法国专利FR3023019A1 MODULE FOR COMPENSATION OF MICROCOUPONS OF POWER SUPPLY OF A SERVER

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专利摘要:
The invention relates to a module for compensating for the power supply of at least one server, comprising at least one capacitive storage element (12) of electrical energy that can then be released in order to compensate for said micro-cuts, characterized in that it also comprises a controller (10) for charging and / or discharging said capacitive storage element (12), limiting the charging and / or discharging current of said capacitive storage element (12) sufficiently to make said module insertable and / or extractable even during operation of said server.
公开号:FR3023019A1
申请号:FR1456044
申请日:2014-06-27
公开日:2016-01-01
发明作者:Georges Lecourtier
申请人:Bull SA；
IPC主号:

专利说明:

[0001] FIELD OF THE INVENTION The invention relates to the field of power supply voltage compensation modules and the field of computers incorporating such compensation modules.
[0002] BACKGROUND OF THE INVENTION According to a first prior art, it is known electronic systems in which the failure of the power supply devices is treated at the alternating current level (AC for "alternating current" in English). For example, an uninterruptible power supply (UPS) contains a rectifier, batteries, and an uninterruptible power supply to compensate for interruptions for a few minutes of the supplied AC power. by the sector. To support a failure of the alternating voltage converter (ACDC) for "Alternative Current Direct Current" or the power supply unit (PSU), it may to be redundant, for example according to a 1 + 1 scheme. In this case, the two outputs of the power units are interconnected at the motherboard of the information processing equipment to form a DC power rail, for example a 12V rail. This 12V rail feeds downstream a number of charging points which are direct voltage DC voltage converters supplying the different supply voltages of the integrated circuits. The motherboards support several tens of different charge points whose power output ranges from a few hundred watts to a few watts each. In such a system, the failure of a single point of charge generally leads to a fatal error that results in the loss of data in volatile memory.
[0003] According to a second prior art, it is known to use a backup power supply system based on a power supply voltage compensation module which concerns the reliability and availability of the systems in which it is integrated. It applies to information processing systems which generally contain volatile memory devices and power supply devices. Without a compensation module, any major failure of the power supply device causes the loss of data stored in the volatile memories. This compensation module performs the function of a backup power supply device to ensure both an automatic data backup and easy maintainability of the associated backup system. Maintenance of this type of compensation module is tricky. Indeed, when the capacitive storage elements of this type of compensation module must be changed or verified, the module can be extracted only when the entire system is stopped, that is to say does not work not. The servers in the system must be turned off. SUMMARY OF THE INVENTION The object of the present invention is to provide a module for compensation of electrical power supply shortages at least partially overcoming the aforementioned drawbacks. More particularly, the invention aims to provide a power supply microcoupage compensation module for extracting it suddenly from the system, even during the operation of said server or said servers of the system. We also speak of "hot extraction". More particularly, the invention also aims to provide a compensation module power supply microcouures for reinsertion suddenly in the system, even during the operation of said server or said servers of the system. We also talk about "hot reintegration". Capacitive storage elements being capacitive elements capable of storing a large amount of energy, in particular when they are, for example, super capacitors, their extraction then "hot" re-insertion, that is to say during the operation of the server or servers managed by the compensation module that contains them, seems a challenge. Indeed, their large capacity resulting in the storage of large amounts of energy, faster releasable because of their capacitive appearance, makes high the risk of excessive current draw resulting in a momentary collapse of the voltage level of the power supply. and therefore also increases the risk of system malfunction during "hot extraction" and / or "hot insertion". There is therefore a technical bias against a "hot extraction" and / or "hot insertion" of a component comprising one or more capacitive electrical energy storage elements having a high storage capacity . The invention seeks to reverse this technical prejudice by integrating a load current and / or discharge current limitation of the capacitive storage element (s) and a management of this current limitation by a controller, thus making possible their "extraction and / or hot insertion ", without any significant risk of excessive current draw which could cause a significant disturbance of the power supply of the system which could in turn lead to a malfunction of the servers and a loss of data in volatile memory in this or these servers .
[0004] To this end, the present invention proposes a module for compensation of micro-cuts of the power supply of at least one server, comprising at least one capacitive element for storing electrical energy that can then be released in order to compensate for said micro-cuts, characterized in that it also comprises a controller for charging and / or discharging said capacitive storage element, limiting the charging and / or discharging current of said capacitive storage element sufficiently to make said module insertable and / or extractable even during operation of said server .
