JPH0360339A - Battery charging controller - Google Patents

Abstract

PURPOSE:To present a DC power source which can sufficiently cope with a frequency happening service interruption, by charging a back-up battery always except at the time of the service interruption, with the DC power source for supplying power to an equipment from an AC power source. CONSTITUTION:From a power supply section 1, power is fed to a battery 4 and a load section via switches MS1-1, MS2-1, MS3-1. By a control section 6, with service interruption detecting signal (*INVA) from a service interruption detecting circuit 5 and power signal (PON) from an external section, and battery back-up-unnecessary signal (*DISAB), the power supply is controlled. The charging switch MS1-1 is turned ON/OFF with the only service interruption detecting signal regardless of the signals PON, *DISAB. In other words, charging is always performed except at the time of service interruption, and so can the battery sufficiently cope with the frequently happening service interruption.

Description

[Detailed Description of the Invention] [1 Required] With regard to a battery charging control device during a power outage of an AC input power source, the purpose of this invention is to provide a battery that can sufficiently cope with frequently occurring power outages. a power supply unit that converts the power from the MS2 into direct current and supplies system power;
-1), which receives system power supply through the power supply unit; and a second load power supply switch (MS3-1) from the power supply unit;
1) a second load section that receives system power supply through the power supply section; and a battery charging switch (MSl-1) from the power supply section.
A power outage detection circuit that outputs a power outage signal when an AC input power outage is detected, and a power signal (PON) that is input from the outside. The battery charging switch (MSI-1) and the first load power supply switch (MS
2-1), second load power supply switch (MS3-1)
has a control unit that controls ON/OFF of the first load power supply switch (MS2-1
) is turned on when the power signal (PON) is input, and the battery hack-up unnecessary instruction signal (*DIS
AB) and power failure detection signal (*INVA) are input, it turns 0FF and the second load power supply switch (MS3-
1) is turned on when the power signal (PON) is input,
When the power outage detection signal (*INVA) is OFF, the battery charging switch (MSI-1) is connected to the power signal (PON) and the battery backup unnecessary instruction signal (*DI 5A).
B) is turned on regardless of power outage detection signal (*IN
VA) is input and the power signal (PON) is OFF.
or when the power outage detection signal (*INVA) is input and the battery backup unnecessary instruction signal (*DISAB) is input.
) is configured to turn off the pantry charging switch (MSI-1) when it is on.

[Industrial application field]

The present invention relates to a battery charging device.

[Conventional technology]

FIG. 5 is a conventional diagram showing a battery charging device. In the figure, reference numeral 51 denotes a power supply section, which converts AC input power into DC to supply system power. It has a switching section Ql, and this switching section Q1 outputs a pulse signal and performs voltage conversion. 52 is a first load section, for example, a converter that requires backup; 53 is a second load section, which outputs a power signal (PON
) is a converter operated by 57 is a battery charging switch (MSI-1), which charges the battery 54 and supplies power from the battery in the event of a power outage; 58 is a first load power supply switch (MS2-1), which is turned on At times, power is supplied to the first load section 52. 59 is the second load power supply switch (MS3
-1), and is turned on and off by a power signal (PON), and when turned on, supplies power to the second load section 53. 55 is a control circuit (for example, configured as shown in FIG. 6), which includes a power signal (PON) and a battery backup unnecessary instruction signal (*DISAB) that informs the first load section 52 whether or not battery backup is necessary. The power signal (PON) is used to connect the battery charging switch (MSI-1) 57, the first load power supply switch (MS2-1) 58, and the second load power supply switch (M
S3-1) 59 is turned ON and OFF, and the battery backup unnecessary instruction signal (*DI 5AB) is turned ON and OFF of the battery charging switch (MSI-1) 57.
It performs the FF operation, and also performs the ON/OFF operation of the *CHGON signal that operates the switching unit Ql of the power supply unit 51.

FIG. 7 is a time chart diagram of a conventional circuit.

In the figure, the AC input is a power source to the power supply means 51,
PON is a power signal ON/OFF.

MSI-1, MS2-1. MS3-1 turns ON and OFF the battery charging switch 57, the first load power supply switch 58, and the second load power supply switch 59, respectively.
represents the state. *CHGON signal is the power supply circuit 5
When the *CHGON signal is turned on, the switching unit Q1 outputs a pulse signal and operates the power supply unit 51. BAT is a battery 1, a backup unnecessary instruction signal (*D I
5AB) is not ON, the power is supplied during a power outage.

