DE102009031988A1 - Method for powering a computer, computer and separate component for connection to a computer - Google Patents

Abstract

The invention relates to a method for supplying energy to a computer, wherein the computer can be outputted to a network, a first voltage level being assigned to a supply voltage in standby mode and at least one further voltage level being assigned to an operating voltage of the computer during operation of the computer Power supply of the computer output voltage values are evaluated and that the power supply of the power supply is interrupted when eb associated voltage level is output and that, on the other hand, at the same time the at least one further voltage level of the operating voltage associated with the ongoing operation of the computer is not output, whereby an interruption of the energy supply of the Power supply is prevented when the computer is booted into the operating state for running operation.

Description

The invention relates to a method for powering a computer according to the preamble of patent claim 1, a computer according to claim 9 and a separate component according to claim 10.

The applicant is aware that the current PC is designed according to the current ATX standard or its extensions from the ground up a permanent standby mode with corresponding continuous power consumption. This standby mode is when the computer is shut down. In standby mode, the power consumption is typically 5-20 watts, depending on the equipment and connected accessories. A primary-side shutdown of the PC, by disconnecting the power supply, is structurally not provided with the previously known ATX technology. The main switch of a PC housing is also difficult to access attached on the back of the ATX power supply for constructive reasons or he is not even exist because he there the requirement for a convenient, convenient operation anyway does not meet.

Furthermore, solutions with additional components are known, such as disconnectable power strips. These require constant personal activity and constant engagement of the user. So-called "master-slave circuits" or power strips have not enforced appreciably. They are too complicated for the average user as they must be preset to a consumption threshold that is different for each PC system.

The object of the present invention is to improve the energy management of a computer.

This object is achieved according to claim 1, characterized in that in a method for powering a computer, the computer has a power supply via which different voltage levels can be output. A first voltage level is assigned to a supply voltage in standby mode. At least one other voltage level is associated with an operating voltage of the computer during operation of the computer. According to the present invention, the voltage values output by the computer's power supply are evaluated and the power supply of the power supply is interrupted when it is detected that the voltage level associated with the standby mode is output and at least one more associated with the current operation of the computer Voltage level of the operating voltage is not output. An interruption in the power supply of the power supply is prevented when the computer is booted to the operating state for ongoing operation.

Advantageously, the energy consumption in standby mode is avoided. Furthermore, the reliability is still advantageously improved because the risk of fire is minimized by a device error when energy consumption of the device is avoided in the unattended state.

The need to operate a PC in the long-term standby is given only in a few cases. This would be the case, for example, if the PC as a server or for data and fax reception or, for example, even when used as a DVD recorder for recording programs of a television program or otherwise must be permanently ready to receive.

An embodiment of an electronic circuit is explained below. Such a circuit consists of an electronic control system. This can either be installed in the PC or in its power supply or else be configured as a separate component independently of the PC. Advantageously, such a circuit can also be used in a simple manner for existing PCs. In a configuration of the electronic circuit as a separate component this can be combined, for example, with a power strip.

The present method ensures that the PC is automatically disconnected from the mains voltage after shutdown on the primary side. This reduces the energy consumption "at standstill" to zero.

The conventional PC, or its ATX power supply, has in addition to the de-energized, disconnected from the mains state, the "Standby" and the "operating state".

In standby, the ATX power supply only supplies +5 volts standby voltage to ground. In the operating state, it also supplies all other operating voltages on separate outputs. Among other more +5 volts to ground. These two voltages are used to control and switch relays, plus +12 V to switch another load relay. All other operating voltages are for the function described below also usable, but since they - together with the exception of the standby voltage - occur together, they can be seen summarized in the context of the present invention, under the term "operating voltages".

The invention makes use of the circumstance that the two switching states "standby" and "operating state" with respect to the given or not given voltages correspond to two different logical states, which altogether occur in three different combinations, each of which has an unambiguous assignment and effect allow various functions of the control electronics.

