JPH05207642A - Discharge state detector for battery - Google Patents

Abstract

PURPOSE:To protect a battery against overcharge by detecting the current to be discharged from the battery to a load at the time of power interruption and setting an end of discharge voltage depending on the magnitude of thus detected current and then stopping discharge when the output voltage of the battery drops below thus set end of discharge voltage. CONSTITUTION:AC power is rectified and smoothed and fed through a DC-DC converter 2 to a load 3 whereas a power from a power supply 11 is rectified through a charging rectifier RC1 and fed to a battery 12. Upon power interruption under that state, a comparator 15 is applied with a voltage higher than a voltage reference EV from the battery 12 and a transistor TR 16 is turned ON thus turning a relay 14 ON. Consequently, a contact r1 is closed and power is fed from the battery 12 to the load 3. A current detecting element 17 detects discharge current through a detecting circuit 18. An end of discharge voltage is modified 19 according to the magnitude of the discharge current thus making the voltage reference EV variable. When the voltage of the battery 12 drops to a modified reference voltage, a comparator 15 turns the TR 16 OFF to de- energize the relay 14 thus opening the contact r1. According to the constitution, the battery 12 is protected against overdischarge.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for continuing operation by battery backup in the event of a power failure, and more particularly to a battery discharge state detecting device for controlling the output voltage of the battery so as not to be over-discharged based on the discharge of the battery. Regarding

[0002]

2. Description of the Related Art For example, as shown in FIG. 4, an AC voltage is rectified by a rectifying / smoothing unit 1, and a smoothed DC voltage is converted into a DC voltage.
In a device in which the DC converter 2 further performs DC conversion to operate the load 3, when the AC power supply fails, it is possible to supply power from the battery 12 to the DC-DC converter 2 and continue the operation of the load 3. Has been done. As the battery 12, for example, a Ni-Cd battery or a lead battery is used.

In this case, a so-called battery unit with a charger 10 is used which charges the battery 12 when the AC power source is on. The battery unit with a charger 10 includes a power source 11, a battery 12, an auxiliary power source 13, a relay 14, a comparator 15, a switching transistor 1.
6. It is equipped with rectifiers RC1 and RC2. Here, the auxiliary power supply 13 is a DC of the comparator 15, the transistor 16, etc.
It becomes a power source.

When the AC power source is on, the DC output from the rectifying / smoothing unit 1 is further converted by the DC / DC converter 2 and supplied to the load 3, as described above. At this time, in the battery unit with a charger 10, the output of the power source 11 is rectified by the rectifier RC1 for charging, and the battery 12 is charged. At this time, the output of the auxiliary power supply 13 is the relay 14
Is applied to the collector of the transistor 16 via. On the other hand, the output voltage of the battery 12 and the reference voltage E are applied to the comparator 15, and when the output voltage of the battery 12 is larger than the reference voltage E, the comparator 15 outputs "1" and the transistor 16 is turned on. When turned on, the relay 14 is energized, and the contact rl of the relay 14 is turned on.

In this state, if the AC power source fails, the output voltage of the battery 12 is higher than the reference voltage E. As described above, the transistor 16 is in the ON state, so that the relay 14 maintains the ON state. Since the contact rl of 14 also remains in the ON state, the output voltage of the battery 12 is applied to the DC / DC converter 2 via the rectifier RC2, and this time the load 3 continues to operate by the output of the battery 12. Become.

The output voltage of the battery 12 also decreases if the AC power failure continues for a long time. When the voltage becomes equal to or lower than the reference voltage E, the comparator 15 outputs "0" and the transistor 16
Is turned off, the relay 14 is deenergized, and its contact rl is turned off. Therefore, the DC / D of the battery 12
The power supply to the C converter 2 is stopped and the operation of the load 3 is also stopped.

Here, when the output voltage of the battery 12 becomes equal to or lower than the reference voltage E, the power supply to the DC / DC converter 2 of the battery 12 is stopped. If the power supply is continued, the voltage of the battery 12 is discharged. This is to prevent the problem that what is called over-discharge, that is, discharge to a voltage equal to or lower than the cutoff voltage, reliable charging is not performed at the next charging, and the life is shortened.

To prevent this over-discharge, a circuit for disconnecting the battery 12 from the DC / DC converter 2 when the battery voltage reaches the discharge end voltage is provided.

[0009]

As described above, in the device having the battery backup function, the discharge current and the discharge end voltage of the battery 12 are as shown in FIG.
The relationship is as shown in (B). That is, as shown in A, when the discharge current is 0.5 A, the discharge end voltage is as high as 10 V, and when the discharge current is 10 A, as shown in B, the discharge end voltage is as low as 8 V. In any case, if the discharge is continued further than the respective discharge end voltage, the reliable charging will not be performed at the next charging, and the life will be shortened.

As shown in FIG. 4 (b), the discharge current and the discharge end voltage become high when the discharge current is small, and the discharge end voltage becomes low when the discharge current is large. This shows that it is necessary to determine the discharge current in order to accurately determine the discharge cutoff voltage.

