KR20200046619A - Battery management device that does not require external power source with battery terminal fixing structure - Google Patents

Abstract

The present invention relates to a battery management device having a battery terminal fixing structure without requiring an external power source, to provide a technique for safely and easily managing a battery. According to the present invention, the present invention provides effects of providing a battery management device not requiring a separate power source to increase convenience in battery state measurement, not requiring a cable for connecting a plurality of batteries to reduce measurement preparation time for a checkup and prevent a problem occurring when an inspector touches the cable, using optical communications not to generate a voltage level difference to facilitate configuration of a communication circuit even if being a battery management device using battery power, and providing the battery management device integrated with a battery to facilitate battery management. According to the present invention, the battery management device comprises a master module and N slave modules.

Description

Battery management device that does not require external power source with battery terminal fixing structure

The present invention relates to a battery management device that does not require an external power supply of the battery terminal fixing structure.

The battery management system (BMS) detects the voltage, current and temperature of the battery in real time and controls the charging and discharging current to prevent overcharging and overdischarging of the battery, and calculates the remaining capacity and remaining life of the battery during charging and discharging To inform the control unit. The information transmitted to the control unit serves to control the operation of the switch, and if necessary, transmits the information to the monitoring system when overvoltage, overcurrent, undervoltage and abnormal temperature are stored using the stored information.

In general, a plurality of batteries are always provided for reserve power required for an environment in which a plurality of batteries are provided, for example, a wireless communication base station, and these batteries are periodically checked. They are electrically connected. In order to check the status of the plurality of batteries, a process of connecting and inspecting a battery management device is performed for each battery.

  For example, a system as shown in FIG. 1 may be disclosed. A typical battery management system has a plurality of batteries 210 and a plurality of battery management devices 230 connected thereto, a power supply 200 that supplies power to these battery management devices, and a cable 240 that connects between the battery management devices , It consists of an external device 250 connected to the battery management system by wired or wireless.

With respect to the battery management apparatus used in such a battery management system, in the prior art publication 10-2012-0073520, each state of the battery is measured and stored, and this information is delivered to the consumer, or the battery maintenance company monitors this information A technology capable of transmitting by wireless communication has been disclosed.

However, although the aspect of managing the collected data using the wireless communication of the battery management device has been improved, there is a possibility that a cable connecting multiple batteries is disconnected during the battery management process, thereby preventing the threat to devices and inspectors. Therefore, it was necessary to provide safety and convenience and make the management process easier.

The present invention provides a technology capable of more safely and easily managing the battery with the invention devised to solve the above-described problems.

A first aspect of the battery management apparatus according to the present invention is a master module installed in a battery and receiving power; And N slave modules installed in a battery and receiving power and collecting battery information while being connected to the master module, wherein the master module comprises: a first measuring unit for measuring battery information; A first connection unit for optical communication with the slave module; a wireless communication unit for transmitting status information measured by the measurement unit to an external device; And a first housing in which the configuration is installed and coupled with a battery; and the slave module comprises: a second measurement unit for measuring battery information; a second connection unit for optical communication with each slave module or master module; And a second housing in which the above configuration is installed and combined with a battery.

The second form of the battery management apparatus according to the present invention further includes a battery in the above-described first form, and the battery is characterized in that an accommodating groove in which the master module or the slave module is installed is provided.

The master module of the battery management apparatus according to the present invention may further include a display unit for notifying completion of reception when all of the management numbers transmitted by the N slave modules are received.

The first housing and the second housing of the battery management apparatus according to the present invention may be characterized in that it comprises a coupling means provided to be detachable from the battery.

The communication unit of the battery management apparatus according to the present invention may transmit abnormal state information of the slave module to an external device.

The battery management apparatus according to the present invention has the following effects.

First, since a battery management device that does not require a separate power source can be disclosed, the convenience of measuring the battery state is improved.

Second, since there is no need for cables to connect multiple batteries, the preparation time for measurement during inspection is reduced, and problems caused by the inspector touching the cables can be prevented.

