KR20110116680A - Battery monitoring system - Google Patents

Abstract

The battery monitoring system 1 comprises a detector 11 and a manager 12 connected to the detector 11. A plurality of sensors 113 of the detector 11 are respectively disposed in the battery cells 21 to detect at least corresponding voltage and temperature signals of the battery cells 21 of the battery 2. The signals are then sent to a central processor 112 for individual conversion into accessible and distinguishable data that is applied for comparison with a predetermined threshold. Finally, the compared results are shown on the manager 12 so that users are aware of the physical state for each battery 2. The central processor 112 acts favorably on the compared result in an irregular state and sends a warning signal to the manager 12 to perform the warning operation without delay.

Description

Battery monitoring system {BATTERY MONITORING SYSTEM}

The present invention relates to a monitoring system, and more particularly to a battery monitoring system configured to monitor the normal state of the battery.

Technology development is changing rapidly day by day; To effectively reduce air pollution, people use electricity to drive more and more vehicles or vehicles. Thus, batteries will be a major power source for future transportation. In practice, since the vehicle will not be able to be operated by a single battery, a plurality of batteries connected in parallel or in series to form a battery pack are provided for the vehicle to ensure sufficient energy. As such, it should be noted that careful and rigorous inspection of the battery, such as state of charge, maintenance, and safety, is essential to ascertain the utilization of the battery. However, because the batteries are connected in parallel or in series, existing inspection techniques can only detect the integral state of all battery packs, not the battery units in the battery pack. Therefore, if the battery pack is damaged, technicians must separate the battery units from the battery pack and test the battery units to find out which battery unit has failed. Clearly, such sensing wastes time and makes us uncomfortable.

Accordingly, various existing battery test methods have been developed as follows;

The “battery monitoring system” disclosed in US Pat. No. 4,217,645 employs parameters to automatically monitor multiple batteries, respectively. According to the remote scanner means, a number of sensors provide analog signals corresponding to the variables for performing the monitoring operation. If any parameter of the battery cell is above the threshold, an alarm is triggered. The remote scanner means can only be applied to monitoring and displaying the voltage state of the battery, and this monitoring operation can only act on the surface of the battery. Therefore, when a battery pack is formed by batteries in parallel and series connections, such a general system makes the decision about one failed battery therein obsolete, resulting in many difficulties in maintenance and repair. Moreover, in practical applications, the only basis for voltage sensing will not depend on accurate and complete determination of a single battery.

The “battery monitor for electric vehicle” disclosed in US Pat. No. 5,808,469 refers to a battery monitor for monitoring and determining the voltage and temperature of the battery connected to the battery pack of the electric vehicle. Accordingly, the controller means selectively activates one of the switches capable of selecting a particular battery voltage signal to finally determine the battery voltage of the selected battery, and selects the selected switch after the capacitor is charged by the selected battery voltage signal. Stop it. However, such monitoring only checks the integral battery. The detailed status of each battery cell contained in each battery is still not monitored.

The "Online Battery Maintenance and Monitoring System and Method" disclosed in US Pat. No. 6,031,354, illustrates a system using a central monitoring station and controller that will execute corresponding measurement data and associated warning condition data, to solve existing battery problems. An initial hold command is passed. However, while the disclosure essentially calculates the relevant operating parameters of the battery to confirm that it has delivered an initial hold command, it still does not accurately detect each battery cell in the battery. It should be noted that the disclosed patent only employs external inspection of the integral battery, so that the normal state of each battery cell is still difficult to achieve.

The “battery voltage display device for a wireless communication system” disclosed in US Pat. No. 6,295,002 utilizes the coordination of a wireless two-way communication, power sensing system, and display to perform residual power of the battery. The sense of battery power is transmitted to the main system section within a predetermined time. Thus, if the detection result is not received at the appropriate time and does not exist, an error is sent out to indicate the power consumption state. Clearly, such means can only sense and indicate the residual power of the integrated battery. The detailed usage status of each battery cell in the battery is still inaccessible.

"Automotive tracking device and associated method including battery monitoring characteristics" disclosed in US Patent No. 6,819,269 mainly comprises a wireless communication device and a sensing circuit. When the sensed battery voltage is below the threshold, the operation of the receiver for the wireless communication device becomes impossible. Thus, the use state of the battery cells included in the battery can still not be detected.

