JP2556995B2 - Power supply - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Summary] The present invention relates to a maintenance replacement method for a backup device, which aims to smoothly replace the converter or the power supply when the converter or the power supply is abnormal. A power supply (1) that converts the AC input power via the input side into a direct current to supply system power, and a converter (2) that converts the voltage of the system power from the power supply unit and rectifies it to the load unit (3). A battery supply unit (4) having a voltage conversion unit for converting the voltage of an AC input power source via another input side to rectify it and a battery charged via a battery supply switch by a direct current from the voltage conversion unit. In a power supply device including: a battery supply switch (4) connected to a backup current supply path between a battery supply switch and an output side of the power supply unit (1). The power switch is started by the input of the backup switch (5) and the power signal (OWRON), at least the power supply switch and the backup switch (5) in the power supply unit (1) are closed, and the power supply device is controlled. A control unit (6) for receiving an abnormal signal (* CONVAL, * PDUAL) from the power supply unit (1) is provided, and the control unit (6) is a power supply device when the abnormal signal from the converter or the power supply unit is received. The function of is stopped and at least the power supply switch and the backup switch are opened.

[Industrial applications]

The present invention relates to a maintenance replacement method for a backup device.

[Conventional technology]

FIG. 5 is a circuit diagram of a conventional power supply device. 51 in the figure
Is a power supply unit, and a power supply switch (MS1-1) 51
a, a rectifier circuit 51b, a switch controller 51c, and a circuit breaker (CB1) 51d. Power supply switch (MS1-1) 5
1a supplies AC input power to the converter 52 as system power when the switch (MS1-1) is ON. Rectifier circuit 51
b is a switch controller 51c for exchanging alternating current with direct current.
Is the voltage conversion operation and the abnormal signal of the power supply unit 51 (* PDUA
L) is issued. 51d is a circuit breaker (CB1) that prevents the risk of circuit destruction due to an increase in current, and disconnects the power supply line when a specified amount of current or more flows.

Reference numeral 52 is a converter that converts the voltage and supplies power to the first load unit 53 and the second load unit 56, and includes an abnormality warning unit 52a. The abnormality warning unit 52a outputs an abnormality signal (* CONVAL) when the converter 52 has an abnormality. The first load unit 53 is an MSU
Is a storage unit (memory element). The second load part 56 is
It is the part that controls the pipeline that reads data from the memory element of the MUS or writes data to the memory element and the interface with the CPU or CHP (channel) that is a higher-level device. Here, it is simply called the control unit of the MSU.

A battery supply unit 54 is composed of a voltage conversion unit 54a, a circuit breaker 54b, a battery supply switch 54c, and a battery 54d. The voltage conversion unit 54a outputs a pulse signal at the switching unit Q1 to perform voltage conversion. The circuit breaker (CB2, CB3) 54d prevents the risk of circuit destruction due to an increase in current, and disconnects the power supply line when a current exceeding the specified amount flows. Battery supply switch (MS2-1) 54c is ON
Sometimes the battery is charged and the battery power is supplied during backup. The battery 54d supplies power to the load unit 53 when the AC input power to the load unit 53 is stopped.

Reference numeral 56 is a control circuit unit, which is a power signal (PWRON) input when the power supply is started and a converter abnormality signal (* CONVA
L) and the power supply unit abnormality signal (* PDUAL), and operates the switching unit Q1 of the voltage conversion unit 54a (* CHGO
N) and a signal (* PONCV) for controlling the converter 52 are output to turn ON / OFF the power supply switch (MS1-1) 51a and the battery supply switch (MS2-1) 54c.

