a housing for accommodating a plurality of servers and at least two servers, wherein each of the servers has at least one power supply unit and one input circuit. The invention further relates to an input circuit for a server for use in such a server system.

Server systems of the type mentioned are known from the prior art. For example, from the DE

202010009423 Ul discloses a rack housing with a plurality of load zones, in which rack components in the form of server computers are accommodated in 19-inch rack modules with a height unit in different load zones. The different load zones are assigned to individual phase lines in order to avoid total failure of all load zones in the event of a single external line failure.

From the prior art, other server systems for receiving a plurality of servers are known. For example, so-called blade server systems are known in which a plurality of blade servers are arranged in a common blade server system.

From the prior art, various approaches to Ver ^¬ improve the reliability of server systems are known. For example, one or more power supplies can be kept redundant for each server. In this way, the cost in the manufacture and operation of the Serversys ^¬ tems but increases considerably. In addition, the provision has dundant components also adversely affect the energy efficiency of the server system.

It is an object of the present invention to provide improved devices and methods to be described, which make it possible to describe with respect to the failure of one or more power supplies insensitive server system verhältnismä ^¬ SSIG simple construction and ensures the achievement of high energy efficiency.

According to a first aspect of the invention, a server system comprising a housing for accommodating a plurality of servers is described. The server system comprises at least two servers, each server having at least a power supply and monitor an input circuit and at least one in the housing of the server system located secondary power supply ^¬ line. The power supplies of the at least two servers are adapted to generate from at least one primary supply ^¬ AC voltage a secondary DC supply voltage and to deliver to the at least one sheet arrange ^¬ te in the housing secondary power supply line. The input circuit of the at least two servers each have a power limiting element for limiting a maximum power consumption of the associated servers and are adapted to receive an operating voltage for each server from the at least one arranged in the housing sekundä ^¬ ren voltage supply line.

The server system according to the first aspect provides at least one secondary power supply line arranged in a housing of a server system for distributing a secondary supply DC voltage. At the same time, each server has an input circuit with a power limitation relay. to limit the maximum power consumption of the server. By means of these measures, in the event of the failure of a single power supply unit, be it due to an internal fault or a fault in its primary AC supply voltage, the associated server can be operated via capacity reserves of power supply units of other servers of the server system. By the input circuit to the power limiting element is ensured that the available Capa ^¬ zitätsreserven are not exceeded, for example if a short circuit of a secondary power consumer of the server.

By suitable choice of the output power of the power supplies used in the server and / or the connection of the power supplies to different primary supply lines, a redundancy with respect to the power supplies, the phase lines or the primary supply sources can be ensured.

The input circuit described is suitable both for integration into a power supply unit of a server and for inclusion in a receiving opening of a server system which is provided for receiving redundant power supply units.

According to various embodiments, the power supplies, the input circuits and / or a system management module of a server to a first common control ^¬ be included may be, to enable a power management of the entire server system. Regardless, the power supplies may be connected via a second common control bus to match their power output. According to a second aspect of the present invention, an input circuit for a server is described. The input circuit comprises at least one voltage supply connection for connecting the input circuit to a DC supply voltage, at least one voltage supply output for outputting the DC supply voltage to a power consumer of the server and at least one bus connection for connecting the input circuit to a first control bus. The input circuit has an electrically between the at least one power supply terminal and the at least one power supply output switched power limiting ^element for limiting a power ^¬ recording of the server to a predetermined maximum power ^¬ recording on. In addition, the input circuit comprises at least one coupled to the first bus terminal micro- rocontroller, which is adapted to the power limiting element to specify the maximum power consumption based on we ^¬ least one received via the first control bus control command.

Such an input circuit permits secure connection of a server to a secondary power supplies walls ^¬ rer server computer powered secondary power supply Leis ^¬ processing. In this case, an available capacity limit can be specified via the microcontroller.