In the conventional battery unit 10 with a charger, the reference voltage E indicating the discharge end voltage set in the comparator 15 has a fixed value, and therefore the discharge current also has a value corresponding thereto. Moreover, if the discharge current is determined, it is limited to a specific application corresponding to the discharge current, resulting in a problem that versatility is lost.

For a battery unit with a charger in which the discharge end voltage is set low (that is, in a case where the discharge current is large), when the discharge current is small, the discharge end voltage is originally set high. There is a problem that the battery life is shortened because it is over-discharged because it is used in a state where the place where it should be set is set low.

On the contrary, when a large discharge current is taken for the battery unit with a charger in which the discharge end voltage is set high, the battery performance cannot be fully utilized.
The problem arises that the battery becomes larger than necessary.

[0014]

In order to solve these problems, the present invention sets the reference voltage EV of the comparator 15 variably based on the discharge current of the battery 12, as shown in FIG. is there.

In FIG. 1, 17 is a current detecting element, 18 is a discharge current detecting circuit, and 19 is a discharge end voltage changing circuit.

[0016]

The discharge current of the battery 12 is converted into an electric signal (for example, voltage) by the current detecting element 17. The discharge current detection circuit 18 detects the discharge current value of the battery 12 based on this. Then, this discharge current value is transmitted to the discharge end voltage changing circuit 19.

As a result, the discharge end voltage changing circuit 19 is
The reference voltage EV is set to the optimum discharge end voltage for the discharge current value of the battery 12. Therefore, the battery 12 can be set to an optimum discharge end voltage according to the discharge current determined by the load 3, so that the battery can be used without shortening the battery life due to overdischarge.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the present invention will be described with reference to FIG. 1 and other drawings. In the figure, the same symbols as those in the other figures indicate the same parts. The output voltage of the battery 12 is applied to one side of the comparator 15 and the reference voltage EV is applied to the other side of the comparator 15, and the two are compared, but the reference voltage EV is not fixed and can be variably adjusted. Is.

The current detecting element 17 produces an output according to the magnitude of the current, and is composed of, for example, a resistor.
It outputs a voltage according to the flowing current. The discharge current detection circuit 18 detects the output current value of the battery 12 based on the output transmitted from the current detection element 17.

The discharge end voltage changing circuit 19 sets the value of the reference voltage EV based on the current value transmitted from the discharge current detecting circuit 18. For example, when the current value transmitted from the discharge current detection circuit 18 is 0.5 A, the value of the reference voltage EV is set to 10 V, and when the current value transmitted from the discharge current detection circuit 18 is 10 A, The value of the reference voltage EV is set to 8V.

Next, the operation of FIG. 1 will be described. When the AC power source is on, the DC / DC converter 2 converts the rectified and smoothed output from the rectifying / smoothing unit 1 into DC, and the load 3 operates. At this time, in the battery unit with a charger 10,
The battery 12 is charged by the output transformed by the power supply 11. At this time, the comparator 15 outputs "1" because the output voltage of the battery 12 is higher than the reference voltage EV,
Transistor 16 turns on and relay 14 is energized, turning on contact rl.

When the AC power supply fails in this state, the comparator 15 outputs "1", so that the transistor 16 maintains the ON state, and the contact rl of the relay 14 also maintains the ON state. The output of 12 is a rectifier RC
The load 3 is applied to the DC / DC converter 2 via 2 and the load 3 continues to operate by the output of the battery 12.

If the AC power source is out of power for a long time, the output voltage of the battery 12 gradually decreases. When the voltage becomes equal to or lower than the reference voltage EV, the comparator 15 outputs "0", the transistor 16 is turned off, the relay 14 is deenergized, the contact rl is opened, and the power supply to the load 3 is stopped.

At this time, since the reference voltage EV is set according to the discharge current of the battery 12 as described above, the reference voltage EV is set to a value according to the load 3, and the battery 12 is terminated according to the state. It is not discharged below the voltage, that is, it is not over-discharged.

Next, a second embodiment of the present invention will be described with reference to FIG. 2A is a configuration diagram of the battery unit with a charger according to the second embodiment, and FIG. 2B is a configuration diagram of the discharge end voltage setting switch S.

In the second embodiment of the present invention, when the discharge current of the battery is known in advance from the load 3, the changeover switch S ₀ , so that the discharge end voltage corresponds to the discharge current,
It is set by S ₁ ... Sn or the like. As shown in FIG. 2B, when the discharge current is 0.5 A, the changeover switch S ₀
Is turned on, and in the case of 10 A, the changeover switch Sn is turned on. Note that R is a resistor and V is a DC power source.

As a result, the changeover switches S _{0 to} Sn are selectively turned on according to the discharge current to adjust the control voltage Vc to the discharge end voltage changing circuit 19-1, and the reference voltage EV is set based on this. Can be set. In this way, it is possible to set the end-of-discharge voltage that matches the discharge current of the battery. Of course, the changeover switches S _{0 to} S
Instead of selecting one n by the discharge current, the control voltage Vc can be adjusted by a plurality of combinations.