The "battery monitor with wireless telecommunication" disclosed in US Pat. No. 7,394,394 uses an alternating current (AC) signal applied to the battery to diagnose whether the battery is normal. At the same time, such monitoring only checks the internal usage of the battery, but not the battery cells therein. Therefore, the normal state of each battery cell also cannot be monitored.

As a result, the aforementioned prior arts only disclose that they include a monitoring device for externally sensing the voltage or current state of the internal battery or battery pack. However, the prior arts are usually inconvenient to check the detailed normal condition of each battery cell in the battery. In addition, a single signal does not provide information that can indicate all normal conditions of the battery. Moreover, when the batteries are connected in series and in parallel, the replacement or repair is difficult due to the fact that the batteries included in the battery pack must be tested and replaced one by one. Therefore, monitoring cannot be performed accurately without delay. This makes it impossible to quickly indicate abnormal problems resulting from damaged batteries. As a result, there is a need for a solution to the aforementioned disadvantages.

SUMMARY OF THE INVENTION An object of the present invention is to provide a battery monitoring system which allows for quick and accurate inspection of the normal state of battery cells in a battery, which is easy to replace later.

The battery monitoring system according to the invention basically comprises a detector and a manager connected to the detector. Multiple sensors of the detector are each disposed in the battery cells of the battery, and voltage and temperature signals of the battery cells are correspondingly sensed. Since the signals are integrated by the integrator of the detector, the central processor converts the signals into accessible and distinguishable data, which makes them more comparable. Next, the results compared with the data are displayed in the manager, so that users can recognize the normal state of each battery cell.

Thus, the continuous replacement of the battery becomes faster and more convenient, which positively increases the convenience of use.

1 is a schematic view showing a first preferred embodiment of the present invention.
2 is a schematic view showing a first preferred embodiment in the inspection step.
3 is a flowchart showing a sensing model of the first preferred embodiment according to the present invention.
4 is a schematic view showing a second preferred embodiment of the present invention.
5 is a schematic view showing a third preferred embodiment of the present invention.
Fig. 6 is a flowchart showing a sensing model of the third preferred embodiment according to the present invention.
7 is a schematic view showing a fourth preferred embodiment of the present invention.
8 is a schematic view showing a fifth preferred embodiment of the present invention.

Advantages of the invention overcoming known prior art will become more apparent to those skilled in the art by the following description in conjunction with the accompanying drawings.

Before describing in more detail, it should be noted that like elements are represented by the same reference numerals throughout the disclosure.

1 and 2, the first preferred embodiment of the present invention shows a battery monitoring system 1 for checking the normal state of a plurality of battery cells 21 while the battery 2 is in use. The battery monitoring system 1 comprises a detector 11 and a supervisor 12. The detector 11 includes an integrator 111 and a central processor 112 as well as a plurality of sensors 113 respectively connected to the integrator 111. Here, the sensors 113 are disposed in the respective battery cells 21 to sense the temperature and voltage generated by the battery cells 21, respectively. According to the present embodiment, the sensor 113 for sensing the temperature of the battery cell 21 while the sensor 113 for sensing the voltage of the battery cell 21 is connectable to the battery cell 21. ) May or may not be connected to the battery cell 21. The sensors 113 are connected to the integrator 111, whereby the integrator 111 can integrate the voltage signal and the temperature signal received from the battery cell 21, and then transmit the signals to the central processor. Can be sent to 112.

Subsequent to the foregoing, the central processor 112 includes a converter 1121 and a central processing unit (CPU) 1122 coupled to the converter 1121. The converter 1121 receives a voltage signal and a temperature signal of the battery cell 21 integrated by the integrator 111 and converts each of the signals into separate voltage data and temperature data. In addition, the CPU 1122 stores a predetermined value therein and makes a decision by comparing the voltage data and temperature data with a predetermined value, so that the compared result is achieved.

The manager 12 includes a controller 121 for receiving a comparison result from the CPU 1122 and a display 122 connected to the controller 121. The controller 121 receives the comparison result from the CPU 1122 via the transmission / reception unit 1211. Here, the transmission and reception unit 1211 is connected to each other to the CPU 1122 by wireless or wired. According to this embodiment, the CPU 1122 connected to the transmission and reception unit 1211 by wire to each other has been exemplarily adopted. In addition, the transmission / reception unit 1211 is connected to a processing unit 1212 which is further connected to the display 122. Accordingly, since the CPU 1122 determines the comparison result and performs any abnormal state, a warning signal is emitted from the manager 12 and displayed on the display 122 via the controller 121. . The warning signal may employ a widely blinking warning light, buzzer or the like to alert the user. In order to accurately represent the normal state inside the battery 2, the display 122 adopts a screen as an example of this embodiment.

1 to 3, the battery monitoring system 1 is applicable to a vehicle, and the manager 12 and the detector 11 are connected by wire. That is, a screen (not shown) of the means of transportation is provided to the display 122 connected to the battery 2 in a wired manner through a control circuit (not shown), which is equivalent to the controller 121. In use, the means of transportation is driven by a battery 2 which provides electricity. At the same time, the sensors 113 operate to freely detect the normal state of each battery cell 21 in the battery 2 to obtain respective temperature and voltage signals, and transmit the signals to the integrator 111. send. Due to this, after the integrator 111 integrates the sensed temperature and voltage signals, the signals are further transmitted to the converter 1121 of the central processor 112. As such, the signals are converted into communication data, respectively, so that the CPU 1122 performs a consistent analysis and compares it with a predetermined value to determine the compared result. In this way, the result of the comparison is transmitted to the controller 121. Accordingly, the transceiver 1211 receives the compared result and then compares the result with the processing unit 1212 to operate the display 122 which may indicate the usage state of each battery cell 21. send. Thus, if the compared result is abnormal, the CPU 1212 immediately sends out a warning signal to activate the display 122 where the processing unit 1212 emits a flashing light or a buzzer. Therefore, users can recognize the normal state of the battery cell 21 at the time of use, and directly change the abnormal battery 2, thereby increasing the convenience of use.

In addition, while the replaced battery 2 is being regenerated, when only a part of the broken battery cells 21 in the battery 2 generate insufficient current and voltage of the battery 2, the recycler is in a damaged state. The designated battery cell 21 can only be replaced. In general, a typical way to solve the above problem is to discard all the batteries 2, but this is a waste. In the characteristic configuration invented by the present invention, replacement of the battery cell 21 results in long lasting service life and repetitive use of the battery 2, which is consistent with today's environmental protection concept. .

Referring to Fig. 4, the second preferred embodiment of the present invention includes components consistent with the first preferred embodiment. The sensor 113 is additionally installed to communicate with each of the battery cells 21 so as to sense a current signal generated from the battery cells 21. Accordingly, in addition to sensing and integrating the voltage signal and the temperature signal, the sensed current signal may be sent directly to the central processor 112 via the sensor 113. Thus, the signals can be implemented through transformation, division, and analysis. Therefore, according to the present embodiment, the sensors 113 provide a comprehensive solution for determining the normal state of the battery cell 21, so that the criteria for determining the damage state of the battery 2 are accurate.

5 and 6, the third preferred embodiment of the present invention has the same elements as the first embodiment. However, in this embodiment, the manager 12 and the detector 11 are wirelessly connected; That is, the manager 12 is adopted manually. The manager 12 still has a controller 121 connected to the CPU 1122 and a display 122 connected to the controller 121. In use, the integrator 111 integrates the sensed temperature and voltage signals transmitted from the sensor 113 and then transmits the same signals to the converter 1121 to convert the signals into invariant data. As such, the CPU 1122 will distinguish, compare, and analyze the data to determine the compared results. As a result, the compared result is wirelessly transmitted to the transmission / reception unit 1211 of the controller 121. Thus, the display 122 shows unchanged information about the results compared through the processing unit 1212. If the comparison result is abnormal, the CPU 1212 immediately sends out a warning signal to activate the display 122 where the processing unit 1212 emits a flashing light or a buzzer. Thus, the users recognize the normal state of the battery cell 21 through the controller 121. In addition, replacement of a damaged battery can be effective. This increases the convenience in terms of maintenance or application of external monitoring.

Referring to Fig. 7, a fourth preferred embodiment of the present invention represents a combination of preferred first to third embodiments. The connection between the detector 11 and the manager 12 is wired and wireless. On the other hand, when the detector 11 is installed in a vehicle (not shown), the state of use of the battery 2 may be directly displayed on the display 122 of the vehicle through a wired method. Therefore, users can easily understand the voltage, temperature, and current information of the battery cell 21 in use. As a result, when any battery cell 21 is abnormal, the warning signal is activated and displayed on the display 122. With regard to the wireless manual manager 12 ', it is suitable for inspection and maintenance. According to this method, the displayer 122 representing the judgment, comparison, and analysis of the data is not the only way to explain; In addition, the users can directly obtain all the information on the display 122 'of the manager 12' and determine whether to replace the damaged battery 2 or the battery cell 21. Clearly, the ease of use is greatly improved.