The described input circuit is suitable both for integration into a power supply unit of a server of a server system or for setting up a redundant coupling module without its own voltage converter. Further advantageous embodiments of the invention are described in the following detailed description of exemplary embodiments and the dependent claims. The invention will be described below with reference to Ausführungsbeispie ^¬ len with reference to the attached figures. In the figures, similar components of different embodiments are provided with the same reference ^numerals . In addition, different instances of similar components are provided with an alphabetic suffix to better distinguish them. If the reference number is used without an associated suffix, the statements refer to all instances of the associated component. In the figures show:

1 shows a server system according to a first embodiment of the invention, FIG. 2 shows a block diagram of a server system for the server arrangement according to the first embodiment,

3 shows a second server arrangement according to a second

Embodiment of the invention,

4 shows an arrangement comprising a power supply and a re ^¬ dundantes coupling module and

Figure 5 is a connection diagram for servers of a server system.

To clarify the problem of the power supply of server systems, a possible connection scheme will be described in general with reference to FIG. Figure 5 shows an exemplary arrangement of a Serversys ^¬ tems 50 comprising four servers IIa to IId. Each of the servers

11 has each at least one power supply 12 as well as a system component 13, such as a motherboard with a ^¬ is to arranged processor and memory, on.

In the arrangement of Figure 5, the power supplies 12 of the ers ^¬ th and the fourth server system IIa and IId parallel to one another to a first phase line LI of an energy supply network 14 are connected. The power supply 12 of the second server IIb is connected to a second phase line L2 of the power supply network ^¬ fourteenth The power supply 12 of the third server 11c is connected to a third phase line L3 of the power supply network 14. The power supplies

12 each serve to convert a primary AC voltage of the power supply network 14 into a secondary DC supply voltage for operating the system components 13.

The arrangement shown in FIG. 5 effects a distribution of the servers IIa to Ill on the different phases of a power supply network 14. In this respect, in the event of the failure of a single phase of the energy supply network 14, in each case at least two server systems 11 are still available. The arrangement shown in Figure 5, however, does not protect against the failure of the built-in power supplies 12. In addition, the arrangement of Figure 5 has a relatively low energy efficiency, since the operation of all server systems IIa to lld each power supply units 12a to 12d must be turned on. FIG. 1 shows a server system 10 according to a first embodiment of the invention. The server system 10 includes in the illustrated embodiment, four servers IIa to lld. Each of the servers IIa to IId respectively comprises a power supply unit 12, a system component 13, and an input circuit 15, the üb ^¬ SHORT- are arranged in a common housing server. The power supply units 12 of the servers IIa to lld according to FIG. 1 are coupled to a power supply network 14 in the same way as the power supplies 12 of the servers IIa to lld according to FIG.

Unlike in the arrangement of Figure 5, the power supplies 12 are not directly coupled to the Sys ^¬ temkomponenten 13 of the server IIa to IId in the Anord ^¬ voltage according to FIG. 1 Stattdes ^¬ sen provide the power supplies 12, a secondary supply ^¬ DC voltage to a supply terminal 16 of the server 11 is available, which is electrically coupled to a secondary power supply line 17th The secondary power supply line 17 may be a cable connection, a busbar or a conductive track on a so-called backplane or midplane of a server system han ^¬ spindles. The secondary power supply line 17 is disposed within a housing 18 of the server system 10, for example, a standardized 19-inch rack housing, and thus protected from external influences.

The system components 13 are also coupled to the supply terminal 16 via the input circuits 15. Each system component 13 receives its operating current from one or a plurality of the power supply units 12. In this case, its operating power can be wholly or partly derived from the integrated power supply unit 12 of the same server 11 or via the secondary power supply unit. 17, are provided by power supplies 12 of other servers 11.

To protect the connected to the secondary power supply line 17, power supplies 12 from interference of the individual system components 13 15 monitors the input circuit, the power consumption of the system components 13 and limits or interrupts provided on the secondary Spannungsversorgungslei ^¬ tung 17 power to a predetermined limit value. For example, the input circuit 15 may include a so-called power controller that limits the current through the input circuit 15 to a fixed or configurable value. If this limit value is exceeded, the system component 13 may optionally be completely decoupled from the secondary voltage supply line 17 in order to avoid a drop in the secondary DC supply voltage. Alternatively, it is also possible to throttle only individual power consumers of the system component 13 in order to limit their power consumption.