A third embodiment of the present invention will be described with reference to FIG. In the third embodiment, the discharge voltage characteristic of the battery 12 is
As shown in FIG. 4 (B), when the discharge current is large, a short time T
By using the fact that the voltage drops at ₀ and the voltage drop is small when the discharge current is small, the magnitude of the discharge current is detected by detecting the output voltage of the battery 12, and the reference voltage EV is set accordingly. It is a thing.

Therefore, in the third embodiment, when the battery unit with a charger detects the power failure of the AC power supply by the power failure detection circuit 21, the timer 22 is operated. And Figure 4
As shown in (B), when the time T ₀ has passed, the comparator 2
3 is operated to detect the output voltage of the battery 12.

Here, the comparator 23 is composed of comparators 23L, 23M and 23S as shown in FIG. 3B, and a large reference voltage EL is applied to the comparator 23L, and the comparator 23
A small reference voltage ES is applied to S. Reference voltage EL
For example, the curve A at time T ₁ in FIG.
The voltage of the curve B at time T ₁ is applied as the reference voltage ES. Then, as the reference voltage EM, a value halfway between these values is applied.

Therefore, the discharge current of the battery 12 is the curve A.
If it is small, as shown in, each of the comparators 23L, 23M, 2
"1" is output from all 3S, and the discharge current is the curve B.
If it is larger, the comparators 23L and 23M respectively output "0", and the comparator 23S outputs "1".

If it is in the middle, for example, the comparator 23
L outputs "0", and the comparators 23M and 23S respectively output "1". The discharge end voltage changing circuit 19-2 is
The state of the discharge current of the battery 12 is discriminated from the output patterns of these comparators 23L to 23S, and the reference voltage EV adapted to this is set.

That is, the battery voltage is detected after a certain time from the power failure, and if the battery voltage is above a certain current, it is determined that the discharge current is small, and the discharge end voltage is set to a high level. When the battery voltage is low, it is determined that the discharge current is large, and the discharge end voltage is set to a low level.

Although an example in which three comparators are used has been described with reference to FIG. 3B, the invention is not limited to this and can be appropriately selected. Further, as shown in FIG. 3 (C), the output voltage of the battery 12 is compared with the DC voltage detection unit 23.
It is also possible to measure and detect -1 and adjust the set value of the reference voltage EV by the discharge end voltage changing circuit 19-3 based on this. In this case, as the DC voltage detection unit 23-1,
For example, an operational amplifier can be used, and its output can be made variable according to the output voltage of the battery 12. According to this, the output voltage of the battery 12 can be accurately and automatically detected.

[0035]

According to the present invention, it is possible to determine the optimum discharge end voltage according to the magnitude of the discharge current of the battery. Therefore, it becomes possible to effectively prevent over-discharge of the battery and use the battery without shortening its life. Moreover, even if the discharge current is large, the discharge can be stopped at the discharge end voltage corresponding thereto, so that the battery performance can be fully utilized.

[Brief description of drawings]

FIG. 1 is a configuration diagram of an embodiment of the present invention.

FIG. 2 is a configuration diagram of a second embodiment of the present invention.

FIG. 3 is a configuration diagram of a third embodiment of the present invention.

FIG. 4 is a diagram illustrating a conventional example and a battery discharge characteristic.

[Explanation of symbols]

 1 Rectifying / Smoothing Part 2 DC / DC Converter 3 Load 10 Battery Unit with Charger 11 Power Supply 12 Battery 13 Auxiliary Power Supply 14 Relay 15 Comparator 19 Discharge End Voltage Change Circuit

Claims (4)

[Claims] 1. A battery (12) and a battery (12)
In a power supply device that has a charging means RC1 for charging the battery and keeps the operation of the load backed up by the battery (12) during a power failure, a discharge current detection means (18) for detecting a discharge current of the battery (12), The battery (12) is provided with a discharge end voltage changing means (19) for setting a discharge end voltage according to the discharge current, and a comparing means (15) for comparing the output voltage of the battery (12) with the discharge end voltage. When the output voltage of) reaches the discharge end voltage according to the discharge current, the output circuit of the battery (12) is turned off to disconnect the battery (12) from the load side. State detection device. 2. The comparing means for comparing with a specified voltage is used as the discharge current detecting means, the voltage of the battery is checked after a fixed time from the occurrence of the power failure, and the discharging end voltage changing means is controlled based on this. The battery discharge state detection device according to claim 1, wherein the battery discharge state detection device is configured. 3. The battery discharge state detection device according to claim 1, wherein a plurality of comparators are used as the comparison means, and different specified voltages are set to the respective comparators. 4. A battery (12) and the battery (1
In a power supply device having a charging means RC1 for charging 2), which is backed up by the battery (12) in the event of a power failure to maintain the operation of the load, a discharge end voltage setting switch means S corresponding to the discharge current of the battery (12). A discharge end voltage changing means (19-
1) and a comparison means (15) for comparing the output voltage of the battery (12) with the discharge end voltage, and when the output voltage of the battery (12) becomes the discharge end voltage according to the discharge current. A battery discharge state detection device characterized in that the output circuit of the battery (12) is turned off to disconnect the battery (12) from the load side.