[0005] To this end, the present invention also proposes a computer comprising: one or more microprocessors, several dual memories each comprising a random access memory, a non-volatile memory, and a controller adapted to save the contents of the random access memory in the non-volatile memory and for reconfiguring the random access memory with the contents of the non-volatile memory, a main power supply rail of said microprocessors and said dual memories during the operation of said computer without a power supply microcircuit, intended to be connected to an external power supply, a secondary rail supplying said dual memories with power during the operation of said computer at least when exceeding a predetermined power supply cut-off time, said secondary power supply rail not supplying the microprocessors, a feed-back compensation module electrical including el capacitive electrical energy storage elements, which is adapted to supply electrical power, to said main supply rail, during power supply shortages, but only during said predetermined power supply cut-off period, and which is also adapted to supply electrical power to said secondary supply rail during power supply shortages after exceeding said predetermined power supply cut-off time. The secondary supply rail is also called emergency power rail.
[0006] A micro-power supply corresponds to a brief interruption of the sector supplying an alternating current. The computer according to the invention or according to preferred embodiments of the invention can use a power supply voltage compensation module is according to the invention or according to preferred embodiments of the invention. The computer can be a server managed by a compensation module. The same compensation module could also manage multiple servers. The server power supply voltage compensation module connects directly to the power supply board, without the need for cables between this compensation module and this power supply board. According to preferred embodiments, the invention comprises one or more of the following features which can be used separately or in partial combination with one another or in total combination with one or the other of the aforementioned objects. Preferably, the compensation module also comprises an auxiliary power switch connecting said controller to said capacitive storage element and changing state, during the extraction of said module during the operation of said server, so that said controller is powered by said capacitive storage element. Thus, during a power supply short-circuit, this quasi-"temporary" self-supply of the controller, in fact by the adjacent capacitive storage element or elements of said controller in the compensation module, enables this controller to ensure the sequencing operations management micro power cuts, and this while this controller is also a victim, like other elements of the network, this microcoupure to manage. During the extraction of said module during the operation of said server, here preferably means at the beginning of the extraction of said module, before the extraction of said module is effective and completed, the time to properly manage this extraction of said module.
[0007] Preferably, the compensation module also comprises a discharge switch which connects a discharge resistor to said capacitive storage element and which is controlled by said controller during extraction of said module during operation of said server. The capacitive storage element or elements are capable of storing a large amount of energy in order to supply the controller with at least the necessary time to manage a brownout and to be able to supply dual memories with the time necessary to save the data. This stored energy can therefore be important, it can be a source of danger for the operator who extracts it suddenly. The discharge resistance makes it possible to discharge the bulk of this energy so as to render the operator without significant risk of handling this compensation module during a sudden extraction, also called "hot extraction". Preferably, the compensation module comprises a plurality of capacitive storage elements and / or it compensates for power supply shortages occurring on a supply rail of one or more servers. Thus, a single compensation module may be sufficient to manage an electrical network. Preferably, the capacitive storage element or elements are arranged so as to provide a backup power supply at a time during a brownout and during a backup of the contents of one or more volatile memories to one or more non-volatile memories. volatile. To these emergency power supply functions, then adds the temporary power supply function of the controller of the compensation module, during extraction and or "hot" insertion of this compensation module. Preferably, the capacitive storage element or elements comprise one or more super capacitors. Supercapacitors, although of a more limited capacity than other energy sources, for example electrochemical, can however deliver their peak power a much greater number of times during the lifetime of the system, and thus manage a number significantly larger power supply microswitch. Preferably, the compensation module comprises a first power supply terminal which is intended to be connected to an external power supply and which is connected to said capacitive storage element so as to allow charging from said first power supply terminal and their discharging to said first power supply terminal and a second power supply terminal which is intended to be connected to said external power supply and which is connected to said controller so as to supply electrical power to said controller. The capacitive storage element (s) thus store energy from the mains during normal operation of the mains, which they can then restore to the controller during a power failure. Preferably, the compensation module has no decoupling capability which is connected to said first power supply terminal and whose value exceeds 500 nanofarads. Thus the somewhat complex management of these capabilities does not interfere or complicate the management of the micro power supply by the compensation module, nor the management of the "hot" extraction of this compensation module.
[0008] Preferably, the compensation module comprises a first power supply terminal which is intended to be connected to an external power supply, a DC voltage direct voltage converter which is located between said capacitive storage element and said first power supply terminal. and which includes an integrated current limiter which is activated upon insertion of said module during operation of said server. Thus, the risk of excessive current draw, which could be caused by the uncontrolled load of the capacitive storage element (s), and which could cause a significant drop in voltage on the main supply rail, is avoided.
[0009] The external power supply integrates, meanwhile, a DC voltage converter, which converter is located between the input power network and said first terminal. Preferably, the compensation module comprises a second power supply terminal which is intended to be connected to an external power supply, a DC voltage direct voltage secondary converter and a current limiter which are situated between the said controller and the said second terminal. 'food. Thus, in normal operation of the sector, the controller is powered via the sector, without excessive peak of current. Preferably, said controller comprises a function of detecting a sudden extraction of said module which function is connected to a pin which is shorter than the other pins so as to indicate the operation of sudden extraction before this one is completely realized. Thus the controller detects and can manage very early a sudden extraction operation of the capacitive storage elements before it is effective and therefore even before being deprived of the power supply from these capacitive storage elements . This is enabled by the different length of the plug pins of the compensation module in the computer. Preferably, said controller comprises a function for detecting said brownouts which function sends one or more power consumption reduction requests to one or more servers as soon as a brownout is detected. Thus, as soon as a micro-cut is detected, most of the electrical elements managed by the controller will rapidly reduce their power consumption, allowing the capacitive storage elements to manage even short-lasting power cuts, despite their storage capacity. energy that remains relatively limited compared to conventional power sources, for example electrochemical type.
[0010] Preferably, the compensation module is insertable and / or extractable even during the operation of said one or more servers. Preferably, said or at least some of said servers each comprise one or more microprocessors and / or one or more memories. Preferably, said random access memory is a DRAM memory and said non-volatile memory is a FLASH memory. Preferably, said computer is a supercomputer comprising several microprocessors.
[0011] The more the system, dependent on the same mains power supply and being managed by the same module for compensation of microcuts of this power supply, is complex and or contains sensitive data to be backed up, plus the compensation module according to the invention, particularly effective for a relatively reduced complexity and power consumption, is interesting. According to preferred embodiments of the invention, the power supply voltage compensation module makes it possible, with respect to an SSD type disk backup solution, to limit the consumption of the system during the critical operation to a minimum during which the processors and the input-output circuits are not powered, only the memory being powered. The size and cost of the capacitive storage elements are thus greatly reduced. According to preferred embodiments of the invention, the power supply voltage compensation module makes it possible, with respect to an electrochemical battery energy storage solution, for example of the Lithium-Ion or Lead type, to continue to delivering the peak power, which is for example a level of 1400W (about 120A under 12V), up to 500,000 times during the lifetime of the system, while it is limited to only about 1000 times for the electrochemical batteries.
[0012] According to preferred embodiments of the invention, the power supply voltage compensation module makes it possible, with respect to a solution where the group of capacitive storage elements is charged at a voltage that is clearly greater than the supply voltage. external, to dispense with power converter between the charge voltage level of the capacitive storage elements and the voltage level of the external power supply. This reduces the cost and bulk of the implementation of the main switch of the compensation module which can be reduced to a single power transistor operating in switching mode. This single transistor will then cause only a very small increase in silicon temperature. Other features and advantages of the invention will appear on reading the following description of a preferred embodiment of the invention, given by way of example and with reference to the accompanying drawings. BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 schematically shows an exemplary block diagram of a computer motherboard using a power supply microcontroller module according to one embodiment of the invention. FIG. 2 diagrammatically represents an example of a block diagram of a card of a module for compensation of electrical power cuts according to one embodiment of the invention. FIG. 3 diagrammatically represents an example of a dc voltage converter according to one embodiment of the invention. DETAILED DESCRIPTION OF THE INVENTION FIG. 1 schematically shows an example of a block diagram of a computer motherboard using a power supply microcoupage compensation module according to one embodiment of the invention. A computer or a server will be used indifferently to cover the same type of device. The computer comprising this compensation module will be able to support both the short interruptions of the mains inputs without altering the operation of the system, withstand the long interruptions of the mains inputs without loss of volatile memory data, withstand single faults (as opposed to multiple failures) of the majority of load points and power modules without loss of data, support maintenance by "hot" exchange of power