The server system 10 according to FIG. 1 has a number of advantages over the server system 50 according to FIG. In particular ^¬ sondere a failure of a single power supply 12 or a single phase line LI to L3 does not automatically lead to failure of the server IIa to IId. As a rule, the power units 12 installed in the individual servers 11a to 11d are oversized for their operation, so that in the event of failure of only one phase line or of a single power supply unit, as a rule, all system components 13 continue to be supplied with an operating voltage from the remaining power supplies 12 can. If this is still not enough in individual cases for ^¬, for example, because failure together with the first phase line LI two power supplies 12 and the system Components 13, taken together, have an input power that lies beyond the output power provided by the two power packs 12 of the servers IIb and 11c, and at least the operation of the server systems IIa through Lld within the framework of the targeted throttling or switching off of individual system components 13 standing power.

Compared to known approaches, which usually require redundant power supplies and / or a complex, central Regelvor ^¬ direction, the circuitry overhead of the server system 10 is relatively low. On the part of the server system 10, only the secondary Spannungsver ^¬ supply line must be provided 17th On the part of the individual server systems 11 only the provision of a Ver ^¬ supply connection 16 and an input circuit 15 per server 11 is required. Thus, the described improvement can be integrated into simple server systems in a relatively simple and cost-effective manner, such as, in particular, rack server systems with a multiplicity of simply constructed servers.

FIG. 2 shows a server 11 which is suitable, for example, for use in the server system 10 according to FIG. The server 11 comprises a power supply unit 12 and a system component

13. In the system component 13 is, in particular to a motherboard of a server computer with a thereon ^¬ associated processor 21 and a system management module 22. In this case, the processor 21 by way of example a shearing example of typical multiple current consumers of the system component 13. The processor 21 and the system management module 22 are connected in the illustrated embodiment via a system management bus. In the embodiment shown, the power supply unit 12 comprises a converter circuit 23, a microcontroller 24, a power limiting element 25 and a protection circuit 26. The converter circuit 23 is connected to at least one phase line of a power supply network 14 via a primary supply connection 27 on the primary side. The transducers ^¬ circuit 23 provides a secondary DC voltage of for example 12 volts is available, which is delivered to the protection circuit 26 during operation. Optionally, the power supply 12 can deliver a portion of the generated secondary DC voltage or a further voltage generated by an auxiliary converter, for example a standby voltage for supplying the system management module 22 in the switched-off state of the server 11, directly to the system component 13.

In the simplest case, the protective circuit 26 is a so-called decoupling diode, which prevents a feedback of an externally provided secondary DC supply voltage into the converter circuit 23 and a fault in the control circuit thereof. Of course, instead of a simple decoupling diode, an active ^isolating circuit can also be used for selectively disconnecting the converter circuit 23 from the remaining components of the power supply unit 12.

Electrically behind the protection circuit 26, the power supply unit 12 is coupled via a secondary supply connection 16 to a secondary power supply line 17. Via the secondary supply connection 16 both one of the

Transducer circuit 23 generated secondary DC voltage are issued as well as the failure of the converter circuit 23 a externally generated secondary DC voltage can be made available.

The secondary supply terminal 16 is further connected to the power limiting element 25. Behind the power ^{limiting element} 25, the available secondary DC supply voltage is delivered via a connecting line 28 to the system component 13. In the embodiment, it is in the power limitation element 25 effectively to the combination of a current measurement ^¬ circuit and a switch. If the current flow through the power ^{limiting element} 25 ^exceeds a preset maximum value, the switch is opened and thus the power supply from the secondary power supply line 17 to the system component 13 is interrupted.

In the embodiment shown in Figure 2 embodiment, the predetermined maximum value for the permissible current flow can be adjusted indivi ^¬ duel. This serves, in particular, to adapt the possible maximum power consumption of the system component 13 to the available power of the power supplies 12 in operation. For this purpose, communicate in the illustrated embodiment, the microcontroller 24, the system management module 22 and / or the processor 21 via a system management bus 29 with comparable components of other servers 11 or with a central power management unit. Optionally, a microcontroller integrated into the power supply can also be connected to the system management bus 29.