FIG. 6 is an explanatory diagram of the detailed configuration of the control circuit 55.

In the figure, drivers 62 and 65 turn on relays 64a, 64b, and 64c when the input signal is 1, and relay 64a is a battery charging switch (MSI-1) 5.
Move 7. Further, the relay 64b operates the load power supply switch (MS2-1) 5B, and the relay 64c operates the load power supply switch (MS3-1) 59.

The operation of the control circuit 55 will be described below (see FIG. 6).

When the power signal (PON) is 0N (1) and the backup unnecessary instruction signal (*DISAB) is 0FF (1), the power signal (1) and the backup instruction signal (1) enter the AND gate 61 and pass through the driver 62. So relay 64a
By battery charging switch (MSI-1) 57
is turned on. In addition, as shown in the figure, knot gate 63
Through this, the *CHGON signal becomes ON (0). The power signal enters the driver 65 and relays 64b, 6
Load power supply switch (MS2-1) 58 by 4c
Then, the load power supply switch (MS3-1) 59 is turned on.

For this reason, as shown in the time chart of Fig. 7, the power signal (PON) is turned on (■, ■, ■), 0FF (■, ■
) At the same time, *CHGON signal and battery supply switch (MSI-1) 57 are turned ON.

The battery was being charged by turning it off.

In addition, a backup unnecessary instruction signal (* DI 5AB
) ON (■), OFF (■)
The N signal and battery supply switch (MSll) 57 were turned on and off.

[Problem to be solved by the invention]

Therefore, even if there is an AC input power source, the power signal (PON)
If it is OFF, the battery will not be charged, and even if there is an AC input power source, if the no-backup instruction signal (*DISAB) is ON, the battery will not be charged. Therefore, if power outages occur frequently, you may need to use a larger capacity battery,
It was necessary to lengthen the input time.

An object of the present invention is to provide a battery that can sufficiently cope with frequent power outages.

[Means to solve the problem]

FIG. 1 is a diagram explaining the principle of the present invention. In the figure, 1 is a power supply unit that converts alternating current to direct current, 2 is a first load unit that requires backup by a battery 4, and 3 is a second load unit that is a load power switch ( M
4 is a battery, which is provided via a battery charging switch (MSI-1) and is charged with power from the power supply unit 1. 5 is a power outage detection circuit which outputs a power outage signal when detecting a power outage in the AC input power supply; 6 is a control unit that controls the first load power supply switch (MS2-1) with a power signal (PON); ) is input, and the battery backup unnecessary instruction signal (*DI 5AB) and power outage detection signal (*
The second load power supply switch (MSI-1) is turned OFF when the power signal (PON) is input, and the battery charge switch (MSI-1) is turned OFF when the power signal (PON) is input. ) as the power outage detection signal (* INVA
) is OFF, it is turned ON regardless of the power signal (PON) and battery backup unnecessary instruction signal (*DI 5AB), and when the power failure detection signal (*INVA) is input and the power signal (PON) is OFF, Alternatively, the battery charging switch (MSI-1) is configured to be turned off when the power failure detection signal (*INVA) is input and the battery bank up unnecessary instruction signal (*D[5AB) is turned on.

[For production]

In the present invention, as shown in FIG.
And no battery backup required regardless of the instruction signal,
Always charge battery 4.

Therefore, the battery will be charged as long as there is an AC input power source, regardless of whether the power signal (PON) is ON or OFF and whether there is a backup unnecessary instruction signal C*DI5AB).

〔Example〕

FIG. 2 is a block diagram of an embodiment of the present invention, showing a battery charging device. Reference numeral 21 denotes a power supply unit, which converts AC input power into DC and supplies system power, and has a switching unit Q1.
outputs a pulse signal and performs voltage conversion. A battery charging switch (MSI-1) 27 charges the battery 24 when turned on, and a load power supply switch (MS2-1) 28 supplies power to the first load section 22 when turned on. The load power supply switch (MS3-1) 29 supplies power to the second load section 23. 26 is a power failure detection circuit,
25 is a control circuit (for example, configured as shown in Fig. 3) that detects a power outage in the input power supply and checks whether there is an AC input power supply, and a power signal (PON) and an indication that battery backup is not required. Signal (*DI 5AB)
and a power outage signal (*INVA) output from the power outage detection circuit 26.
) and remove the battery charge switch (MSI-1).
27, load power supply switch (MS2-1) 28, load power supply switch (MS3-1) 29, and power supply section 2t
The *CHGON signal is output to operate the switching unit Q1.