FIG. 7 is a time chart diagram showing the operation of FIG. In FIG. 7, AC input 1 and AC input 2 indicate the presence or absence of the AC power input (AC1 and AC2 in FIG. 5), which are CB1 and CB2, respectively.
It is turned on and off. DC input 3 indicates the presence or absence of battery power input, which is turned on and off by CB3. PWRON is a power signal input at the time of starting the power supply device, and MS1-1 and MS2-1 are the ON and OFF states of the power supply unit switch (MS1-1) 51a and the battery supply switch (MS2-1) 54c, respectively. CONVIN
Indicates whether the power input to the converter 52 is AC power or battery power. * CHGON is a signal for operating the switching unit Q1, * PONCV is a signal for operating the converter 52, * CONVAL is an abnormal signal of the converter 52 and is output by the abnormal warning unit 52a, and CONV unit replacement is performed by the converter 52. It shows whether it can be replaced.
In Fig. 7, * CONVAL or * PDUAL, CONV unit replacement or power supply unit replacement.

FIG. 6 is an explanatory diagram of a detailed configuration of the control circuit 56. The control circuit 56 receives the power signal (PWRON), the converter abnormality signal (* CONVAL) and the power supply section abnormality signal (* PDUAL), and supplies the power supply switch (MS1-1) 51a and the battery supply switch (MS2-1). Controls 54c, * CHGON signal, and * PONCV signal. In the figure, the drivers 63 and 65 turn on the relays 67a and 67b when the input is 1, and the relay 67a operates the power supply switch (MS1-1) 51a and the relay 67b.
Operates the battery supply switch (MS2-1) 54c.
The latch 64 holds the ON state, and is composed of, for example, a flip-flop.

The operation of the control circuit 56 will be described below (see FIG. 6). When the power signal (PWRON) turns on (1), the power signal passes through the knot gate 61, so the * CHGON signal turns on.
(0) and the signal (PWRON) passes through the AND gate 62 and the driver 63, so the power supply switch (MS1-1) 51a is turned ON (1) by the relay 67a, and the signal (PWRO) is turned on.
N) passes through the latch 64 and the driver 65, so the battery supply switch (MS2-1) 54c is turned on (1) by the relay 67b.
Is done. When there is no converter error signal * CONVAL (1) and there is no power supply unit error signal (* PDUAL) (1)
At the time of, since the above three signals (PARON, * CONVAL, * PDUAL) pass through the NAND gate 66, the start signal of the converter 52 (*
PONCV) turns ON (0).

Therefore, as shown in the time chart of FIG. 7, the converter 52 or the power supply unit 51 causes the abnormal signal * CONVAL, * PDU
When AL is output (), converter 52 or power supply unit 51
In order to replace the
N) was turned off () and the circuit breaker (CB1) 51d was disconnected (). Then, because the battery power supply 54 backs up the battery power, it is different from the place where the converter 52 is mounted (for example, 50
m) After turning off the circuit breaker (CB2) 54b and the battery output circuit breaker (CB3) 54b, which are inputs to the battery device that are separated from each other, replace the converter 52 or the power supply unit 51 that has finally become abnormal. Was able to do ().

[Problems to be Solved by the Invention]

Therefore, when the converter or the power supply unit becomes abnormal, it takes time and effort to replace the converter or the power supply unit.

An object of the present invention is to smoothly replace the converter or the power supply unit when the converter or the power supply unit is abnormal.

[Means for solving the problem]

According to the present invention, the above object is as shown in the principle diagram of FIG.
A power supply unit (1) that converts the AC input power from one input side into a direct current and supplies the system power, and a converter that converts the system power from the power supply unit to a rectified voltage and sends it to the load unit (3) ( And a battery supply unit (4) having a voltage conversion unit for converting the voltage of another AC input power source for rectification and a battery charged by a DC current from the voltage conversion unit via a battery supply switch. In the device, by the backup switch (5) connected in the backup current supply path between the battery supply switch of the battery supply unit (4) and the output side of the power supply unit (1) and the input of the power signal (OWRON) When the power supply unit (1) is started, at least the power supply switch and the backup switch (5) in the power supply unit (1) are closed and the power supply device is controlled, and The control unit (6) for receiving the abnormal signal (* CONVAL, * PDUAL) from the power supply unit (1) to the data (2) is provided, and the control unit (6) is the abnormal signal from the converter or the power supply unit. Is received, the function of the power supply is stopped, and at least the power supply switch and the backup switch are opened.