modules as well as capacitive storage module modules of the compensation module. For this purpose, the circuitry of the computer and especially the circuitry of the compensation module, detailed in FIG. 2, make it possible to detect the occurrence of a supply micro-cut and the switchover to the local energy source, detect long interrupts and save volatile data in a non-volatile memory area, perform "hot" exchange of a power module or capacitive storage element, and reboot the system on the saved data. In FIG. 1, there is a module 1 for compensating power supply shortages, several power supply modules 2, a plurality of memory cards 3, a converter 4 of the ORing type, an external power supply 5 connected to the mains supplying an alternating current, a main rail 9 of power supply, an auxiliary rail 7 for starting power supply of the system, a secondary supply rail composed of sections 8 and 6 located on either side of the converter 4.
[0013] Each of the rails 6, 7 and 9 is connected to the ground via a decoupling capacitor. By definition, the term ORing means "put in OR", that is to say to bring together two power supplies in parallel through power MOS transistors whose gates are controlled by the drain-source voltage differential making it possible to obtain "Perfect diodes". Components 1 to 4 have different pins connected to different electrical signals. The signal P12VSB corresponds to the input power for starting the system: its value is 12V. The signal P5VSUS corresponds to the output power supply for managing the control circuits on the motherboard during the backup operations: its value is 5V. This output power is also used in the compensation module 1 extractable "hot". The signal P 12V corresponds to the main power supply of the motherboard: its value is 12V.
[0014] This rail is used both in input and output at the interface of the compensation module 1. The signal VMBK corresponds to the support or support power supply, also called backup power, used during the data backup phases . The signal UCKILL is the input signal making it possible to detect a "hot" or sudden extraction of the compensation module 1. The PMBUS signal, circulating on the bus 12C, makes it possible to drive the controller of the compensation module 1 by a microprocessor of maintenance mounted on the motherboard. The PROCHOT signal is the output signal that causes the motherboard processors to switch to a low power mode during a power down. The memory cards 3 each comprise one or more dual memories 31, each composed of a volatile random access memory 32 and a non-volatile memory 33, memories 32 and 33 both managed by a controller 34. The dual memory 31 is of type NVDIMM (for "Non Volatile Dual in Line Memory Module" in English). This dual memory 31, of NVDIMM type, consists for example of the association of a memory 32 in volatile DRAM technology and a memory 33 in non-volatile flash technology, associated with an onboard controller 34 for managing backups. and data restores. A plurality of power inputs provide power to each dual memory 31. At least one of these inputs is from a local power source. The number of dual memory 31 can be quite large by motherboard, for example 48 per server. In normal operation, the power consumed by these dual memories 31 can reach a significant percentage of the total power dissipated by the server. As an example and digital illustration, the 48 dual memory 31 dissipate 480W for a 1400W server, or 34% of the total power dissipated. On the other hand, in a backup mode, the consumption of dual memories 31 is much lower, for example of the order of 240W, ie 17% of the total power dissipated. All of these dual memories 31 are grouped on eight memory daughter cards, each supporting up to six dual memories 31 with a capacity of 4GB and consuming 10W maximum active and 5W backup, associated with eight daughter cards. input-output dissipating each ten watts. The two power supply modules 2 correspond to two 12V power supply modules arranged in redundancy 1 + 1, having an auxiliary 12V standby output for starting which corresponds to the P12VSB signal. The computer shown in FIG. 1 also comprises two microprocessor slots of 150W of dissipation each (not shown in FIG. 1), as well as a compensation module 1 supporting 5 super capacitors of 2000F placed in series. The overall power consumption of the computer in operation is thus of the order of 1400 W. It is the local power sources that make it possible to ensure the backup of the state of the system in a non-volatile memory for any simple failure. power supply circuits. The computer shown in Figure 1 can thus withstand simple failures with a minimum of impact on its operation. It can also, if necessary, allow to replace the faulty modules to avoid having to undergo a second failure while the system is already in degraded mode. In this regard, a mains power cut is considered a simple power failure. The compensation module 1 acts as a backup power supply in the following two cases, namely on the one hand to ensure the operation of the computer during brief interruptions of the sector and on the other hand to ensure the backup volatile memory content in the case of long sector interruptions. The compensation module 1 then plays the role of a third power supply module that acts as a backup of the two standard power supply modules 2. It adds to the interface of these two power supply modules 2 a secondary supply rail 8 which is at the input of the converter 4 supplying the backup voltage to the memory subsystem. This separation makes it possible to completely cut the power on the microprocessors, the disks and the input-output circuits during the operation of saving the contents of the volatile memories 32 in the non-volatile memories 33. FIG. 2 schematically represents an example of a block diagram of a circuit board of a power supply microcoupage compensation module according to one embodiment of the invention. The compensation module 1 comprises a controller 10, a power switch 11, capacitive storage elements 12, a DC voltage converter DC of the step-up type, a DC voltage converter 16 with a first DC voltage. step-up stage 