In the following consideration, the state "voltage present" is equated with logic "H" (high) and the state "voltage not available" with logical "L" (low). This results in the following logical truth table: standby operating voltages Off (primary power supply interrupted): L L Standby (Primary power supply established: H L Booted and raised (PC in operation): H H not possible condition: L H

Advantageously, these operating states of the power supply are evaluated in the present method. At the same time it is avoided that the power supply is switched off immediately when booting up the computer. This would happen without separate measures when the computer goes through the standby state in the initial phase of the startup and the control electronics would derive from the then existing voltage levels that the power supply is to be separated on the primary side.

This suppression of the shutdown at the startup of the computer can be realized, for example, by setting a flag at the startup of the computer, by the evaluation of which the shutdown is suppressed, this flag is cleared again when the computer has reached the operating state of the current operation ,

Alternatively, according to the embodiment according to claim 2, the interruption of the power supply of the power supply when starting the computer in the operating state to the current operation by a timer made by the interruption of the power supply of the power supply is then disabled when the operating state of the power supply with the output of the voltage level corresponding to the standby mode, wherein at the same time the at least one voltage level of the operating voltage associated with the current operation of the computer has not been output, has not existed for a continuous minimum period of time.

In the embodiment according to claim, it is advantageous to a measure that is easy to implement circuitry. The time constant of the timer is chosen so that the computer has passed through the standby state during startup in a time corresponding to this time constant and has reached the operating state of the current operation.

In the embodiment according to claim 3, a button is provided, upon actuation of the computer is started from the state with interrupted power supply of the power supply either in the standby mode or in the operating mode corresponding operating state, wherein the computer upon actuation of the button is started in the operating state corresponding to the operating state when the computer is in standby mode.

This is an embodiment in which the control electronics are integrated into the computer.

The button is advantageous the button, which is already provided to the computer and the computer is raised from the standby mode in the operating state of the current operation in its operation. The situation described when booting the computer advantageously allows easy operation of the computer by the user.

In the embodiment according to claim 4, a capacitive charge storage for storing the starting energy is present, which is charged in the standby mode of the computer and / or in the current operating mode corresponding operating state of the computer.

At least not too long downtime of the computer has been shown that, for example by means of an electrolytic capacitor, the necessary starting energy can be stored.

In the embodiment according to claim 5, a primary and / or secondary battery for storing the starting energy is present.

For example, a secondary battery may be charged in the standby state as well as in the operating state of the computer during operation. Alternatively or additionally, a primary battery may be present. In an additional arrangement of a primary battery, this serves the redundancy of both the secondary battery and the capacitive charge storage device according to claim 4, which may also be present in addition to a primary and / or to a secondary battery.

Advantageously, the voltage levels of the capacitive charge accumulator and the secondary battery are greater than the voltage level of the primary battery. This is advantageously achieved that the starting energy is taken primarily from the rechargeable energy storage.

In the embodiment according to claim 6, an optocoupler is driven with the starting energy of the capacitive charge storage or the primary or secondary battery.

This advantageously ensures that the mentioned starting energy must be low.

In the embodiment according to claim 7, an output socket of the computer for auxiliary devices is only supplied with voltage when the power supply of the current operation of the computer associated with at least one voltage level of the operating voltage is output.

Advantageously, energy consumption of such auxiliary devices then takes place only when the computer is in an operating state in which it can control the additional devices.

In the embodiment according to claim 8, the user is signaled which voltage levels are output by the power supply.

Advantageously, it will be apparent to the user whether the computer is in the running or shutdown state, or whether the computer is being shut down and is in an idle state as an intermediate state during shutdown.

Claim 9 relates to a computer with an electronic circuit which is part of the computer.

Claim 10 relates to a separate component for connection to a computer for carrying out one of the aforementioned methods.

An embodiment of the invention is shown in the drawing. The overall circuit is divided into 4 modules, which in the 1 to 4 are shown as follows:

1 : Load switching section

2 : Starter

3 : LED Flasher u. Standby delay

4 : Restarter

The connection points of the modules are with ( 1 ) to ( 6 ) and ( 1a ) to ( 14a ) designated.