[Operation] In the present invention, the abnormal signals * CONVAL, * PDUAL from the converter 2 or the power supply unit 1 are received as shown in the time chart diagram of the embodiment of the invention of FIG. 2 and the embodiment of the invention of FIG. And the control unit 6 sends an operation signal to the converter 2 (* PONC
The function of the power supply device is stopped by turning off V), and at least the backup switch 5 and each of the power supply switches of the power supply unit are simultaneously turned off.

Therefore, by turning off the circuit breaker (CB1) 21d for the AC input power to the power supply unit 1, power is not supplied from the battery supply unit 4, and the power supply to the converter 2 and the power supply unit 1 can be eliminated. Therefore, repairs and replacements are possible.

〔Example〕

FIG. 2 shows an embodiment of the present invention. In the figure, 1 is a power supply unit, which is a power supply switch (MS1-1) 21a, a rectifier circuit 21b, a switch control unit 21c, a circuit breaker (CB
1) It consists of 21d. The power supply switch (MS1-1) 21a is
When the switch (MS1-1) is ON, the AC input power is supplied to the converter 2 as system power. The rectifier circuit 21b is
The switch control unit 21c outputs a voltage conversion operation and an abnormal signal (* PDUAL) of the power supply unit 1 by replacing the exchange with DC. 21d is a circid breaker (CB1), which prevents the risk of circuit destruction due to increased current, and disconnects the power supply line when more than the specified amount of current flows.

Reference numeral 2 denotes a converter, which performs voltage conversion to supply power to the first load section 23 and the second load section 26 in the load 3, and includes an abnormality warning section 22a. The abnormality warning unit 22a is the converter 2
When is abnormal, an abnormal signal (* CONVAL) is issued. The first load unit 23 is a storage unit (memory element) of the MSU. The second load unit 26 is a part that controls a pipeline for reading data from the memory element of the MSU or writing data in the memory element, and an interface with a CPU or CHP (channel) that is a higher-level device. Here, it is simply called the control unit of the MSU.

4 is a battery supply unit, which is composed of a voltage conversion unit 24a, a circuit breaker 24b, a battery supply switch 24c, and a battery 24d. The voltage conversion unit 24a converts alternating current into direct current, and the circuit breakers (CB2, CB3) 24b prevent the risk of circuit destruction due to an increase in current, and disconnect the power supply line when a current exceeding a specified amount flows. The battery supply switch (MS2-1) 24c charges the battery when it is ON and supplies the battery power when it is backed up. The battery 24d is a power source used when the AC input power to the load unit 23 is stopped.

Reference numeral 6 denotes a control unit, which is a power signal (PWRON) input when the power supply is started and a converter abnormality signal (* CONVA
L) and the power supply unit abnormality signal (* PDUAL) to turn ON / OFF the switching unit Q7 of the voltage conversion unit 24a (* C
HGON) and a signal to turn converter 2 on and off (* PONCV)
The power supply switch (MS1-1) 21a, the battery supply switch (MS2-1) 24c, and the backup switch (MS3-1) 5 are turned on and off. Also,
When the control unit 6 receives an abnormal signal from the converter 2 or the power supply unit 1, the backup switch (MS3-1) 5
The power supply switch (MS _1-1 ) 21a and the battery supply switch (MS _2-1 ) 24c are turned off to prohibit the backup of the power supply by the battery, and the control signal (* PDUAL) to the converter 2 and the voltage conversion unit 24a. Stop sending the operation signal (* CHGON) to the switching section Q _{7 of} .

FIG. 4 is a time chart diagram showing the operation of FIG. In the figure, the same symbols as those in the time chart of the conventional circuit of FIG. MS3-1 represents ON / OFF of the backup switch 5. In Figure 4, *
CONVAL or * PDUAL, CONV unit is replaced or power supply is replaced.

