JPS5841368A - Battery capacity tester - Google Patents

Abstract

PURPOSE:To save energy in the testing of a set battery with an automatic capacity testing of a set battery performed by including a means of detecting the state of a battery, a data collector, a testing resistance and switching means. CONSTITUTION:Data is fed to a controller 7 corresponding to individual electrode voltage of backup batteries 3-1-3-n of power source 1 from data collector 9 to calculate an average voltage of a battery 3 based on the data. Then, when the average voltage is lower than a reference voltage in comparison therewith, the controller 7 outputs an control signal S. This changes over the contact of an electromagnetic switch 5 to make a resistor 6 a load whereby the capacity of the battery 3 is measured. The controller 9 collects data corresponding to a voltage across each battery 3 and sends it to a controller 7, which detects the terminal voltage based on the data. The results of the calculation are displayed on a numerical indicator. Thus, the capacity measurement of the set battery is completed thereby realizing the energy saving in the testing of the battery capacity.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a capacity tester for a storage battery, which is a backup energy source for a DC power supply.

When the commercial power supply is normal, the communication power supply device rectifies the commercial power supply and supplies the necessary DC power to the load. In addition, a storage battery is provided as a backup power source in order to continue supplying power to the load even in the event of a commercial power outage. Figure 1 shows the system W4 of the general device.
2 is a commercial power source, 2 is a rectifier that converts alternating current to direct current, δ is a battery pack constructed by connecting several storage batteries in series, and 4 is a load. This system operates as follows when the commercial power supply is normal.
AC power from a commercial power supply 1 is converted into a DC voltage VC necessary for the load by a rectifier 2, and 4°C power is supplied to the load.

At this time, the rectifier 2 supplies a maintenance charging current to the assembled battery 8 to compensate for self-discharge, and generally the storage battery 1
Each battery is charged at once at a constant w5 voltage of Z/jV to 2/rV at a voltage commensurate with the number of batteries. Also, should the number of storage batteries be adjusted appropriately to match the load voltage? The storage battery capacity is determined from the required load current and retention time during a power outage. Therefore, in the event of a power outage, this storage is available! The required power is supplied to the load from the reservoir.

By the way, in actual assembled batteries, due to the difference in the self-discharging characteristics of individual storage batteries, even if they are charged continuously, the individual 1
Due to the large variation in battery capacity and the deterioration of the battery's S, active material, and separator, the capacity may decrease and the battery may not be able to supply the necessary energy in the event of a power outage. For assembled batteries,
Since then, capacity tests of the assembled batteries have been carried out at intervals of 1 year to λ years vc/times, and the battery containers are always kept in hand and used during power outages. However, in this method, the terminal voltage, which represents the state of the battery,
Characteristics such as the specific gravity of the electrolyte are constantly monitored and periodically analyzed, and capacity tests are not conducted based on the results; instead, capacity tests are simply performed artificially at very long intervals. Therefore, the battery capacity cannot be accurately determined at all times, battery deterioration cannot be accurately detected, and a large amount of IP haze is required to carry out the container test.

In order to eliminate these drawbacks, the present invention constantly monitors the barking of each storage battery in the assembled battery, and when an abnormality occurs, automatically performs a capacity test of the assembled battery. This allows you to know the correct battery capacity, and the details are shown in the drawing below.

FIG. 2 is a block diagram showing the configuration of a first embodiment of the present invention, and in this figure, parts corresponding to those in FIG. 1 are given the same reference numerals. In Figure 2, reference numeral 8
-1 to &-n are storage batteries connected in series, each forming the assembled battery 8, and the e terminal of the 1111 cell 8-1 is 1! It is connected to the common terminal 5C of the magnetic switch 6, the terminal 6 of the electromagnetic switch b is connected to one end of the resistor 6 for capacity testing of the assembled battery 8, and the terminal 6b of the electromagnetic switch b is connected to one end of the rectifier 2. Output terminal VCC18 is connected. The electromagnetic switch 6 is
It is a switch that is switched and controlled by a control signal S output from a controller to be described later, and when the control signal S is output, the common terminal 5c and the terminal 5JI are connected,
When the signal is not output, the common terminal 5C and the terminal 5b are connected.

Further, the e terminal of the storage battery 3-n is connected to the other end of the resistor 6 and the other output i of the rectifier 2, and the storage batteries 8-1 to 8
-n voltages are applied to the input terminals 9-1 to 9-1 of the data recording device 9 via leads @8-1 to 8-n (detector #), respectively.
9-n. The data recording device 9 is recorded at a fixed period (
Each input terminal 9-1 to 9-
The voltages obtained at n are sequentially converted into digital signals and recorded in an internal memory, and the recorded data is supplied to the controller 7 when all data has been recorded. The controller 7 determines whether the battery pack 8 is normal or abnormal based on the data supplied from the data recording device 9, and outputs a control signal 8 if the battery pack 8 is abnormal. In addition, this condylolaph has a function of measuring the capacity 1 (AH) of the assembled battery 8 when the assembled battery 8 is abnormal.

Next, the specific operation of the circuit having the above configuration will be explained.

Data recording equipment! When data corresponding to the voltage vcM across each of the storage batteries 8-1 to 8-n is supplied from II9 to the controller 7, the controller 7 first calculates the average voltage of the storage batteries 8-1 to 8-n based on each data. do. Next (in step 1), the calculated average voltage is compared with a reference voltage preset in the a-rough.