It is the function of each module based on the 1 to 4 described. Afterwards the overall function of the interaction of the "logical states" of operating voltages and standby voltage will be described.

1 shows a load switching part as part of the control electronics. Essential components are the resistors R1 and R2, the triac optocoupler OK1, the relays Rel.1 and Rel.2 as well as an emergency start button.

The capacitors C1, C1a and the resistor R3 belong to the standard external wiring of the triac optocoupler. D1 is freewheeling diode for Relay Rel.2.

The 230 V mains voltage is fed via a conventional line filter circuit (CX, L, L, CY, CY) to the connection points (a1) u. (a2) and from there to the contacts of Rel.1 u. Rel.2.

Rel.1 is the primary main switch for the 230 V mains voltage of the ATX power supply. It is switched by the triac optocoupler OK1. This is via the connection point ( 4 ) and R1 are controlled by a subsequent module "starter". To do this, the user only has to press the usual PC start button (PC-PWR Switch) of the PC housing.

Rel.2 is the primary power switch for the output socket and thus for all additional devices connected there, eg. B. monitor and printer or other. This relay is controlled by one of the operating voltages of the ATX power supply (here 12 V), but not by the standby voltage. Thus, all devices connected to the output socket are only switched to 230 V mains voltage in the PC operating state ON. In standby or OFF, however, they are primarily 2-pole switched off.

The control of the Rel.1 takes place with a short start impulse, through which in 2 described "starter". Once the start pulse has been given and Rel.1 has switched the 230 V mains voltage to the ATX power supply, OK1 will continue to be controlled (also after the start button has been pressed) by the immediately given 5 V standby voltage of the ATX power supply unit so that Rel.1 is energized and the ATX power supply remains in standby.

The standby state of the ATX power supplies is different types and manufacturer due to the beginning of the start phase different susceptible to too short actuations of the start button, as well as against interference from the high internal inrush currents. So it can come to a very short "flutter", which does not become noticeable in the normal operation during the start, but which can lead to malfunction in connection with the control circuit described here. Therefore, it is advantageous to keep the standby right after the start for a safe time. The user should also have the opportunity to initiate the booting of the PC by a second operation of the PC start button.

To ensure a safe time span (about 5 seconds), an in 3 described "standby retarder" provided.

The 5 V standby voltage is therefore for the time being (ie between the first actuation of the start button and before the second operation) during booting of the PC the "holding voltage" for OK1 and thus for holding the ATX power supply to standby. This "standby holding voltage" is switched by the "standby delay" and disappears after the delay time has elapsed. After starting the boot process (by pressing the PC start button a second time), the ATX power supply unit will supply the 5 V operating voltage and will take on the additional function of a holding voltage. The "temporary holding voltage" is therefore always the standby voltage and the "regular holding voltage" is the 5 V operating voltage.

Another possibility of starting can be realized by an "emergency start button", which leads the mains voltage via R2 directly to the coil of Rel.1. In addition, the start can be done alternatively by a "Restarter", which in 4 is described. The "Restarter" leads to a short trial start after each switching on or restarting (also after power failure) in the standby of the ATX power supply, so that the PC can be booted by pressing the start button. The "emergency start button" can be omitted when using the "Restarters".

The following is the "starter" according to 2 to be discribed. The components there are the battery, the capacitors C2-C4, the diodes D2-D10, the Widesrtand R4 and the relay Rel.3

C4 is preferably a "low leakage elk". It is located at connection point ( 1 / 1 ) "Starting voltage" and serves as a charge storage for the start pulse. It is powered by the 5V standby voltage connection point ( 1 ) charges via D7 during PC operation and retains this charge for the next launch for weeks to several months without recharging.

Initially, the starter has the task, upon actuation of the conventional PC start button, even in the logic state LL (off) to deliver a short start pulse to the triac optocoupler OK1 in the load switching part, which causes the logical state HL. For this purpose, the "PC-PWR-Switch" to the connection points ( 5a u. ( 6a ) of the starter.