14 and a second step-up stage 15, a step-down DC voltage converter 17, a step-down DC voltage converter 18, a device 19 whose output generates a stabilized voltage P5VSUS of a 5V value, all of the elements 17, 18 and 19, forming a DC voltage DC secondary converter, a discharge resistor 21. The power switch 11 controls access to the first terminal 22 of connected to the external power supply 5, both the capacitive storage elements 12 and the main converter 16. The converter 17 is connected to a power supply 7 by the second supply terminal 23. The passage of the discharge current of the capacitive storage elements 12 to ground through the discharge resistor 21 is controlled by the transistor 24 itself controlled by the controller 10. The capacitive storage elements 12 are advantageously super capacitors. The device 19, for example of the ORing type, integrates both an auxiliary power switch function and a current limiter function. The interface of the compensation module, with the other functions of the motherboard, is realized by the following signals circulating on the corresponding pins. The power supply P12V is connected to the external power supply 5 connected to the power supply modules 2 which are themselves equipped with AC voltage converters in direct voltage and connected to the mains. These two power supply modules 2 can preferably operate in 1 + 1 redundancy. The level of the external power supply 5 is 12V. Each power supply module 2 provides a low power P12VSB power supply allowing the system to start as soon as the mains is present. This P12VSB power supply also has a value of 12V. The backup power supply VMBK supplied by the compensation module 1 is connected to the converter 4 which is described in FIG. 1. The signal UCKILL is connected to ground (GND for "Ground" in English) of the motherboard by a pin-type pin shorter than the others. The P5VSUS power supply and the PROCHOT and PMBUS signals are connected to the power management functions of the motherboard which are not shown in this figure 2 for the sake of simplicity.
[0015] In the compensation module 1, a low-power secondary converter 17 starts automatically when the auxiliary power supply P12VSB is mounted and supplies a first auxiliary voltage P5VSUS to the controller 10. The step 14 of the main converter 16 generates a power supply P21V , a value of 21V, which is used by the step-down stage 15 of the main converter 16 and by the control circuits of the doors of the power switch 11. The controller 10 starts the step-down stage 15 of the main converter 16 to ensure the loading of the storage elements 12 connected between the mass and the VCAP power rail. On this power rail VCAP are also connected the power switch 11, the converter 13 and the discharge resistor 21. The controller 10 is capable of managing all local voltages such as P12V, VBAT and VMBK. The controller 10 can be realized by means of a CPLD circuit ("Complex Programmable Logic Device" in English language), an FPGA ("Field Programmable Gate Array" in English language), a microcontroller type DSP ("Digital Signal Processor" in English) or a combination of these elements. Its role is to sequence the charging and discharging operations of the capacitive storage elements 12 in the different phases of operation, which are the powering up of the system, the detection of a mains power supply, the detection of a mains power failure with or without data backup on non - volatile memory, "hot" exchange of the compensation module 1.
[0016] On power-up, the converter 17 starts the controller 10. The power switch 11 is kept OFF by the signal UCX from the controller 10. The controller 10 starts the step-down stage 15 of the converter 16 using the UCC signal. The step-down stage 15 of the main converter 16 charges the capacitive storage elements 12 to constant current until they reach their nominal voltage, and then goes into floating mode. When the VCAP power rail reaches a first determined threshold, the converter 18 starts and comes to support the converter 17 by means of the transistors of the ORing device 19 whose output is the signal P5VSUS of a value of 5V which supplies the controller 10 When the VCAP power rail reaches a second determined threshold, the converter 13 is started by the controller's UCW signal and supplies the VMBK back-up power to the motherboard of the computer shown in FIG. voltage, the capacitive storage elements 12 have been isolated from the main supply rail P12V by the power switch 11. They do not therefore short circuit the outputs of the power supply modules 2 shown in FIG. In their absence, the "hot" connection of the compensation module 1 would cause the disjunction of these power supply modules 2. When detecting a brownout, the controller 10 d detects a drop in the voltage level on the P12V main supply rail by means of a threshold comparator and reacts in less than a few las by closing the power switch 11. The internal resistance of the capacitive storage elements 12 and the power switch 11 is determined so that the main supply rail P12V stabilizes just at a first threshold VT1. During a determined time Ti, which is generally a few ms, the capacitive storage elements 12 provide the motherboard of the computer with its nominal power. Beyond Ti, the controller 10 sends the signal PROCHOT which asks the microprocessors of the motherboard to switch to low power mode. With the microprocessors available today, the power reduction can reach -80% compared to the nominal power. The response time T2 of this load drop is less than lms. As soon as the brownout ends, the supply voltage P12V returns to its nominal value because the power supply modules 2 have restarted and they are again able to supply normal power to the motherboard.
[0017] During the seconds following the brownout, the step-down stage 15 of the main converter 16 recharges the capacitive storage elements 12 at their nominal voltage. The recharge time is proportional to the actual duration of the brownout. When detecting an interruption of the external power supply of the sector with data backup in non-volatile memory, the controller 10 detects a decrease in the voltage level on the main supply rail Pl2V by means of a threshold comparator and reacts in less than a few las by closing the power switch 11. The internal resistance of the capacitive storage elements 12 and the power switch 11 are determined so that the main supply rail P12V stabilizes just at the level of this first threshold VT1. During a determined time Ti, which is generally a few ms, the capacitive storage elements 12 provide the motherboard with its nominal power. Beyond Ti, the controller 10 sends the signal PROCHOT which asks the microprocessors of the motherboard to switch to low power mode.
[0018] With the microprocessors available today, the power reduction can reach -80% compared to the nominal power. The response time T2 of this load drop is less than lms. During a determined time T3, beyond T1 + T2, the controller 10 makes the assumption that the drop of the P12V signal originates from a brownout and waits. While waiting, if, at the end of T1 + T2 + T3, the voltage of the signal P12V is not raised above the first threshold VT1, the controller 10 goes into the data backup phase on non-volatile memory. At this time, the controller opens the power switch 11, which has the effect of dropping the voltage of the signal Pl2V below the first threshold VT1. The capacitive storage elements 12 are thus isolated from the main supply rail Pl2V and the remaining energy will be used to supply the backup rail VMBK during the data backup on non-volatile memory. Beyond T1 + T2 + T3, and for a time T4 the converter 13 generates a regulated voltage of 12V on the VMBK spare rail. The particular topology of this converter 13 makes it possible to guarantee the stability of the output voltage as well if the voltage value on the VCAP power rail is lower than the voltage value on the VMBK backup rail than if this voltage value on the VCAP power rail is greater than the voltage value on the VMBK power rail. Thus, the system operates even in the case of low load where the value of the voltage on the VCAP power rail would not have fallen below the first threshold VT1 at the end of the period T1 + T2 + T3. The compensation module 1 does not have a bulk capacitor ("bulk" in English) on the main supply rail Pl2V to avoid disturbing the voltage in "hot" exchange operations.
[0019] On the other hand, the circuits of the motherboard are designed in such a way that the emergency rail VMBK may comprise output capacitors, necessary for the proper operation of the converter 13. In fact, the diodes of the converter 4 of the ORing type mounted between the two VMBK and VBAT sections of the emergency rail (only visible in Figure 1) block any current draw on the main power supply P 12V rail of the motherboard during insertion "hot". In summary, the compensation module, shown in FIG. 1, performs two functions, namely power compensation during power mains interruptions and provision of backup power to dual memories during data backups. to a mains power failure, all for a structure and complexity of the system that remains relatively simple, so relatively inexpensive. The compensation module 1 can supply a sustained voltage to the motherboard for the critical circuits during the power failure phases, that is to say for the circuits which limit the impact of the power loss with respect to of all non-volatile memories. This improves the reliability of the system. Capacitive storage elements 12, and in particular supercapacitors, are more energy efficient than some other uninterruptible power supply systems. This therefore reduces the overall power consumption of the system. The compensation module 1 has in particular the interesting property of being exchangeable "hot", that is to say without stopping the system. In fact, during a sudden or "hot" extraction of the compensation module 1, the controller 10 remains self-powered by the residual energy contained in the capacitive storage elements 12. This temporary self-feeding makes it possible to manage at best the discharge cycle through the discharge resistor 21 clearly indicating to the maintenance operator that the discharge is not complete. Suitable indicators, for example light-emitting diodes, signal the danger of remaining energy and thus allow the maintenance operator to wait for the right moment before intervening inside the compensation module to carry out its maintenance. This improves the electrical safety of the system. FIG. 3 diagrammatically represents an example of DC voltage converter according to one embodiment of the invention. The electrical diagram being self-explanatory, since it includes all the component references and all the numerical values, will not be described in greater detail. This electrical circuit represents an example of the internal circuitry that can be used for the converter 13 supplying the emergency rail 8 on which the signal VMBK has a value of 12V. Some scenarios will now be described. These scenarios use the preferred examples of computer and compensation module described, with the preferred numerical values given. These scenarios give quantified results in terms of power consumption and storage of electrical energy. In these scenarios, the capacitive storage elements are super capacitors, and will be referred to as such.
[0020] In a first normal operating scenario, the unit dissipates in normal mode 860W, which leads taking into account the efficiency of the converters, which is about 80%, and the own consumption of the cooling devices, which is about 200W, to a server consuming 1300W. The energy reserve is constituted by the set of supercapacitors of five cells of 2000F in series, ie 400F equivalent, charged under 12,5V. By neglecting the parasitic resistance of the transfer switches and the supercapacitors 12, the usable value of the stored energy is therefore equal to 1/2 * C * V2 = 31250J. Continuous voltage DC voltage converters located between the VCAP power rail and 12V main and start power rails, as well as the VBAT signal backup rail, are considered to have an average efficiency of 70% this value being limited by the internal resistance of the super capacitors 12 themselves. So a consumption of 1300W for 4ms will be responsible for a reduction of stored energy equal to 1300 * 0.004 / 0.7 7.5J.