Referring to FIG. 8, the fifth preferred embodiment of the present invention shows that the battery pack A is formed by a number of batteries 2 monitored by the battery monitoring system 1. Since the batteries 2 are connected in series or in parallel with each other, the battery pack A provides sufficient electricity. Here, the description to be described later is in the fourth embodiment as an example. As the number of batteries 2 increases, the detector 11 detects whether the battery cells 21 of each battery 2 are damaged and then preferably provides consistent information on the manager 12. Can be. Therefore, users can quickly obtain information on the normal state of the batteries 2. The damaged battery 2 or battery cells 21 can then be inspected without delay and a replacement can be selected.

The battery monitoring system 1 then uses the sensors 113 to individually carry out an omnibus test of the battery cells 21 of the battery 2. Therefore, the respective sensors 113 installed in each battery cell 21 help complete and accurate sensing. And users can fully know the changes in the battery during use. Therefore, only the abnormal battery cell 21 can select later maintenance and replacement without delay. And if only one of the battery cells 21 is damaged, it is not necessary to change all the batteries 2 or the battery packs A. Such measures positively reduce costs and reduce environmental pollution. Therefore, the present invention achieves the purpose of effectively monitoring and applying the normal state of the battery 2 as well as increasing convenience in installation.

In summary, the present invention utilizes sensors installed on each corresponding battery cell to perform a comprehensive check on the normal state of each battery cell in the battery. Thus, users can freely understand the physical state of each battery. Therefore, the operation and subsequent replacement become faster and more convenient.

While we show and describe embodiments according to the present invention, it will be apparent to those skilled in the art that additional embodiments may be made without departing from the scope of the present invention.

1: monitoring system 2: battery
11: detector 12,12 ': manager
111: integrator 112: central processor
113: sensor 121121 ': controller
122,122 ': Displayer 1121: Converter
1122: CPU 1211: transceiver unit
1212: Processing Unit

Claims (8)

In the battery monitoring system 1 for monitoring the normal state of the battery 2,
The battery (2) is formed by a plurality of battery cells (21) monitored by the monitoring system (1); The monitoring system 1 comprises a detector 11 and a manager 12 connected to the detector 11,
The detector (11) disposed in the battery (2) has an integrator (111) and a central processor (112) as well as a plurality of sensors (113) respectively connected to the integrator (111); The sensors (113) are disposed corresponding to the respective battery cells (21) for respectively sensing a voltage signal and a temperature signal; The integrator (111) integrates and transmits voltage and temperature signals to the central processor (112); The central processor 112 includes a converter 1121 and a CPU 1122 coupled to the converter 1121, so that the converter 1122 converts the signals into separate voltage and temperature data to the integrator 111. Receive the voltage and temperature signals transmitted from; The CPU 1122 stores a predetermined value for comparing the voltage and temperature data; The manager is coupled to the CPU 1122 to display the compared result from the CPU 1122 comparing the voltage data and the temperature data with the predetermined value, and the CPU 1122 is connected to the compared result. A battery monitoring system, which acts favorably on an irregular state of and sends a warning signal to the manager (12) to perform the warning without delay.
The method of claim 1,
In order to further detect the current signal of the battery cell 21, a sensor 113 is installed correspondingly on each of the battery cells 21, and the current signal detected by the sensor 113 is converted, Battery monitoring system, characterized in that the comparison is directly sent to the central processor (112) to be distinguished.
The method of claim 1,
The manager 12 is a controller 121 for receiving signals from the CPU 1122, and
Battery display system characterized in that it comprises a display (122) connected to the controller (121).
The method of claim 3,
The controller 121 is a transmission and reception unit 1211 for receiving signals from the CPU 1122, and
And a processing unit (1212) coupled to the transmit / receive unit (1211).
The method of claim 3,
The display (122) is a battery monitoring system, characterized in that to adopt a flashing light to indicate an abnormal state.
The method of claim 1,
A plurality of batteries (2) form a battery pack, wherein the batteries (2) are connected to each other.
The method of claim 2,
A plurality of batteries (2) form a battery pack, wherein the batteries (2) are connected to each other.
The method of claim 3,
A plurality of batteries (2) form a battery pack, wherein the batteries (2) are connected to each other.

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