JP2009053871A - Computer system and battery module for use therein - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To cause a host computer to reset a terminal computer via a battery module and put it into a normally operable state when the terminal computer becomes inoperable. <P>SOLUTION: A computer system includes a host computer 1, a terminal computer 2 connected to the host computer 1, and backup battery modules 3, 30 for supplying power to the terminal computer 2. The battery modules 3, 30 connected to the terminal computer 2 include a communication circuit 8 for receiving a reset signal output from the host computer 1, and a reset circuit 9 for resetting the terminal computer 2 in response to the reset signal that the communication circuit 8 receives. In the computer system, the communication circuit 8 receives the reset signal of the host computer 1 and outputs it to the reset circuit 9, and the reset circuit 9 resets the terminal computer in response to the reset signal input. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a computer system in which a terminal computer is connected to a host computer and a battery module that supplies power to the terminal computer of the computer system.

  A computer system in which a plurality of terminal computers are connected to a host computer via a communication line can connect a battery module to the terminal computer and back up the terminal computer during a power failure. The battery module incorporates a battery that is charged to a commercial power source, and supplies power from the battery to the terminal computer when the commercial power source of the terminal computer fails. When the commercial power supply fails, power is supplied from the battery module to the terminal computer to bring it into operation, and the terminal computer stores the data and file being processed in the storage means and then shuts down.

If an uninterruptible power supply with a built-in battery that can be charged is connected to a computer and the power supply status monitoring operation of the uninterruptible power supply is abnormal, the uninterruptible power supply is reset. A computer system for shutting down a terminal computer by storing processing data of the terminal computer in a storage means has been developed. (See Patent Document 1)
JP 2006-109203 A

  This computer system can prevent the terminal device of the terminal computer from being damaged due to a power trouble. However, this computer system cannot monitor the uninterruptible power supply if the terminal computer hangs up and does not operate normally. Further, if the terminal computer does not operate normally, communication with the host computer cannot be performed, and the host computer cannot reset the terminal computer to normal operation.

  The present invention has been developed for the purpose of solving this drawback. An important object of the present invention is that when a terminal computer becomes inoperable, the host computer resets the terminal computer via the battery module so that the terminal computer can operate normally, and the battery module used in the computer system Is to provide.

  The computer system according to claim 1 of the present invention includes a host computer 1, a terminal computer 2 connected to the host computer 1, and backup battery modules 3 and 30 for supplying power to the terminal computer 2. The battery modules 3 and 30 connected to the terminal computer 2 include a communication circuit 8 that receives a reset signal output from the host computer 1 and a reset circuit 9 that resets the terminal computer 2 using the reset signal received by the communication circuit 8. And. In the computer system, the communication circuit 8 receives the reset signal of the host computer 1 and outputs it to the reset circuit 9, and the reset circuit 9 resets the terminal computer 2 with the input reset signal.

  In the computer system according to the second aspect of the present invention, the communication circuit 8 of the battery modules 3 and 30 is a wireless communication circuit or a wired communication circuit. Further, in the computer system according to the third aspect of the present invention, the battery modules 3 and 30 include the charging circuits 7 and 37 for the battery 6.

  The battery module according to claim 4 of the present invention incorporates a battery 6 for supplying power to the terminal computer 2 connected to the host computer 1. The battery module includes a communication circuit 8 that receives a reset signal output from the host computer 1 and a reset circuit 9 that resets the terminal computer 2 using the reset signal received by the communication circuit 8. In the battery module, the communication circuit 8 receives the reset signal of the host computer 1 and outputs it to the reset circuit 9, and the reset circuit 9 resets the terminal computer 2 with the input reset signal.

  In the battery module according to claim 5 of the present invention, the communication circuit 8 is a wireless communication circuit or a wired communication circuit. Furthermore, the battery module according to claim 6 of the present invention incorporates charging circuits 7 and 37 for the battery 6.

  According to the present invention, the battery module can reset the terminal computer in an inoperable state by receiving a reset signal from the host computer and return to the operating state. Therefore, even if the terminal computer hangs up and does not operate, the host computer can reset the terminal computer. Since the host computer is communicating with the terminal computer, it is possible to detect a hang-up of the terminal computer. However, since the terminal computer that has hung up cannot communicate with the host computer, the terminal computer cannot be reset directly from the host computer. In the present invention, the battery module includes a communication circuit for receiving a signal for resetting the terminal computer by the host computer, and a reset circuit for resetting the terminal computer by a reset signal received by the communication circuit. Therefore, according to the present invention, when the host computer detects that the terminal computer hangs up and stops operating, the host computer resets the terminal computer via the battery module. Therefore, the hang-up of the terminal computer can be reliably reset with the battery module and returned to the operating state. In particular, according to the present invention, since the battery module is provided with a communication circuit and a reset circuit, and the battery module resets the terminal computer, the terminal computer is surely reset and returned to the operating state even in the power failure state of the commercial power supply. it can. Moreover, since the communication circuit and the reset circuit are provided in the battery module connected to the terminal computer, there is no need to connect a dedicated device for resetting the terminal computer, and the battery module connected to the terminal computer is used. Therefore, the circuit configuration for resetting the terminal computer can be simplified.