[0021] Or a second scenario of the detection of a brownout of duration equal to 250ms, which simultaneously affects the two AC inputs of the two power supply modules 2, AC1 and AC2. The case where only one is affected is trivial since the two power supply modules 2 are redundant 1 + 1 and then one would take over the other. After a half-wave, for a maximum of 10ms, the AC FAIL signals are transmitted by the power supply modules 2 to the controller 10 of the compensation module 1. The controller 10 sends the microprocessors a low power request signal (LPRQ for " Low Power Request "in English) which, in the case of an Intel Xeon socket on a Brickland platform can be received by its PROCHOT # bidirectional pin. When the signal is activated by the platform, the microprocessor reduces its power consumption in less than lms to a first power level "Pthrottle", then, in less than 4ms to a second level "PL2" power configurable by the "BIOS setting" . This pin can be advantageously configured in "Fast PROCHOT #" mode which makes it possible to obtain the first reaction on the consumption in less than 100 seconds.
[0022] In this second scenario, the power consumption on the supercapacitors 12 is determined by the level adjustment "PL2" and by the residual consumption of the platform through its inputs and outputs. The consumption of the system analyzed is, in this "PL2" state, of the order of 250W. The clock frequencies of the microprocessors could be set to their minimum value, therefore the memory and input-output activity is also reduced to a minimum. The cooling fans may optionally be momentarily stopped by the controller 10, the thermal inertia of the radiators allowing such an operation without risk of overheating of the electrical circuits. The energy consumption on the reserve of 28800J is still very low in this case. It amounts to 7.5 + 87.8 = 95.3J, ie less than 0.3% of the energy stored. The final voltage on all super capacitors 12 will be almost unchanged.
[0023] A third scenario of the detection of a microbreak lasting between 250 and 800 ms. The system will decide, after 250ms to start the backup of the volatile memory 32 in the non-volatile memory 33 inside the dual memory 31, while keeping the possibility of restarting the operation instantly in case the sector returns before the expiry of the 800ms duration. The operating system (OS for "Operating System" in English) is stopped and all caches are "flush", that is to say imaged, that is to say converted quickly into RAM (DRAM for "Dynamic Random Access Memory" in English). This operation is very brief, typically less than lms. From this point, only the memory consumes to copy the image in the non-volatile memory, for a value equal to 240W. The writing speed being 4GB by 30s per dual memory 31, only a small part of the image will be copied in 800ms. The energy consumption on the 31250J reserve is 7.5 + 87.8 + 188.5 = 284J, which is less than 1% of the energy stored. The final voltage on all super capacitors 12 will be equal to 12.44V.
[0024] Either a fourth scenario of the detection of a mains power failure lasting more than 800 ms. The duration of 800ms being exceeded, the management controller will lose control of the system and dual memories 31 will finish the data backup in standalone mode. If the sector is restored before the end of this backup, this backup will still have priority over the recovery by hand by the controller who will have to wait for the end of the writes in non-volatile memory for reasons of coherence of the memory image. The cooling fans here must be stopped by the controller 10 to avoid consuming unnecessary power on the energy reserve. By keeping a write speed of 4GB by 30s per dual memory 31, the duration of the backup operation being at most equal to 30s since the 48 dual memories 31 operate in parallel, the energy consumption on the reserve of 31250J therefore, it is 7.5 + 87.8 + 188.5 + 7200J = 7484J, or about 25% of the energy stored. The final voltage on all super capacitors 12 will be equal to 10.9V. There is even more room to support dual memories 31 of higher capacity. Either a fifth scenario of a hot replacement of a compensation module 1. The compensation module 1 extractable is removed by the maintenance operator without intervention of the management controller. This mode is sometimes referred to as "hot" or "hot" extraction. However, to avoid losing backup data, a light, for example light emitting diode, visible to the operator, reports any backup operation in progress. The operator will have to wait for the indicator to go out before carrying out this sudden extraction. The indicator being off, as soon as the module is removed from its connector by at most 1 mm, a short pin disconnects from the backplane and indicates to the onboard controller 10 that the compensation module 1 is disconnected from the system.
[0025] Since the controller 10 is self-powered by all the super capacitors 12, it forces the opening of the power switch 11 to avoid any undesirable effects at the time of the separation of the power pins on the main power supply rail 9. 12v. In addition, the controller 10 can automatically perform the energy discharge operations to allow a repair intervention on the compensation module 1 without danger to the maintenance operator. The power switch 11 remains open as long as the residual voltage remains above a very low value of the voltage on the VCAP power rail. At the reinsertion of a new module, therefore not loaded, the controller 10 is powered from the power input of 12V and therefore allows a load of all super capacitors 12 under controlled current conditions. This current limit, for example 3% of the maximum current of the power supply modules 2, makes it possible to recharge the compensation module 1 without requiring oversized power supply modules 2 in output current.
[0026] Of course, the present invention is not limited to the examples and to the embodiment described and shown, but it is capable of numerous variants accessible to those skilled in the art.