FIG. 4 is a time chart diagram of the inventive circuit.

In the figure, the same symbols as in the time chart of the conventional circuit in FIG. 7 represent the same things, and *TNVA is a power failure detection signal output from the power failure detection section, which notifies the presence or absence of AC input.

FIG. 3 is a detailed structural explanatory diagram of the control circuit 25. As shown in FIG.

In the figure, drivers 35, 36, and 39 turn on relays 38a, 38b, and 38c when the input signal is 1, and relay 38a is the battery charging switch (MSI-1) 27.
move. Further, the relay 38b operates the load power supply switch (MS2-1) 28, and the relay 38c operates the load power supply switch (MS3-1) 29.

The operation of the control circuit 25 will be described below (see FIG. 3).

The power signal (PON) is 0N (1) and the battery backup unnecessary instruction signal (*DISAB) is OFF (1).
), and the power outage signal (*INVA) is OFF (1), the battery charging switch (MS 1-1) 27
The power signal (1), battery backup unnecessary instruction signal (1), and power outage signal (1) are at the OR gate 31.33
Since the signal passes through the AND gate 32 and enters the driver 35, it is turned on by the relay 38a. Further, as shown in the figure, since the power passes through the AND gate 34 and enters the driver 36, the load power supply switch (MS2-1) 28 is turned on by the relay 38b. Then, as shown in the figure, since it passes through the Nant gate 37, the *CHGON signal becomes ON (0).

The load power supply switch (MS3-1) 29 is turned on by the relay 38c since the power signal is input to the driver 39. For this reason, as shown in the time chart of FIG. 4, the battery charging switch (MSI-1) 27
Turn the power signal (PON) ON (■, ■, ■), OFF
(■,■) and backup unnecessary instruction signal (*D I
5AB) ON (■).

It has nothing to do with OFF (■), and the power failure signal (*■NV
When A) indicates the presence of input, the battery is charged by turning on the *CHGON signal and the battery charging switch (MSI-1) 27.

Conventionally, the battery was not charged when the power signal (PON) was OFF even though there was an AC input power source, and when the battery backup unnecessary instruction signal (*DI 5AB) was ON. However, in the embodiment, the battery is charged as long as there is an AC input power source. Therefore, the battery is in a fully charged state.

[Effects of the Invention] As explained above, according to the present invention, as long as there is an AC input power source, the battery is charged, so even if power outages occur frequently, the specified discharge time can be maintained. Batteries need to be smaller, charging time is shorter, batteries are cheaper, and there are no longer any restrictions on usage for users.

[Brief explanation of drawings]

Fig. 1 is a diagram 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, Fig. 4 is a time chart diagram of an embodiment of the invention, FIG. 5 is a circuit diagram of a conventional example, FIG. 6 is a control circuit diagram of a conventional example, and FIG. 7 is a time chart diagram of a conventional example. In the figure: Power supply section: First load section: Second load section; Battery: Power failure detection circuit: Control section → ( →

Claims (1)

[Claims] A power supply unit (1) that converts power from an AC input power source into DC and supplies system power; and the power supply unit (1).
A first load section (2) receives system power supply from the power supply section (1) via a first load power supply switch (MS2-1), and a second load power supply switch (M
A second load section (3) receives system power supply via the power supply section (S3-1), and a battery charging switch (MS1) from the power supply section (1).
-1), and a battery (4) that backs up the first load section, and a power outage detection circuit (5) that outputs a power outage signal when it detects a power outage of the AC input power source.
), the battery charging switch (MS1-1) and the first load power supply switch ( MS2
-1), a control unit (6) that controls ON/OFF of the second load power supply switch (MS3-1), and the control unit (6) controls the first load power supply switch (MS3-1).
2-1) is turned on when the power signal (PON) is input, and the battery backup unnecessary instruction signal (*
DISAB) and power failure detection signal (*INVA) are input, the second load power supply switch (M
S3-1) is set to O when the power signal (PON) is input.
When the power failure detection signal (*INVA) is OFF, the battery charging switch (MS1-1) is turned off and the power signal (PON
) and battery backup unnecessary instruction signal (*DISA
B) is turned on regardless of the power failure detection signal (*INVA
) is input and the power signal (PON) is OFF,
Or, turn off the battery charging switch (MS1-1) when the power outage detection signal (*INVA) is input and the battery backup unnecessary instruction signal (*DISAB) is on.
A battery charging control device characterized by: