CN204190430U - A kind of monitoring device of lithium battery - Google Patents

Abstract

The utility model discloses a kind of monitoring device of lithium battery, comprise Li-Battery monitor chip (10), single-chip microcomputer (20), charactron (30), DC-DC transducer (50), described battery detection chip (10) is connected with lithium battery (40), described single-chip microcomputer (20) is connected with battery detection chip (10), described charactron (30) is connected with single-chip microcomputer (20), and described DC-DC transducer (50) connects lithium battery (40) and single-chip microcomputer (20).The utility model, to the status monitoring of lithium ion battery, understands the basic status of lithium battery, to realize a series of protections to battery.

Description

A kind of monitoring device of lithium battery

Technical field

The utility model relates to battery boosting technology field, in particular to a kind of monitoring device of lithium battery.

Background technology

The mode difference that charge controller realizes causes its charging effect different.Much adopt the rapid charging of big current in the market, so as stopping not in time making battery hot after battery is full of, excessive overcharging can life-span of grievous injury battery.Also the charge controller of some low costs is had to adopt voltage compare method.In order to prevent overcharging, being generally charged to 90% and just stopping big current filling soon, adopting the boost charge of small area analysis trickle.Usually, in order to make battery charge fully, easily causing and overcharging, battery is often hot (battery after charging phase obvious hot general remark battery overcharges) charging at the end to show as some charge controller.Often occur overcharging to battery and the shortcoming of charge less more and more can not meet the needs of people.The useful life of lithium battery and single cycle service time and charge maintenance process and service condition closely related.A good charge controller not only can be sufficient by electricity at short notice.And certain maintenance effect can also be played to battery, repair the memory effect caused due to improper use, i.e. capacity decline (battery-active decline) phenomenon.Thus traditional common charge controller exists significantly not enough.

Summary of the invention

The technical problem that the utility model solves: the status monitoring how carrying out lithium ion battery, understands the basic status of lithium battery, to realize a series of protections to battery.

The utility model provides following technical scheme: a kind of monitoring device of lithium battery, comprise Li-Battery monitor chip, single-chip microcomputer, charactron, described battery detection chip is connected with lithium battery, and described single-chip microcomputer is connected with battery detection chip, and described charactron is connected with single-chip microcomputer.The monitoring device of described lithium battery also comprises DC-DC transducer, and described DC-DC transducer connects lithium battery and single-chip microcomputer.

By technique scheme, the effect of DC-DC transducer is that single-chip microcomputer is powered by direct current transformation lithium battery, directly adopts 5V DC power supply directly for single-chip microcomputer is powered when designing.

Battery detection chip described in the utility model selects DS2741 chip, and AT89C2051 single-chip microcomputer selected by single-chip microcomputer.

The utility model adopts resistance induction mode in sheet, is made up of DS2741 Li-Battery monitor chip, AT89C2051 single-chip microcomputer and charactron.The monitoring of the main complete battery pair current state of DS2741, comprises the isoparametric monitoring of electric current, temperature and dump energy, and it can also gather these data automatically simultaneously, and places it in memory.Can need to read the relevant parameter of battery and process according to user by AT89C2051 single-chip microcomputer, then be sent to charactron and show.AT89C2051 single-chip microcomputer is the control treatment center of whole device, because a large amount of work all can have been come by single-chip microcomputer, thus significantly reduces hardware complexity of the present utility model.

Charactron can be used to the battery current state information that display user needs to understand, so that user can make corresponding process according to these information.In fact, this charactron only accepts control and the access of single-chip microcomputer.

Further illustrate as of the present utility model, described DS2741 Li-Battery monitor chip comprises two test sides, an I2C interface, power control module, described two test sides comprise the first test side and the second test side, described first test side is connected with charger or load, described second test side is connected with lithium battery, described I2C interface comprises serial date transfer or output and serial clock input, the described end that inputs or outputs is connected with single-chip microcomputer by the first data wire, described serial clock input is connected with single-chip microcomputer by the second data wire, the first resistance is provided with between described first data wire and the first test side, the second resistance is provided with between described second data wire and the first test side, described power control module establishes pin, described pin connecting charger or load, first electric capacity, described first capacity earth.Wherein, described first resistance value and the second resistance value are 10K ohm, and described first capacitance is 0.1u farad.Wherein, when low level effectively, when DS2741 Li-Battery monitor chip is placed on the sleep state of a low-power consumption, it is disabled that all devices comprises I2C bus to described power control module, the low level of first power switched control end, and then homing device and I2C bus.