In addition, as for this reference voltage, the floating charge voltage of the storage battery is xisv at -#, and the 膆联館 is about L10V, so YuOj■~! Approximately 10V is appropriate. If the average voltage is higher than the reference voltage, the control signal S is not output. In this case, the assembled battery 8 is normal, and the controller 7 is in a dormant state until the next data is output from the data recording device 9. On the other hand, when the average voltage is lower than the reference voltage, that is, when the assembled battery 8 is abnormal, the controller 7 outputs the control signal S. As a result, the contact point of the electromagnetic switch b is switched, and the terminal 5 of the electromagnetic switch 6 is switched.
1 and the common terminal 5c, and thereafter the capacity of the assembled battery 8 is determined. That is, when the ms switch 6 is switched, the resistor 6 is connected to both ends of the assembled battery 8, and the electrical energy being applied to the assembled battery 8vc is sequentially discharged via the resistor 6.

On the other hand, the data recording device 9 records data corresponding to the voltage 1'(1') across each of the storage batteries 8-1 to 8-0 at a constant cycle (this cycle is shorter than the basic cycle described above), and the controller 7
send to The controller 7 detects the voltage across each storage battery 8-1 to g-n based on data supplied from the data recording device 9. Then, when any of the voltages becomes equal to or less than a preset sound pressure, it is recognized as the discharge end time, and the control signal S is turned off. As a result, the electromagnetic switch 5 is switched, and the output voltage of the rectifier 2 is again supplied to both ends of the assembled battery 8. After the controller 7 turns off the control signal S,
The capacity of the assembled battery 8 (
A) Calculate i) and display the calculation result on a numerical display (not shown).

In this way, the measurement of the capacity of the assembled battery 8 is completed.

Next, the second embodiment of this invention will be explained. FIG. 3 is a pull diagram showing the 111 configuration of the second embodiment of this invention. are given the same reference numerals. The difference between this illustrated circuit and the circuit illustrated in FIG. 2 is that there are two rectifiers and an electromagnetic switch 5A. That is, the rectifier 2A has a main signal input terminal 10, and when the control signal S is supplied from the controller 7 to the drive signal input terminal 10, the output of the rectifier 2A is turned off. Further, the electromagnetic switch 5A is an on/off switch, and one terminal of the electromagnetic switch 5A is an on/off switch.
The e-terminal 1 of the storage battery 8-1 is connected to one end of the resistor 6, and the other terminal is connected to one end of the resistor 6.The e-terminal of the storage battery 8-1 is directly connected to one output end of the rectifier 2A. The operation of the circuit shown in this figure is for capacitance measurement (control signal S
is output), the five IC electromagnetic switches are turned on, and the resistor 6 and load 4 are both VC connected as a load of the assembled battery 8, and at this time, the output of the rectifier 2A is turned off. This circuit differs from the circuit shown in FIG. 2 in that the circuit shown in FIG.

In the eleventh second embodiment described above, the leads @8-1 to 3 are used as the detection means for detecting the shape of the assembled battery 8.
-n was used to determine whether the assembled battery 8 was normal or abnormal based on the 1i5i terminal voltage of each storage battery δ-1 to 8-n.
A hydrometer for measuring the upper molds of 3-n to 3-n may be used, and whether the assembled battery 8 is normal or abnormal may be determined based on the output of this hydrometer. In addition, in the first, tl, and second embodiments described above, all the storage batteries 8-1 to 3 constituting the assembled battery 8
- n is recorded, but it is also possible to set II number of storage batteries in the assembled battery δ as pilot batteries and record only the data of this number of pilot batteries.

Since it has a hook device, a controller, a test resistor, and a switching means, automatic VC testing is possible! The oil capacity test can be carried out and the result is #II! According to this invention, it is possible to always know the accurate battery assembly and battery capacity.
A highly maintainable and reliable backup energy source can be secured.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the structure of a gastrointestinal device having a backup energy source, FIG. 2 is a block diagram showing the structure of a first embodiment of the present invention, and FIG. FIG. 2 is a block diagram showing the configuration of an embodiment. 2.2A... Rectifier, 8... Battery pack,
8-1 to 8-n...Storage battery, 5.5A...
...Electromagnetic switch (switching means), 6...Resistor, 7...Controller, 8-1~g-n...
. . . Lead Ih (detection means), 9 . . . Data recording device k, 10 . . . Phase drive signal input terminal. Figure 1 Figure 12

Claims (1)

[Scope of Claims] (i) In a battery capacity tester for testing the capacity of a battery pack consisting of a plurality of storage batteries connected in series and connected in parallel between the output terminals of a rectifier, IIWl in the battery pack, a detection means for detecting the state of each of the storage batteries; a data recording device for recording the output data of each of these detection means; and a data recording device for determining whether the assembled battery is normal or abnormal based on the data recorded in the data recording device. In case of % abnormality Ic1llJ I
a controller that outputs a II signal; a resistor for testing the assembled battery; switching is controlled by the control signal, and when the control signal is output, the resistor or the resistor and the resistor are connected between both ends of the assembled battery; A battery capacity l tester comprising switching means for connecting a load and connecting the assembled battery to a VC connection between output terminals of the rectifier when the control signal is not output. (z) The battery according to claim 1, wherein the rectifier has a drive signal input terminal, and when the control signal is applied to the drive signal input terminal, the output thereof is turned off. Capacity tester.