In the following, the second operation within the mentioned "standby delay" to start the PC motherboard, so that the PC boots and the logical state HH is given. For this, the corresponding slot of the PC main board (PWR-ON) with the connection points ( 3a u. ( 4a ) of the starter.

In order to be able to start the ATX power supply unit with the first actuation of the PC start button in the de-energized state without concern of the standby voltage, it conducts the charge of the Elkos C4 or a lithium button cell (C4 via D8, or battery via D10) from connection point ( 1 / 1 ) via normally closed contacts 9 / 8th . 3 / 2 Rel.3 and resistor R4 to the connection point ( 4 ) and thus starts over R1 the control input of the triac optocoupler OK1. Rel.1 picks up and starts the ATX power supply into standby. The logical state is HL.

Rel.3 will pick up due to the instantaneous 5V standby voltage and the next second press on the PC start button will now be via the contacts 3 / 4 u. 8th / 7 to the connection points ( 4a u. ( 3a ) and from there to the "PWR-ON" port of the PC motherboard. This second actuation of the PC start button causes the PC to boot. The logical state is HH.

Furthermore, a two-pole, externally attached to the PC housing "mode switch" is connected to the starter. Connection points ( 1a ) 9a ) 10a ) 12a ) 13a ). The mode switch has OFF and standby positions.

The control input of the triac optocoupler OK1 is generally connected via connection point ( 2 ), D2, connection point ( 2a ), D5 u. R4 is kept ON from the 5V operating voltage which, as already mentioned, is "regular holding voltage". However, if the mode switch is set to "Standby" (logic state HL), the switch contacts 1a / 10a the 5V standby voltage of ( 1a ) via D4, R4 to the connection point 4 and thus directed to the control input of the OK1. The 5 V standby voltage is in this switch position thus the "additional, second. Holding voltage ". Since the 5 V standby voltage continues to exist after the PC shuts down, this switch position of the mode switch also keeps the entire PC in standby mode.

On the other hand, if the mode switch is OFF, only the 5 V operating voltage is the "holding voltage" and the PC will no longer hold the Rel.1 ON after shutdown and will switch off. It is thus separated from the mains voltage including primary and 2-pin. (logic state LL) Likewise, all connected auxiliary devices are disconnected from the mains voltage, since the 12 V operating voltage for switching Rel.2 after shutdown is likewise no longer present.

C2 as well as C4 serves as a charge storage for the start pulse, but only in connection with the "mode switch". It is connected via connection point ( 13a ) going to the OFF position of the mode switch via its contacts 13a / 9a and connection point ( 9a ) (together with C4) to + D7 charged by the 5V standby voltage. When the mode switch is switched to standby, the charge from C2 is applied through the contacts 13a / 12a and connection point ( 12a ) about D3 u. R4 on connection point ( 4 ) and thus to the control input of the OK1. Its charge thus makes it possible to start the PC from the OFF state at any time by switching the mode switch to standby, where it then keeps ON by means of the immediately given standby voltage.

C3 represents a buffer for the 5 V operating voltage.

D2, D3, D4, D5 are designed to discharge start control pulses to other connection points than ( 4 ). D6 is freewheeling diode for Rel.3. D7 should charge C4 to 5V standby voltage and avoid charge backflow. D9 should be 5 V standby voltage for the 2nd start pulse at connection point ( 1 / 1 ) and from there to Rel.3. D10 avoids charge backflow to the battery.

A need to change the battery (lithium button cell) is not expected due to the rare and low stress.

The following should be related to 3 the "LED Flasher" and the "Standby Delay" are explained. 3 The components contain capacitors C5-C9, diodes D11-D13, integrated circuit IC1, LED1, resistors R5-R13 and transistor T1.

This entire assembly is only used by connection point ( 1 ) 5 V standby voltage operated.

IC1 is a dual-timer module.