Further illustrate as of the present utility model, described AT89C2051 single-chip microcomputer comprises XTAL1 and XTAL2 pin, RST pin, described XTAL1 with XTAL2 pin is connected crystal oscillator and the second electric capacity, the 3rd electric capacity, described crystal oscillator frequency is 12M hertz, described second electric capacity and the 3rd capacitance are 30p farad, and described RST pin connects the 4th electric capacity and the 3rd resistance, described 3rd grounding through resistance, described 4th capacitance is 10u farad, and described 3rd resistance value is 1K ohm.

Accompanying drawing explanation

Below in conjunction with accompanying drawing, the utility model is described further:

Fig. 1 is the structural representation of the monitoring device of a kind of lithium battery described in the utility model;

Fig. 2 is the functional block diagram of battery detection chip in Fig. 1;

Fig. 3 is the circuit diagram of the monitoring device of a kind of lithium battery described in the utility model;

Fig. 4 is the read-write flow chart that battery detection chip and single-chip microcomputer carry out the I2C bus of communication.

Symbol description in figure:

10-battery detection chip; 11-power control module; 12-detects resistance; 13-ten plus sign A/D converters; 14-actual registers; 15-accumulator register; 16-temperature register; 17-voltage interface;

20-single-chip microcomputer;

30-charactron;

40-lithium battery;

50-DC-DC transducer;

60-charger or load;

70-crystal oscillator;

R1-resistance; R2-resistance; R3-resistance;

U1-electric capacity; U2-electric capacity; U3-electric capacity; U4-electric capacity.

Embodiment

As shown in Figure 1, a kind of monitoring device of lithium battery, comprises Li-Battery monitor chip 10, single-chip microcomputer 20, charactron 30, DC-DC transducer 50.Described battery detection chip 10 is connected with lithium battery 40, and described single-chip microcomputer 20 is connected with battery detection chip 10, and described charactron 30 is connected with single-chip microcomputer 20, and described DC-DC transducer 50 connects lithium battery 40 and single-chip microcomputer 20.

Selected by the utility model, battery detection chip 10 is DS2741 chip.Selected by the utility model, single-chip microcomputer 20 is AT89C2051 single-chip microcomputer.

As shown in Figure 2, described battery detection chip 10 comprises the first test side RS+ and second test side RS-, 38m Ω detection resistance 12, ten plus sign A/D converters 13, actual registers 14, current accumulator 15, temperature register 16, interface I2C, power control module 11, a voltage interface 17.Meet 38m Ω in described first test side RS+ and the second test side RS-and detect resistance 12.Described power control module 11 establishes pin SLP.

As shown in Figure 1, Figure 3, described first test side RS+ is connected with charger or load 60, described second test side RS-is connected with lithium battery 40, described interface I2C comprises serial date transfer or output SDA and serial clock input SCL, the described end SDA that inputs or outputs is connected with single-chip microcomputer 20 by the first data wire, described serial clock input SCL is connected with single-chip microcomputer 20 by the second data wire, be provided with the first resistance R1 between described first data wire and the first test side RS+, between described second data wire and the first test side RS+, be provided with the second resistance R2.Described pin SLP connecting charger or load 60, first electric capacity U1, described first electric capacity U1 ground connection.Wherein, described first resistance R1 value and the second resistance R2 value are 10K ohm, and described first electric capacity U1 value is 0.1u farad.

As shown in Figure 3, described single-chip microcomputer 20 comprises XTAL1 and XTAL2 pin, RST pin.Described XTAL1 with XTAL2 pin is connected crystal oscillator 70 and the second electric capacity U2, the 3rd electric capacity U3, and described crystal oscillator 70 frequency is 12M hertz, and described second electric capacity U2 and the 3rd electric capacity U3 value are 30p farad.Described RST pin connects the 4th electric capacity U4 and the 3rd resistance R3, and described 3rd resistance R3 ground connection, described 4th electric capacity U4 value is 10U farad, and described 3rd resistance R3 value is 1K ohm.

Battery detection chip 10 and single-chip microcomputer 20 utilize I2C bus to carry out communication, and described I2C bus comprises the first data wire and the second data wire.In order to ensure the reliability that data transmit, the data transmission of I2C bus has strict timing requirements.As shown in Figure 4, the second data wire keeps between high period, and the saltus step from high to low of the first data line level is as the total initial signal of I2C.Second data wire keeps between high period, and the stop signal of I2C bus is made in the saltus step from low to high of the first data line level.When single-chip microcomputer 20 carries out write operation, first send 7 bit address codes of this device and write position, direction " 0 " (8, i.e. a byte), send rear release first data wire and produce the 9th clock signal on the second data wire.Selected storage component part is after being confirmed to be the address of oneself, and the first data wire produces an answer signal as corresponding, single-chip microcomputer 20 just can transmit data after receiving response.When single-chip microcomputer 20 carries out read operation, single-chip microcomputer 20 first send this device 7 bit address codes and write position, direction " 0 (" puppet is write "), send rear release first data wire and on the second data wire line produce the 9th clock signal.Selected storage component part, after being confirmed to be the address of oneself, the first data wire produces an answer signal as corresponding.Then, send out the first address wanting the memory block of read-out device of a byte again, after receiving response, single-chip microcomputer 20 will repeat an initial signal and sends address of devices and read position, direction (" 1 "), just can sense data byte after receiving device response, often read a byte, single-chip microcomputer 20 all will reply answer signal.After last byte number certificate runs through, single-chip microcomputer 20 should return with " non-response " (high level), and sends termination signal to terminate read operation.