权利要求:
Claims (17)
[0001]
REVENDICATIONS1. Module for the compensation of micro-cuts of the power supply of at least one server, comprising at least one capacitive storage element (12) of electrical energy then releasable to compensate for said microcuts, characterized in that it also comprises a controller (10) ) charging and / or discharging said capacitive storage element (12), limiting the charging and / or discharging current of said capacitive storage element (12) sufficiently to make said module insertable and / or extractable even during the operation of said server.
[0002]
2. Power supply microswitch compensation module according to claim 1, characterized in that it also comprises an auxiliary power switch (19) connecting said controller (10) to said capacitive storage element (12) and changing state, during extraction of said module during operation of said server, so that said controller (10) is powered by said capacitive storage element (12).
[0003]
Electric power cutoff compensation module according to claim 1 or 2, characterized in that it also comprises a discharge switch (24) which connects a discharge resistor (21) to said capacitive storage element (12). and which is controlled by said controller (10) during extraction of said module during operation of said server.
[0004]
4. Power supply microswitch compensation module according to any one of the preceding claims, characterized in that it comprises a plurality of capacitive storage elements (12) and / or that it compensates for power supply shortages occurring on a supply rail (5) of one or more servers.
[0005]
Power supply micro-cut compensation module according to one of the preceding claims, characterized in that the capacitive storage element (s) (12) is arranged to supply a back-up power supply at a time when a micro-cut and during a backup of the contents of one or more volatile memories to one or more non-volatile memories.
[0006]
6. Power supply microswitch compensation module according to any one of the preceding claims, characterized in that the capacitive storage element (s) (12) comprise one or more super capacitors.
[0007]
7. Power supply microswitch compensation module according to any one of the preceding claims, characterized in that it comprises a first power supply terminal (22) which is intended to be connected to an external power supply (5) and which is connected to said capacitive storage element (12) so as to allow charging thereof from said first power supply terminal (22) and discharging them to said first power supply terminal (22) and a second power supply terminal (22); 23) which is intended to be connected to said external power supply (5) and which is connected to said controller (10) so as to supply electrical power to said controller (10).
[0008]
8. power supply microswitch compensation module according to claim 7, characterized in that it has no decoupling capacitance which is connected to said first power supply terminal (22) and whose value exceeds 500 nanofarads.
[0009]
9. module for compensation of power supply shortcuts according to any one of the preceding claims, characterized in that it comprises a first power supply terminal (22) which is intended to be connected to an external power supply (5), a DC voltage direct voltage main converter (16) which is located between said capacitive storage element (12) and said first power supply terminal (22) and which includes an integrated current limiter which is activated upon insertion said module during operation of said server.
[0010]
10. power supply of the microcoupling compensation module according to any one of the preceding claims, characterized in that it comprises a second power supply terminal (23) which is intended to be connected to an external power supply (5), a DC voltage direct voltage secondary converter (20) and a current limiter (19) which are located between said controller (10) and said second power supply terminal (23).
[0011]
11. Power supply microswitch compensation module according to any one of the preceding claims, characterized in that said controller (10) comprises a function of detecting a sudden extraction of said module which function is connected to a pin which is shorter than the other pins so as to indicate the pulling operation before it is completely completed.
[0012]
12. The power supply microswitch compensation module according to any one of the preceding claims, characterized in that said controller (10) comprises a function of detecting said brownouts which function sends one or more requests for power consumption reduction to a power supply. or more servers as soon as a brownout is detected.
[0013]
13. Power supply microswitch compensation module according to any one of the preceding claims, characterized in that it is insertable and / or extractable even during the operation of said one or more servers.
[0014]
14. Power supply micro-compensation module according to any one of the preceding claims, characterized in that said or at least some of said servers each comprise one or more microprocessors and / or one or more memories.
[0015]
15. Computer comprising: - one or more microprocessors, - two dual memories (31) each comprising a random access memory (32), a non-volatile memory (33), and a controller (34) adapted to save the contents of the random access memory (32) in the non-volatile memory (33) and for reconfiguring the random access memory (32) with the contents of the non-volatile memory (33), - a main power supply rail (9) of said microprocessors and said dual memories ( 31) during operation of said computer without a power supply cutoff, for connection to an external power supply (5), - a secondary power supply rail (6, 8) of said dual memories (31) during operation of said computer to least when exceeding a predetermined power supply cut-off time, said secondary supply rail (6, 8) not supplying the microprocessors, - a compensation module (1) for power supply microcuts. An electric cord as claimed in any of claims 1-14, wherein the capacitive storage element (12) for electrical energy is adapted to supply electrical energy to said main supply rail (9). during microswitching power supply, but only during said predetermined power supply cut-off period, and is also adapted to supply electrical power to said secondary supply rail (6, 8) during power supply micro-cuts, after exceeding said predetermined power cutoff time.
[0016]
16. Computer according to claim 15, characterized in that said random access memory (32) is a DRAM memory and in that said non-volatile memory (33) is a FLASH memory.
[0017]
17. Computer according to any one of claims 15 to 16, characterized in that said computer is a supercomputer comprising several microprocessors.

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同族专利:

公开号 | 公开日

BR102015015660A2|2016-03-15|

JP2016012353A|2016-01-21|

FR3023019B1|2016-10-21|

US20150380985A1|2015-12-31|

JP6560546B2|2019-08-14|

US9787134B2|2017-10-10|

EP2961029A1|2015-12-30|

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优先权:

申请号 | 申请日 | 专利标题

FR1456044A|FR3023019B1|2014-06-27|2014-06-27|MODULE FOR COMPENSATION OF MICROCOUPONS OF POWER SUPPLY OF A SERVER|FR1456044A| FR3023019B1|2014-06-27|2014-06-27|MODULE FOR COMPENSATION OF MICROCOUPONS OF POWER SUPPLY OF A SERVER|

EP15173434.0A| EP2961029A1|2014-06-27|2015-06-23|Compensation module for power line disturbance of a server|

US14/750,226| US9787134B2|2014-06-27|2015-06-25|Micro power outage compensating module for a server|

JP2015128352A| JP6560546B2|2014-06-27|2015-06-26|Micro power failure compensation module for servers|

BR102015015660A| BR102015015660A2|2014-06-27|2015-06-26|micro power drop compensator module for a server|

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