FIG. 3 is a detailed configuration explanatory diagram of the control unit 6. Control unit 6
Indicates the power signal (PWRON) and converter error signal (* C
ONVAL) or a power supply abnormal signal (* PDUAL) is received, and the power supply switch (MS1-1) 21a, the battery supply switch MS2-1) 24c, and the backup switch (MS3-
1) Control 5 and * CHGON signal and * PONCV signal. In the figure,
Drivers 33, 35, 38 relays 39a, 39b, if the input is 1
39c is turned on, relay 39a is a power supply switch (MS
1-1) 21a is an operation relay, relay 39b is for operating a battery supply switch (MS2-1) 24c, and relay 39c is for operating a backup switch (MS3-1) 5. The latch 34 holds the ON state and is composed of, for example, a flip-flop.

The operation of the control unit 6 will be described below (see FIG. 3). When the power signal (PWRON) turns ON (1), the signal (PWRON)
* CHGON signal is ON because WRON) passes through knot gate 31
It becomes (0). The signal (PWRON) passes through the AND gate 32 and the driver 33, the relay 39a turns on the power supply switch (MS1-1) 21a, and the signal (PWRON)
The battery supply switch (MS2-1) 24c is turned on (1) by the relay 39b passing through the latch 34 and the driver 35. When there is no converter error signal * CONVAL (1) and when there is no power supply unit error signal (* PDUAL) (1),
Since the above three signals (PWRON, * CONVAL, * PDUAL) pass through the NAND gate 36, an operation signal (* PONC
V) turns ON (0). The above three signals (PWRON, * CONVA
L, * PDUAL) enters the driver 38 through the NAND gate 36 and the NOT gate 37, so the backup switch (MS3-1) 5 is turned ON (1) by the relay 39c.

Therefore, as shown in the time chart of FIG.
Abnormal signal * CONV issued by converter 2 or power supply unit 1
When the control unit 6 receives AL, * PDUAL (), the control unit 6 turns off the * PONCV signal and * CHGON signal at the same time (), and simultaneously controls the power supply switch, the battery supply switch, and the backup switch. (MS3-1) 5 for O
Set to FF (). Therefore, when the converter 2 or the power supply unit 1 becomes abnormal, the operator can detect the power signal (PWRO
N) to OFF (), circuit breaker (CB1) 21d
By disconnecting () the converter 2 or the power supply unit 1
It is possible to replace the maintenance of ().

〔The invention's effect〕

As described above, according to the present invention, since the power supply from the battery is cut off at the same time as the abnormality of the converter or the power supply unit, there is an effect that the maintenance replacement of the converter or the power supply unit can be performed in a short time. There is no annoyance and no danger.

[Brief description of drawings]

 FIG. 1 is a diagram for explaining the principle of the present invention, FIG. 2 is a circuit diagram of an embodiment of the invention, FIG. 3 is a control circuit diagram of an embodiment of the invention, and FIG. 4 is an embodiment of the invention. FIG. 5 is a conventional example circuit diagram, FIG. 6 is a conventional example control circuit diagram, and FIG. 7 is a conventional example time chart diagram. In the figure, 1: Power supply part 2: Converter 3: Load part 4: Battery supply part 5: Backup switch 6: Control part

Claims (1)

(57) [Claims] 1. A power supply unit (1) for converting an AC input power source via one input side into a direct current to supply a system power source, and a load unit (3) for converting the system power source from the power source supply unit to rectify it. A battery having a converter (2) to be sent to a battery), a voltage converter that converts the voltage of an AC input power source via the other input side to rectify it, and a battery that is charged by a DC current from the voltage converter via a battery supply switch. In a power supply device including a supply unit (4), a backup switch (5) connected in a backup current supply path between a battery supply switch of the battery supply unit (4) and an output side of the power supply unit (1). And a power signal (OWRON) is input to activate the power supply unit (1) and at least the power supply switch and the backup switch (5) are closed. And a converter (2) for receiving an abnormal signal (* CONVAL, * PDUAL) from the power supply unit (1). The control unit (6) is a converter or a power supply. A power supply device characterized by stopping the function of the power supply device and opening at least the power supply switch and the backup switch when an abnormal signal is received from the supply unit.