The particular content that the utility model is monitored lithium battery is as follows:

1. the reading of battery current and temperature

In an active mode, Li-Battery monitor chip 10 being measured inflow by detecting the 38m Ω pressure drop detected on resistance 12, being flowed out the electric current of lithium battery 40, and data are stored in actual registers 14 with the form of complement code, temperature sensor measurement temperature is also stored in data in temperature register 16.Actual registers 14 and temperature register 16 all can only read.Actual registers 14 is registers of 2 bytes, and its address is 16h and 17h.The address of temperature register 16 is 14h.Therefore, obtain electric current and the temperature parameter of lithium battery 40, single-chip microcomputer 20 is only needed to read actual registers 14 and the temperature register 16 of Li-Battery monitor chip 10 by I2C bus, and treat its sampling after by the measured value of electric current, temperature stored in corresponding register, finally read the content of register again by single-chip microcomputer 20.

2. the monitoring of dump energy

The dump energy of lithium battery 40 is one of important informations required for user, and it can utilize the value in accumulator register 15 to try to achieve.The value of accumulator register 15 obtains by after Li-Battery monitor chip 10 real-time automatic measuring lithium battery 40 electric current, thus need not control it.Usually when lithium battery 40 charges, this value increases, and when lithium battery 40 discharges, this value reduces.Accumulator register 15 be one can according to single-chip microcomputer 20 need change read/write 2 byte REG of data, its address is 10h and 11h.Single-chip microcomputer 20 can read the accumulator register 15 of Li-Battery monitor chip 10 by I2C bus.

Above content is only better embodiment of the present utility model, for those of ordinary skill in the art, according to thought of the present utility model, all will change in specific embodiments and applications, this description should not be construed as restriction of the present utility model.

Claims (4)

1. the monitoring device of a lithium battery, comprise Li-Battery monitor chip (10), single-chip microcomputer (20), charactron (30), described battery detection chip (10) is connected with lithium battery (40), described single-chip microcomputer (20) is connected with battery detection chip (10), described charactron (30) is connected with single-chip microcomputer (20), it is characterized in that: also comprise DC-DC transducer (50), described DC-DC transducer (50) connects lithium battery (40) and single-chip microcomputer (20).

2. the monitoring device of a kind of lithium battery as claimed in claim 1, is characterized in that: described battery detection chip (10) comprises two test side (RS+, RS-), interface (I2C), power control module (11), described two test side (RS+, RS-) the first test side (RS+) and the second test side (RS-) is comprised, described first test side (RS+) is connected with charger or load (60), described second test side (RS-) is connected with lithium battery (40), described interface (I2C) comprises serial date transfer or output (SDA) and serial clock input (SCL), the described end (SDA) that inputs or outputs is connected with single-chip microcomputer (20) by the first data wire, described serial clock input (SCL) is connected with single-chip microcomputer (20) by the second data wire, the first resistance (R1) is provided with between described first data wire and the first test side (RS+), the second resistance (R2) is provided with between described second data wire and the first test side (RS+), described power control module (11) establishes pin (SLP), described pin (SLP) connecting charger or load (60), first electric capacity (U1), described first electric capacity (U1) ground connection.

3. the monitoring device of a kind of lithium battery as claimed in claim 2, is characterized in that: described first resistance value (R1) and the second resistance (R2) value are 10K ohm, and described first electric capacity (U1) value is 0.1u farad.

4. the monitoring device of a kind of lithium battery as claimed in claim 1, it is characterized in that: described single-chip microcomputer (20) comprises XTAL1 and XTAL2 pin, RST pin, described XTAL1 with XTAL2 pin is connected crystal oscillator (70) and the second electric capacity (U2), 3rd electric capacity (U3), described crystal oscillator (70) frequency is 12M hertz, described second electric capacity (U2) and the 3rd electric capacity (U3) value are 30p farad, described RST pin connects the 4th electric capacity (U4) and the 3rd resistance (R3), described 3rd resistance (R3) ground connection, described 4th electric capacity (U4) value is 10U farad, described 3rd resistance (R3) value is 1K ohm.