Recognizes the central power management unit and one of the other devices connected to the system management bus 29 Comp ^¬ components such as the microcontroller 24, for example, that half of all available power supplies 12 have failed, the maximum power consumption of each system component 13 is reduced, for example, to half of a maxi ^¬ paint output of a single power supply 12. For example, the power consumption of each Ser ^¬ verse can be limited to 200 watts when the power supply nor ^¬ mally has a maximum output power of 400 watts to ^¬. Such a restriction is non ^¬ achtlich for operating a moderately busy Ser vers 11. Alternatively, in many cases it is also possible, one or more

Disconnect server 11 by interrupting the power supply via the associated power ^limiting element 25 or by controlled shutdown of the server 11 via the Systemmanagementbau ^¬ stone 22 to secure operation of the remaining server 11 of the server system.

In particular, the switching power supplies used in known servers achieve the best energy efficiency in the range of a relatively high utilization of, for example, 50 to 100 percent of the maximum output power. To improve the energy efficiency, it is thus possible, independently of the failure of a power supply unit 12, to switch off individual power supply units 12 in a targeted manner by an energy management unit connected to the system management bus 29, if not all the power supply units 12 are required to provide a required operating energy. If the energy requirement rises, the power supply units can then be switched back on as ^needed . In addition to the respect to the embodiment descriptions ^¬ NEN system management bus 29 which may include some other geeigne- th control signals such as a control signal for

Wake a power supply 12 are used. Instead of an external energy management unit, one of the microcontrollers 24 can also assume the function of energy management. In the illustrated embodiment, the input ^¬ circuit 15 includes the microcontroller 24, the power limiting element 25 and the protection circuit 26 and is fully integrated into the power supply 12. In this way, in addition to the modified power supply 12, only an additional secondary power supply line 17 must be provided in a server system. A further Modi ^¬ fication, in particular the system component 13 or the construction lent refinement of the housing of the server 11 or the server system, however, is not required.

FIG. 3 schematically shows another server system 30 for accommodating a plurality of servers 11 in a common housing 18. In the exemplary embodiment, FIG

Server system 30 to a rack server system, in which a total of 13 slot servers of different heights are included. The individual servers 11 each have two receiving openings 31 and 32 for receiving one power supply module each. The power supply modules can either be

Power supplies 12 or redundant Kop ^¬ pelmodule 33 described below act.

In the illustrated embodiment, a respective power supply unit 12 is received in the first receiving opening 31 and a redundant coupling module 33 is received in the second receiving opening 32. The connection of the power supply units 12 to one or more primary supply lines is not shown in FIG. 3 for reasons of clarity. Unlike in the first embodiment a continuous busbar is in the server system 30 ge ^¬ Mäss Figure 3 is not provided, but in each case a cable connection 34 between two adjacent server modules that together form a secondary Versor- form supply line 17. In this way, the server system 30 can in a relatively simple manner modular expands the ^¬. In the figure 4, an arrangement is shown comprising a power supply 12 and an associated redundant switching module 33, as may be found, for example, in the server system 30 according to Figure 3 Ver ^¬ application. The power supply unit 12 is a so-called hot-pluggable power supply unit 12 for a typically standardized receiving opening 31 of a server

11 with, for example, a height unit. Power supplies 12 of this type have output powers of, for example, 250, 450 or 800 watts. In addition to a primary supply terminal 27 for connecting the power supply 12 sorgungsnetzwerk to a primary energy 14 includes the power supply 12 has two secondary Ver ^¬ sorgungsanschlüsse 16a and 16b. The first Versorgungsan ^¬ circuit 16a serves for providing a first secondary DC voltage, for example, a DC voltage of 12 volts for operation of one or more system components 13. The second supply output 16b is used for providing a second secondary DC supply voltage, for example a so-called stand-by voltage for the supply from even in the off state, the server 11 with a

Power supply coupled components, such as in particular a system management module arranged thereon 22. In the described embodiment, the height of the second sec ^¬ dary DC supply voltage is also 12 volts.