Third, since the voltage level difference does not occur due to the use of optical communication, the communication circuit can be easily constructed even though it is a battery management device that uses battery power.

Fourth, the battery management device provided integrally with the battery may be disclosed, thereby facilitating battery management.

1 is a schematic diagram of a conventional battery management apparatus.
Figure 2 is a schematic diagram showing the operation of the battery management apparatus according to the present invention.
3 is a schematic view showing the connection of the battery management apparatus according to the present invention with an external device.
Figure 4 is an enlarged view showing a coupling means of the battery management apparatus according to the present invention.
5 is a schematic diagram of a battery management apparatus including a battery according to the present invention.
6 is a block diagram of a battery management apparatus according to the present invention.

The preferred embodiments of the present invention will be described in more detail, but

Technical parts that are missing will be omitted or compressed for the sake of brevity.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

<Structure of battery management device>

As shown in FIG. 6, the first form of the battery management device that does not require an external power supply having a battery terminal fixing structure according to the present invention includes a master module 110 and a slave module 120.

  The master module 110 is installed in a battery to receive power and collects battery information.

The master module 110 measures battery information and is connected to the slave module 120, which will be described later, through optical communication, and transmits the slave module and self-measured battery status information by communicating with an external device. Here, the external device may be an information processing device having communication means such as a computer, a laptop, a smart phone, and a PDA.

The master module 110 includes a first measurement unit 111, a first connection unit 112, a wireless communication unit 113 and a first housing 114, and a first micro controller unit (MCU) 115.

The first measurement unit 111 measures battery state information. Here, the battery state information may be voltage, current, temperature, and charge / discharge capacity of the battery as an example. The measured battery state information is transmitted to the first micro controller unit (MCU) 115.

The first connection unit 112 is provided to enable optical communication with the slave modules 120. The first connection unit 112 converts the battery status information request command of the first MCU 115 into an optical signal, transmits it to the receiving unit of the second connection unit 122 of the slave module 120, and conversely measures the slave module 120 When the electrical signal in which the battery state information is stored is converted and transmitted from the second connection unit 122 to an optical signal, it is received by the first connection unit 112 and transmitted to the first MCU 115. The first connection portion 112 protrudes to the outside of the first housing 114, which will be described later, so that the optical signal can be easily transmitted and received. Here, the optical communication may mean, for example, IR (Infrared) communication or LI-FI (Light-Fidelity).

Referring to FIG. 3, the communication unit 113 is provided only in the master module 110 and the first measurement unit 111 of the master module 110 and slave modules 120 connected to the master module 110 are described below. 2 The battery state information measured by the measurement unit 211 may be collected through the first MCU and transmitted to an external device. It is preferable that short-range communication such as Bluetooth communication is used for terminals such as a short-term checker, and long-distance communication such as IoT is used for remote servers.

The first housing 114 is provided with the first measurement unit 111, the first connection unit 112, and the communication unit 113 described above, and serves to protect it and is combined with a battery.

The first housing 114 may have detachable coupling means when combined with a battery. When checking the battery, the battery and the master module 110 are combined, and when the inspection is over, it is possible to easily disengage the connection again. The combining means also serves as a power supply means for supplying power from the combined battery to the battery management device. The portion on the battery to which the coupling means is coupled may be variable, but a connection means such as a bus bar, which is electrically connected between at least one battery, is preferable.

Referring to FIG. 4, for example, when there is a battery connection member in the form of a bar connecting a plurality of batteries, the battery connection member can be coupled to and released from the attachment means in the form of detachable forceps.

At least one slave module 120 is provided and installed on a battery to receive power, and collects battery information while being connected to the master module through optical communication.

The slave module 120 is dependent on the above-described master module 110, but except for the communication unit 113, the configuration and role are similar and provided in at least one or more. Each slave module 120 includes a second measurement unit 121, a second connection unit 122 and a second housing 123, a second MCU (124).