  Embodiments of the present invention will be described below with reference to the drawings. However, the embodiment shown below exemplifies a computer system for embodying the technical idea of the present invention and a battery module used in the computer system, and the present invention describes the computer system and the battery module as follows. Not specific to anything.

  Further, in this specification, for easy understanding of the scope of claims, numbers corresponding to the members shown in the embodiments are indicated in the “claims” and “means for solving problems” sections. It is added to the members. However, the members shown in the claims are not limited to the members in the embodiments.

  The computer shown in FIG. 1 includes a host computer 1, a terminal computer 2 connected to the host computer 1, and a backup battery module 3 that supplies power to the terminal computer 2.

  The host computer 1 and the terminal computer 2 are connected via a wired or wireless communication line 4. In the illustrated computer system, a plurality of terminal computers 2 are connected to a host computer 1, and a backup battery module 3 is connected to each terminal computer 2.

  As shown in FIG. 2, the battery module 3 is connected to the terminal computer 2 and supplies operating power to the terminal computer 2 in a state in which the commercial power supply 5 fails. The terminal computer 2 includes a power supply circuit 21 that operates with the commercial power supply 5. The power supply circuit 21 converts the input commercial power supply 5 into a direct current of the power supply voltage and outputs it to the power line 22 of the terminal computer 2. The power supply circuit 21 outputs DC power for operating the terminal computer 2 to the power line 22 in a state where the commercial power supply 5 is input. However, if the commercial power supply 5 is not input due to a power failure, DC power cannot be output to the power line 22 of the terminal computer 2. The battery module 3 supplies operating power to the power line 22 of the terminal computer 2 in place of the power supply circuit 21 of the terminal computer 2 in a state where the commercial power supply 5 fails.

  Therefore, the battery module 3 includes a battery 6 that outputs DC power to the power line 22 of the terminal computer 2 in a power failure state. The battery 6 is a rechargeable battery such as a lithium ion secondary battery, a nickel metal hydride battery, a nickel cadmium battery, or a lead battery. The battery 6 is charged by the commercial power source 5 and is always kept in a state where operating power can be supplied to the power line 22 of the terminal computer 2. The battery module 3 includes a charging circuit 7 that charges the battery 6. The charging circuit 7 converts the commercial power source 5 into a charging voltage for the battery 6 and charges the battery 6 without a power failure. When the battery 6 is fully charged, the charging circuit 7 stops charging, and when the battery 6 is self-discharged and the remaining capacity is reduced to a predetermined capacity, the charging circuit 7 is charged again so that the battery 6 is always charged. Hold.

  The battery module 3 supplies DC operating power to the power line 22 of the terminal computer 2 during a power failure. The battery module 3 that outputs DC operating power to the power line 22 of the terminal computer 2 is connected to the power line 22 of the terminal computer 2 via a diode 23 as shown in FIG. However, as shown in FIG. 3, the battery module 30 can also output alternating current and input it to the power supply circuit 21 of the terminal computer 2. The battery module 30 is connected to the commercial power input side of the power supply circuit 21 of the terminal computer 2. The battery module 30 that outputs AC operating power inputs AC of the same voltage as that of the commercial power source to the power supply circuit 21 of the terminal computer 2 instead of the commercial power source that has been interrupted. The battery module 30 that outputs alternating current includes an inverter 31 that converts direct current output from the battery 6 into alternating current. This inverter 31 converts the output voltage of the battery 6 into an alternating current of the voltage of the commercial power supply and outputs it.

  In the battery module 3 of FIG. 2, the power line 10 that stabilizes the output voltage of the battery 6 is connected to the power line 22 of the terminal computer 2 via the power line 11 and the diode 23. In the terminal computer 2, the output of the power supply circuit 21 that converts the commercial power supply 5 into direct current is connected to the power line 22 via a diode 24. The terminal computer 2 is supplied with operating power from both the built-in power supply circuit 21 and the power line 10 of the battery module 3 via the diodes 24 and 23. The output voltage of the battery module 3 is slightly lower than the output voltage of the power supply circuit 21. In other words, the output voltage of the power supply circuit 21 is slightly higher than the output voltage of the battery module 3, and the commercial power supply 5 does not fail. Then, operating power is supplied to the power line 22 only from the power supply circuit 21 of the terminal computer 2. When the commercial power supply 5 fails, operating power is not supplied from the power supply circuit 21. In this state, operating power is supplied from the battery module 3 to the power line 22 of the terminal computer 2 via the power supply line 11 and the diode 23.