The left part of the circuit with C5, C7, D12, R6-R10 u. T1 represents a LED flasher of known type for the "PC case Power LED" and need not be explained. T1 as output transistor controls via R6 and connection point ( 7a ) the external power LED of the PC case. The LED "flashes" or "flashes" in standby mode. A special feature is the supply of 5 V operating voltage immediately after booting, from connection point ( 2a ) via R5 u. D11 to the LED connection point ( 7a ). This bypasses the flasher and the PC housing power LED lights up permanently in the logic state HH. This is for the user to distinguish between the standby and ON operating states.

The right part of the circuit with C6, C8, D13, R12, R13 represents a timer ("standby delay"), the duration of which starts immediately after the start with concern of the 5 V standby voltage and for about 5 seconds (depending of size C8, R12) via D13 u. R13) the 5 V standby voltage on connection point ( 10a ) and continue via D4, R4 to connection point ( 4 ) and thus leads to the control input of the OK1. Thus, a fail-safe, logical state HL is given for about 5 seconds. LED1 with resistor R11 indicates this on the board, but can be omitted. The capacitor C9 is a buffer capacitor for the supply voltage.

This "standby delay" maintains the standby after the first start pulse for a fixed time (about 5 seconds) regardless of the individual characteristics of different power supply makes. In this fixed time, the user can bring the PC by a second operation of the PC start button for booting and booting the operating system (logic state HH).

4 shows the restarter. The components are the capacitor C10, the diodes D14, D15, the resistors R14, R15, R16, R17, R18, R19, R20, the Relay Rel.4 and the transistors T2, T3.

The "Restarter" can optionally be switched on and replaces the "Emergency Start button". He still needs the battery 2 or starts the PC even with a discharged battery. It can also be integrated as an integral part of the circuit.

The circuit gets over D14, the positive half-wave of the mains voltage. When switching on or switching back on (even after a power failure), C10 recharges because it was previously discharged by R14 when the mains voltage was switched off. Due to the charging current of C10, the base of the NPN transistor T2 gets a short positive pulse and turns on. As a result, the voltage potential at node R16, R17, R18 is negative, the base of PNP transistor T3 receives a negative pulse and the transistor turns on briefly. Rel.4 picks up for about 1 second and drops again. The short closing of the relay contacts 3 / 4 has the same effect on P1 / P2 as pressing the emergency start button already described in wiring diagram sheet 1. The PC will go to the logic state HL (standby mode) each time the 230 V mains voltage is switched on or switched on again and held there for 5 seconds by the "standby delay". If the mode switch is in standby mode, the PC remains in standby mode. On the other hand, if the mode switch is set to OFF, Rel.1 (see page 1) will also drop again after 5 seconds of standby and switch off the entire PC system. (logic state LL) Thus, after a power failure, the PC goes into the "pre-set" mode "Standby" or "OFF" mode switch.

In the following, the effects of the logical states will be summarized in detail.

The logic state LL causes the contact closure of the PC start button to trigger a start from OFF to standby. This then gives the logical state HL.

In logic state HL, the contact closure of the PC start button causes the motherboard to start. The PC boots. This gives the logical state HH.

In the logic state HL, the PC power LED "flashes" (flashes).

In logical state HH, the PC power LED lights up permanently.

In logical state HH all connected auxiliary devices are switched on.

In logic state HL, all connected auxiliary devices are switched off.

In the logic state LL everything is switched off.