The second measurement unit 121 measures battery state information in the same way as the first measurement unit 111 described above. Here, the battery state information may be voltage, current, temperature, and charge / discharge capacity of the battery as an example. The measured battery status information is transmitted to the second MCU.

The second connection unit 122 is provided to enable optical communication with the master module 110 or other slave modules 120. Here, the optical communication may mean, for example, IR (Infrared) communication or LI-FI (Light-Fidelity). The second connection unit 122 receives the battery status information transferred to the second MCU 124, converts it into an optical signal, transmits it to the receiving unit of the second connection unit 122 of the other slave module 120, and vice versa. When the electrical signal stored in the battery state information measured in) is converted into an optical signal and transmitted, the second connection unit 112 transmits the second signal to the second MCU 124. Such a second connection unit 122 Is projected to the outside of the second housing 113, which will be described later, so that the optical signal can be easily transmitted and received.

Since the second housing 123 has a similar configuration and role to the first housing 114 described above, a detailed description thereof will be omitted.

As shown in FIG. 5, the second form of the battery management device according to the present invention may be in the form of a battery and a battery management device integrally provided with the battery. That is, the battery management device is provided with a battery coupled to facilitate battery management.

For this, the battery is preferably provided in a form having a receiving groove that can accommodate the battery management device. When the above-described battery management device is accommodated in the receiving groove provided in the battery, the battery management device does not need to be detached when managing the battery, so it can be managed more safely and conveniently, thereby improving the ease of battery management.

<How to operate the battery management device and how to collect battery status information>

2, the battery management apparatus according to the present invention includes a master module 110 and at least one slave module 120. The battery management device may be temporarily coupled to the battery (first form) or integrally coupled to the battery (second form) when checking the battery. Describes the steps in which the battery check begins. First, the numbering of the master module 110 and the slave modules 120 starts. The numbering is a step in which the number of the batteries combined by the master module 110 and the slave modules 120 coupled to the batteries connected to the batteries is determined. The master module 110 transmits the battery ID (identification number) to the next slave module 120 as 1, and the slave module receiving its ID is another slave module 120 coupled to the next battery connected to its battery. Passes 2 with 1 added to its ID. The slave module 120 whose ID is 2 is again transmitted to the next slave module 120 connected to itself, and when this process is repeated and connected to the last connected slave module 120, the ID of the slave module is sent back to itself. It transfers its ID back to the previous slave module 120 that has been transferred. Finally, the numbering process is performed until the ID transmission process of the master module 110 is performed again, and when the ID of the slave module 120 next to the master module 110 is transmitted, the numbering process is terminated. In the above-described numbering process, the method of transmitting the ID is performed by the first communication unit 112 of the master module 110 and the second communication unit 122 of each slave module 120 as described above.

As described above, when the numbering step ends, the operation of the battery management device starts immediately. At this time, preferably, the operation of the first connection unit 113 and the second connection unit 122 is performed on the first housing 114 of the master module 110 of the battery management device and the second housing 123 of each slave module 120. The display unit for displaying the status can inform the transmission / reception status of each ID information. The display unit may display an abnormal state of the slave module, which will be described later.

The battery checking step described with reference to FIG. 2 is as follows. For every predetermined period, the master module 110 may transmit a command for requesting battery status information to each slave module 120 sequentially from the slave module 120 connected to the first connection unit 110 as a starting point. The slave module 120 receiving the command measures the state information of the battery installed therein and transmits it through the second connection unit 120 to the previous slave module 120 that has transmitted the command to itself along with its ID. . The slave module 120 receiving its ID and the measured battery status information from the slave module 120 requesting battery status information is the second connection unit of the slave modules 120 connected in series to finally deliver it to the master module ( 122). The above-described battery status information request command can be made to the entire slave module 120 and only to the specific slave module 120. The battery status information request command of the master module transmits only the slave module 120 that is the farthest to the master module among the slave modules 120 of the specified target, and the slave module 120 that received the command transmits the battery status information to the previous slave module 120 Transfer to the final master module 110 is preferably in progress. If there is a slave module 120 that has been requested additional battery status information during the above-described transfer process, the process of transferring its battery status information to the master module 120 while the corresponding slave module 120 transmits another battery status level Proceeds.