  2 supplies operating power from the power supply circuit 21 and the battery module 3 of the terminal computer 2 through the diodes 24 and 23, but operates from the battery module to the power line of the terminal computer through the changeover switch. Electric power can also be supplied. This computer system detects a power failure of the commercial power supply and outputs the operating power of the terminal computer from the battery module at the time of the power failure. The battery module includes a detection circuit that detects a power failure of the commercial power supply, and a changeover switch that is turned on when the power failure is detected by the detection circuit and outputs operating power to the power line of the terminal computer. ing. In a state where there is no power failure, the changeover switch is in an off state, and the operating power is switched from the commercial power supply to the power supply circuit. When the commercial power supply fails, the changeover switch is turned on, and operating power is supplied from the battery module to the terminal computer.

  Furthermore, as shown in FIG. 3, the battery module 30 can also supply operating power to the terminal computer 2 while floating charging the battery 6 with the charging circuit 37 without providing a changeover switch. The battery module 30 converts the commercial power source 5 into a direct current, converts the commercial power source 5 into a direct current for charging the battery 6 with the DC / DC converter 32, and the DC power for charging the battery 6 is the same as the commercial power source 5 with the DC / AC converter 33. The AC voltage is converted and input to the power supply circuit 21 of the terminal computer 2. The battery module 30 is connected to the terminal computer 2 by the DC / AC converter 33 while maintaining the commercial power source 5 in a state where the battery 6 is charged by the DC / DC converter 32 of the charging circuit 37 in a state where no power failure occurs. Supply the same AC voltage as The battery 6 is always in a state where power can be supplied to the terminal computer 2 and is kept in a charged state. When the commercial power supply 5 fails, the battery 6 is not charged, but the battery 6 supplies operating power to the power supply circuit 21 of the terminal computer 2 via the DC / AC converter 33. The battery module 30 in FIG. 3 inputs the commercial power supply 5 to the power supply circuit 21 of the terminal computer 2 via the battery module 30. The battery module 30 can continuously output the same AC operating power as that of the commercial power source 5 to the terminal computer 2 even if the commercial power source 5 fails. This is because the output side of the battery 6 is always connected to the power supply circuit 21 of the terminal computer 2 via the DC / AC converter 33.

  The battery modules 3 and 30 include a detection circuit 13 that detects a power failure of the commercial power supply 5. When the detection circuit 13 detects a power failure of the commercial power supply 5, a power failure signal is output to the terminal computer 2. When the terminal computer 2 detects this power failure signal, the terminal computer 2 stores the data and file being processed in the storage means within a time period during which operating power can be supplied from the battery module 3, and then shuts down.

  Further, the battery modules 3 and 30 include a communication circuit 8 that receives a reset signal output from the host computer 1 and a reset circuit 9 that resets the terminal computer 2 using the reset signal received by the communication circuit 8. Yes. The battery module 3 is connected to the terminal computer 2 via a power line 11 for supplying operating power to the power line 22 of the terminal computer 2 and a signal line 12 for outputting a reset signal.

  The communication circuit 8 is a wireless communication circuit or a wired communication circuit. The wireless communication circuit receives a radio wave transmitted from the host computer 1 and detects a reset signal. When the host computer 1 that transmits a reset signal to the battery modules 3 and 30 detects that the terminal computer 2 is hung up and cannot operate, it modulates and transmits the carrier wave with the reset signal. The wireless communication circuit receives this radio wave and demodulates it to detect a reset signal. The wired communication circuit directly detects a reset signal of an analog signal or a digital signal input from the host computer, or receives a carrier wave modulated by the reset signal and detects the reset signal.

  The reset circuit 9 resets the terminal computer 2 with a reset signal input from the communication circuit 8. Therefore, the reset circuit 9 is connected to the reset line 25 of the terminal computer 2 via the signal line 12.

  The host computer 1 is connected to the terminal computer 2 via the communication line 4 to transmit / receive data to / from each other. When the host computer 1 detects that the terminal computer 2 hangs up and cannot operate, it outputs a reset signal. The reset signal output from the host computer 1 is received by the communication circuit 8 of the battery modules 3 and 30. The reset signal received by the communication circuit 8 is input from the reset circuit 9 to the terminal computer 2 to reset the terminal computer 2 in the hang-up state.