In the illustrated embodiment, the power supply 12 further includes a bus port 41 for coupling the power supply

12 with a first bus system. For example, this may be a general system management bus or a dedicated power management bus. Technically speaking this is a relatively simple fieldbus han ^¬ spindles, such as a so-called I ² C bus. In addition, the power supply unit 12 has a second bus connection 42 which serves to couple the power supply unit 12 to other similar power supply units 12. Also in the second bus connection 42 may be a terminal according to the I ² C protocol, which is used for example for matching rule ^¬ algorithms arranged in the power supply 12 switching converters. Instead, a proprietary control bus or a single control line can be used, which is used to control and / or tuning of the power supplies 12 with each other. Information can be exchanged between the power supply units 12 via the second bus connection 42, which ensures uniform loading of all active power supply units. For example, a blanking ratio for all switching ^{¬ converter} all power supplies 12 can be set evenly.

In the illustrated embodiment, the power supply 12 and the redundant coupling module 33 via a so-called power backplane 43 are interconnected. Via the power backplane 43, further power supply units 12 and coupling modules 33 can be coupled to the described arrangement, in particular the power supply units 12 and coupling modules 33 of other servers 11 of a server system. The redundant coupling module 33 arranged parallel to the power supply unit 12 has the same connections on the backplane 43 side as the power supply unit 12, so that network ^components 12 and coupling modules 33 are structurally compatible with one another and thus mutually replaceable. The redundant switching module 33 comprises in the embodiment shown, ^¬ guide for a microcontroller 24 and a power limitation element 25. The microcontroller 24 is coupled via the first bus 41 to the first data bus. Via the bus connection 41, the microcontroller 24 can communicate with an energy manager, not shown in FIG. 4, which in particular specifies a maximum power consumption of the associated server 11 to be maintained by the power limitation element 25. The power limiting element 25 in the exemplary embodiment is preferably a so-called power management controller which is suitable for limiting the output power or an output current output via a voltage supply output 44 of the redundant coupling module 33 to a system component 13 to a predetermined limit value.

In the exemplary embodiment, the redundant switching module 33 additionally includes an optional feedback path 45 between the first supply terminal 16a for providing the first secondary DC supply voltage and a second supply terminal 16b for providing the second sekundä ^¬ ren DC supply voltage for the standby mode. In the embodiment, the two voltages have the same HOE hey, so that a simple feedback diode 46 to normally USAGE can be ^¬ det, a supply of standby power even when failure of all this, certain

To ensure auxiliary transducers. As already mentioned the power supply unit 12 and the Redun ^¬ Dante coupling module 33 have the same dimensions and external terminals. Thus, a server 11 may optionally be equipped with only egg ^¬ single power supply 12, two power supplies 12 or a combination of a power supply 12 and an redundant switching module 33rd Equipping with only one power supply 12 represents a low-cost minimal equipment that offers no redundancy with respect to the power supply of the associated server 11. An equipment with two power supplies 12 provides a complete redundancy with respect to the used parts of a single network server 11, but leads to increased price ei ^¬ nem thereof. The use of a single power supply 12 in combination with a redundant switching module 33 in conjunction with a plurality of other similar servers 11 in a server system 30 to a relatively high degree of redundancy on the part of the power supply at a circuit technically significantly reduced effort and low cost.

Although the invention with reference to architectures as are known from Rackserversystemen has been described, the disclosed therein input circuit is 15 in particular ^¬ sondere in the form of redundant switching module 33 also for switching set in the so-called blade server systems or other server systems with a plurality of similar servers

and / or power supplies.

Of course, the features described above with reference to various embodiments may be combined in a variety of ways to achieve the benefit associated therewith.