It will be explained with an example. As shown in Figure 2, when there are a total of N, including one master module 110 and a slave module 120, each of the modules may be installed in N batteries connected in series, respectively # 1, # 2, Assume # 3 ... # N. In the numbering phase before the battery check starts, the battery ID is designated as 1 from the master module, and the battery ID 1 is transmitted to the slave module # 2 through the first connection via optical communication. Slave module # 2 transfers battery ID 2 plus 1 to battery ID 1 to slave module # 3 through the second connection, and when the slave module that receives it reaches the final slave module #N through the previous process again, slave module # N passes its ID to the previous slave module. When the ID information of the slave module # 1 reaches the master module through successive transfer processes, the numbering step ends and the operation of the battery management device starts.

  Thereafter, the command for requesting battery status information from the master module 110 is transmitted to the final slave module, and the final slave module transfers the battery status information to the master module in a subsequent linking process as described above. If there is a slave module that requested battery status information during the transfer process, the battery status information of the corresponding slave module is also included and transmitted.

Even if there is a command for requesting battery status information of the above-described master module 110, if the commanded slave module 120 does not respond or there is an abnormal state of the slave module in which delivery is interrupted in the course of successive command delivery, the master module 110 ) May transmit the above specifics to an external device through the communication unit 113.

The battery management device does not require an inconvenient process such as connecting power from outside the base station by receiving power from the battery to be managed, without requiring a device to supply power for a separate battery management device in battery management. It is convenient to prepare and does not require a separate cable for connection with such a battery, and can be easily detached from the battery through a coupling means provided in the housing, thus touching a short-circuit accident or installed cable that may occur due to incomplete installation. Accidents, etc. are prevented. In addition, since the communication between the battery management devices uses optical communication instead of a wired cable, the structure is simplified.

In addition, by using such optical communication, there is no problem that may occur due to different voltage levels, such as a voltage rise that occurred when using a communication cable for connection between battery management devices, so an additional isolation process of a communication circuit is unnecessary. Is done.

As described above, although the detailed description of the present invention has been made by examples, it is understood that the present invention is limited only to the above-described embodiments, since the above-described embodiments are merely described as preferred examples of the present invention. It should be understood that the scope of the present invention is to be understood by the following claims and equivalent concepts.

100: battery unit
101: acceptance home
110: master module
111: first measurement unit
112: first connection
113: communication department
114: first housing
114a: combining means
115: 1MCU
120: slave module
121: second measurement unit
122: second connection
123: second housing
123a: combining means
124: 2MCU
130 external device
140: display device
200: power supply
210: battery
230: battery management device
240: cable
250: external device

Claims (5)

A master module installed on a battery to receive power and collect battery status information; And
Includes; installed in the battery and receiving power, and connected to the master module through optical communication, the N slave modules for collecting battery status information;
The master module,
A first measurement unit for measuring battery information;
A first connection unit in optical communication with the slave module;
A wireless communication unit that transmits battery status information measured by the measurement unit to an external device; And
The configuration is installed and the first housing coupled to the battery; includes,
The slave module,
A second measurement unit for measuring battery state information;
A second connection unit in optical communication with each slave module or master module; And
It characterized in that it comprises a; the second housing is installed and the configuration is installed and coupled to the battery
Battery management device. According to claim 1,
Further comprising a battery unit including N battery cells,
Each of the N battery cells of the battery unit
The master module or the slave module is provided with a receiving groove that can be installed, characterized in that
Battery management device. The method according to claim 1 or 2,
The first housing and the second housing
Further comprising; a display unit for displaying whether the operation of the first connection unit and the second connection unit
Battery management device. The method according to claim 1 or 2,
The first housing and the second housing,
Characterized in that it comprises a coupling means provided to be detachable with the battery
Battery management device. The method according to claim 1 or 2,
The communication unit
Transmitting the abnormal status information of the slave module to an external device
Battery management device.

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