  Furthermore, the battery modules 3 and 30 shown in FIG. 2 and FIG. 3 have a structure in which the terminal computer 2 can be forcibly restarted when the terminal computer 2 falls into a hang-up state due to some trouble. The battery modules 3 and 30 shown in these drawings include a communication control circuit 14 that communicates with the terminal computer 2, and periodically communicates with the terminal computer 2 via the communication line 15. The communication control circuit 14 can detect the hang-up of the terminal computer 2 by observing the communication state with the terminal computer 2. This is because communication with the battery modules 3 and 30 is interrupted when the terminal computer 2 hangs up and does not operate. In the terminal computer 2, communication with the battery modules 3 and 30 is interrupted even when the shutdown process is performed. In this case, the terminal computer 2 connects to the communication control circuit 14 via the communication line 15. It can be detected that the normal shutdown processing has been performed by the input shutdown signal.

  The communication control circuit 14 observes the communication with the terminal computer 2 for a specified time, determines that the terminal computer 2 has hung up if the communication is not resumed, and outputs a power-off signal to the terminal computer 2. The terminal computer 2 forcibly terminates the system in response to the power-off signal input from the communication control circuit 14. However, as shown in FIG. 3, in the terminal computer 2 that is supplied with power only from the battery module 30, the power switch 16 provided on the output side of the battery module 30 is turned off to stop supplying power to the terminal computer 2. By doing so, the terminal computer 2 can be forcibly terminated. The power switch 16 is normally controlled to be on and is kept in a power supply state.

  When a predetermined time elapses after the terminal computer 2 is forcibly terminated, the battery modules 3 and 30 output a power-on signal to the terminal computer 2. The terminal computer 2 restarts the system by a power-on signal input from the battery modules 3 and 30. In the battery module 30 that stops power supply and forcibly terminates the terminal computer 2, the power switch 16 is turned on to resume power supply to the terminal computer 2, and then a power-on signal is output to the terminal computer 2. . Here, if the terminal computer is configured to be activated by restarting power supply, the terminal computer can be restarted without outputting a power-on signal. The battery modules 3 and 30 described above can easily and reliably recover the hung-up terminal computer by forcibly restarting using the communication means with the terminal computer 2.

  As described above, the battery modules 3 and 30 have a structure and a function capable of forcibly restarting the terminal computer 2 when the terminal computer 2 falls into a hang-up state due to some trouble. The function can be given to the power supply circuit 21.

It is the schematic of the computer system concerning one Example of this invention. It is a block diagram of the terminal computer and battery module of the computer system shown in FIG. It is a block diagram which shows another example of a battery module.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Host computer 2 ... Terminal computer 3 ... Battery module 4 ... Communication line 5 ... Commercial power supply 6 ... Battery 7 ... Charging circuit 8 ... Communication line 9 ... Reset circuit 10 ... Power line 11 ... Power supply line 12 ... Signal line 13 ... Detection Circuit 14 ... Communication control circuit 15 ... Communication line 16 ... Power switch 21 ... Power supply circuit 22 ... Power line 23 ... Diode 24 ... Diode 25 ... Reset line 30 ... Battery module 31 ... Inverter 32 ... DC / DC converter 33 ... DC / AC Converter 37 ... Charging circuit

Claims (6)

A host computer (1), a terminal computer (2) connected to the host computer (1), and backup battery modules (3) and (30) for supplying power to the terminal computer (2) A computer system,
The battery module (3), (30) connected to the terminal computer (2) receives the reset signal output from the host computer (1), and the communication circuit (8) receives the communication circuit (8). A reset circuit (9) for resetting the terminal computer (2) with a reset signal,
The communication circuit (8) receives the reset signal of the host computer (1) and outputs it to the reset circuit (9), and the reset circuit (9) resets the terminal computer (2) with the input reset signal. A computer system that makes it happen.   The computer system according to claim 1, wherein the communication circuit (8) of the battery modules (3), (30) is a wireless communication circuit or a wired communication circuit.   The computer system according to claim 1, wherein the battery modules (3) and (30) incorporate a charging circuit (7) and (37) for the battery (6). A battery module containing a battery (6) for supplying power to a terminal computer (2) connected to a host computer (1),
A communication circuit (8) for receiving a reset signal output from the host computer (1), and a reset circuit (9) for resetting the terminal computer (2) by the reset signal received by the communication circuit (8). And
The communication circuit (8) receives the reset signal of the host computer (1) and outputs it to the reset circuit (9), and the reset circuit (9) resets the terminal computer (2) with the input reset signal. A battery module made in this way.   The battery module according to claim 4, wherein the communication circuit (8) of the battery module is a wireless communication circuit or a wired communication circuit.   The battery module according to claim 4, wherein the battery module incorporates a charging circuit (7), (37) for the battery (6).

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