Reference sign list

10 server system

11 servers

12 power supply

13 system component

14 power supply network

15 input circuit

16 (secondary) supply connection 17 (secondary) power supply line

18 housing

21 processor

22 System Management Module

23 converter circuit

24 microcontroller

25 power limiting element

26 protection circuit

27 (primary) supply connection

28 connecting cable

29 system management bus

30 server system

31 first receiving opening

32 second receiving opening

33 redundant coupling module

34 cable connection

41 first bus connection

42 second bus connection

43 backplane

44 power supply output

45 feedback path

46 feedback diode

50 server system

Claims

claims

Server system (10, 30), comprising

a housing (18) for receiving a plurality of servers

(Ii);

at least two servers (11), each of the servers (11) having at least one power supply (12) and an input circuit (15); and

at least one secondary power supply line (17) disposed in the housing (18); in which

the power supplies (12) of the at least two servers (11) are adapted to generate from at least one primary versor ^¬ source AC, a secondary DC supply voltage and to deliver to the at least one in the housing (18) located secondary power supply ^¬ line (17); and

the input circuits (15) of the at least two servers (11) each having a power limiting element (25) for loading ^¬ limitation a maximum power consumption of the associated server (11) and are adapted to an operating voltage for the respective server (11) from the at least one in the housing (18) arranged to receive secondary power supply line (17). 2. server system (10, 30) according to claim 1, wherein the at least one power supply (12) of the at least two servers (11) has an output that ranges from ^¬ at least two servers (11) at least in an operating condition supply with limited power consumption with the secondary DC supply voltage. Server system (10, 30) according to claim 1 or 2, wherein the at least one power supply (12) of a first of the at least two servers (11) is connected to a first primary supply line and ^wherein the at least one network ^¬ part (12) of a second of the at least two servers (11) is connected to a second, different from the first supply line, primary supply line.

Server system (10) according to one of claims 1 to 3, wherein the input circuit (15) at least a first server (11) of the at least two servers (11) in which we ^¬ nigstens a power supply (12) of the first server (11) in ^¬ tegriert is.

Server system (30) according to any one of claims 1 to 3, wherein the at least one first server (11) of the at least two servers (11) at least a first and a second Recordin ^¬ detection port (31, 32) for receiving a respective supply device, wherein the power supply (12) of the first server (11) is accommodated in the first receiving opening (31) and the input circuit (15) of the first server (11) is accommodated in the second receiving opening (32) of the first server (11).

A server system (10, 30) according to any one of claims 1 to 5, wherein the power supplies (12) are connected to a first common control bus so that an energy manager coupled to the first common control bus can perform at least one of the following actions: activating a predetermined one Power supply (12); Deactivating a predetermined power supply (12); and setting a predetermined output power of a predetermined power supply (12). Server system (10, 30) according to any one of claims 1 to 6, wherein the input circuits (15) of the at least two servers (11) each at least one microcontroller (24), which are ^¬ closed at a first common control bus so that an energy manager coupled to the first common control bus can perform at least one of the following actions: activating the system component (13) associated with a predetermined input circuit (15), deactivating the system component (13) associated with the predetermined input circuit (15); and specifying a maximum power consumption for the system component (13) associated with the predetermined input circuit (15).

Server system (10, 30) according to any one of claims 1 to 7, wherein the at least two servers (11) each Wenig ^¬ least include a system management module (22) which are connected to a first common control, so that a joint with the first Control bus gekop ^¬ pelte energy manager at least one of the following actions: Start a predetermined server

(11); Stopping the predetermined server (11); Activating a power-saving state of the predetermined server

(11); and setting a power profile of the vorbe ^¬ voted server (11).

Server system (30) according to one of claims 1 to 8, wherein the power supply units (12) of the at least two servers (11) are connected to a second common control bus and adapted to match their power output, in particular by even distribution the output power to be generated on all active power supplies (12) of the server system (30).

An input circuit (15) for a server (11) comprising: at least one power supply terminal (16) for connecting the input circuit (15) to a DC supply voltage;

at least one power supply output (44) for giving the DC supply voltage to a power consumer of the server (11);

at least one bus connection (41) for connecting the input circuit (15) to a first control bus;

an electrically at least one between the power supply terminal (16) and the at least one clamping ^¬ voltage supply output (44) switched performance-grenzungselement (25) for limiting a Leistungsauf ^¬ acquisition of the server (11) to a predetermined maximum power consumption; and

at least one with the first bus (41) gekop ^¬-coupled microcontroller (24) which is adapted to the power limiting element (25) the maximum Leis ^¬ tung receptive to specify based on at least a control command received via the first control bus.