(Logical state LH not possible.) 1 +5 V standby 2 +5 V 3 Minus / Ground 4 II control sp to OK1 5 NC 6 +12 V 1a minus 2a 5V standby 3a 5 V 4a NC 5a 12V 6a connection point 7a connection point 8a connection point 9a connection point 10a connection point 11a connection point 12a connection point 13a connection point 14a connection point 21 CX = 100 nF / 360V 22 L 23 CY = 3.3 nF / 630V 24 R1 560 ohms 25 OK1 triac optocoupler 26 MOC 3023 27 C1 = 10nF / 400V 28 R3 82 ohms 29 C1a = 100 nF / 400V 30 Rel.1 31 R2 10k 32 D11 N4007 33 Rel.2 37 (1/1) 38 D8 1N4148 39 C4 1000 μF / 6.3 ("low leakage") 40 Jmp.2 battery 41 Battery (3.2V) CR1632 42 D10 BAT 46 (Schottky) 43 D9 1N4148 44 D4 1N4148 45 D5 1N4148 46 D6 1N4148 47 D7 1N4148 48 C2 1000 μF / 6.3 ("low leakage") 49 C3 1 μF / 35 V tantalum 50 D3 1N4148 51 R4 82 ohms 52 D2 1N4148 53 Mode Shift 54 OFF / Stdby 55 PC-PWR switch (external) 56 (external) 57 PC housing LED 58 LED 59 S1 2x Um (external) 60 Discharge 61 Threshold 62 Contr. Volt. 63 reset 64 output 65 trigger 66 GND 67 VCC 68 R7 4,7 k 69 D12 1N4148 70 R10 4,7 k 71 R8 4.7k 72 R9 4.7k 73 T1 PNP BC556 74 R5 270 ohms 75 D11 1N4148 76 R6 270 ohms 77 C5 100 μF / 35V 78 C7 100 nF 79 C8 100 nF 80 LED1 2 mA, 3 mm red 81 C6 100 μF / 35V 82 R11 2.2k 83 R13 82 ohms 84 IC1 NE556 (dual timer) 85 D13 1N4148 86 R12 39 k (5 sec.) 87 C9 100 μF / 35V 88 D14 1N4007 89 R17 10k 90 R19 2.2k 91 T3 (PNP) MPSA61 92 R18 100 k 93 R20 15k 94 Rel.4 DC 95 C10 47-100 nF / 400V 96 R14 4.7 M 97 R15 2.2k 98 R16 220 k 99 D15 1N4007 100 T2 (NPN) MPSA44 101 Rel.3 DC5V 102 Input ATX power supply 103 IEC chassis connector 104 IEC device socket (to the monitor) 105 IEC device socket (for ATX power supply) 106 Notstarttaster

Claims (10)

A method of powering a computer, the computer having a power supply through which different voltage levels can be output, wherein a first voltage level of a supply voltage is assigned in standby mode and wherein at least one further voltage level of an operating voltage of the computer is assigned during operation of the computer, characterized in that the output from the power supply of the computer voltage values are evaluated and that the power supply of the power supply is interrupted when it is detected that on the one hand the standby mode associated voltage level is output and that on the other hand simultaneously associated with the current operation of the computer at least one more voltage level of the operating voltage is not output, wherein an interruption of the power supply of the power supply is inhibited when the computer is booted to the operating state for ongoing operation. A method according to claim 1, characterized in that the interruption of the interruption of the power supply of the power supply when starting up the computer in the operating state to the current operation is performed by a timer, by which the interruption of the power supply of the power supply is then deactivated when the operating state of the power supply with the output of the voltage level corresponding to the standby mode, while the current operation of the computer associated with at least one voltage level of the operating voltage is not has not existed for a contiguous minimum period of time. A method according to claim 1 or 2, characterized in that a button is present, upon actuation of which the computer is started from the state with interrupted power supply of the power supply either in the standby mode or in the operating mode corresponding operating state, wherein the computer when the button is pressed into the operating mode corresponding to the current operation, when the computer is in standby mode. Method according to one of claims 1 to 3, characterized in that a capacitive charge storage for storing the starting energy is present, which is charged in the standby mode of the computer and / or in the current operating mode corresponding operating state of the computer. Method according to one of claims 1 to 4, characterized in that a primary or secondary battery for storing the starting energy is present. A method according to claim 4 or 5, characterized in that with the starting energy of the capacitive charge storage or the primary or secondary battery, an optocoupler is driven. Method according to one of claims 1 to 6, characterized in that an output socket of the computer for accessories is only supplied with voltage when the power supply of the current operation of the computer associated with at least one voltage level of the operating voltage is output. Method according to one of claims 1 to 7, characterized in that the user is signaled, which voltage levels are output from the power supply. Computer having an electronic circuit for carrying out one of the methods according to one of the preceding claims. Separate component for connection to a computer for carrying out one of the methods according to one of claims 1 to 8.

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