KR20230148868A - METHOD FOR BATTERY MONITORING AND CONTROLLING OF LiFePo4 BATTERY EMBEDDING POWER SUPPLY FOR 5G L2 SWITCH - Google Patents

Abstract

The present invention relates to a battery monitoring and control method for a power device with a built-in lithium iron phosphate battery for a 5G L2 switch. Designing a dedicated battery management system so that the 5G L2 switch operates normally even in a power outage, and providing a battery management system to the battery pack through the battery management system. If an alarm occurs about an abnormal state of the battery pack, including charging overvoltage, discharge undervoltage, charging current abnormality, discharging current abnormality, battery cell deviation abnormality, temperature abnormality, charging state abnormality upon completion of charging, or a combination of these, the corresponding alarm occurs. This relates to a battery monitoring and control method that stores information in the system log (syslog) and provides the corresponding blocking information to a network management system when the battery pack is turned off (faulted).

Description

Battery monitoring and control method of power device with built-in lithium iron phosphate battery for 5G L2 switch {METHOD FOR BATTERY MONITORING AND CONTROLLING OF LiFePo4 BATTERY EMBEDDING POWER SUPPLY FOR 5G L2 SWITCH}

The present invention relates to a battery monitoring and control method of a power device with a built-in lithium iron phosphate battery for a 5G L2 switch. More specifically, a dedicated battery management system is designed to ensure that a 5G class L2 switch operates normally even in a power outage, and the battery management system Alerts on abnormal conditions of the battery pack, including charging overvoltage, discharging undervoltage, charging current abnormality, discharging current abnormality, battery cell deviation abnormality, temperature abnormality, charging state abnormality upon completion of charging, or a combination thereof. This relates to a battery monitoring and control method that stores the corresponding alarm information in the system log (syslog) when an alarm occurs and provides the corresponding blocking information to the network management system when the power to the battery pack is turned off (fault).

An Ethernet switch refers to a network switch device that controls information flow between nodes, including subscribers and objects, to be selectively transmitted when providing Ethernet services.

These Ethernet switches are widely used in home networks, factory automation, autonomous vehicles, and multimedia transmission and reception.

In particular, recently, as communication technology to provide gigabit (Gbps) Ethernet services such as 5G has developed, 5G L2 switches that provide gigabit speeds have been developed and used.

In the case of Ethernet switches, there is a problem that if the switch goes down due to lack of power, such as a power outage, the Ethernet service may not be available, which may cause damage to the Ethernet service provider or subscriber.

In order to solve this problem, the present invention includes a battery pack composed of a plurality of battery cells, and controls the operation between the SMPS (switched mode power supply) and the battery pack when power is normally supplied from a commercial power supply or a power outage occurs. We would like to propose a method to enable continuous processing of high volumes of data.

On the other hand, when a battery pack is built-in, if the battery cell or battery pack is in poor condition or malfunctions, the Ethernet switch may be affected and problems may arise that require replacement of the Ethernet switch itself, so there is a need to monitor the status of the battery pack.

Therefore, the present invention relates to abnormal conditions of a battery pack including charging overvoltage, discharging undervoltage, charging current abnormality, discharging current abnormality, deviation abnormality between battery cells, temperature abnormality, charging state abnormality upon completion of charging, or a combination thereof. Design a battery management system to monitor, store in the system log (syslog) when an alarm for the abnormal condition occurs through the battery management system, and network through SNMP (simple network management protocol) when a fault occurs. We would like to propose a method to provide information about disconnection through a management system so that the battery pack can be inspected or the power supply unit replaced in a timely manner.

In particular, the present invention provides a method of monitoring an abnormal state of a battery pack according to battery management standards according to the operation mode of the battery pack, including charging mode, discharging mode, and sleep mode, and disarming the alarm upon recovery and providing notification of the normal state. We propose a way to do this.

Next, we will briefly describe the prior art existing in the technical field of the present invention, and then describe the technical details that the present invention seeks to achieve differently compared to the prior art.

First, Korean Patent No. 0750371 (2007.08.10) is intended to maintain normal mode operation with battery power even in the event of a power failure of the optical network security system so that the optical switch is in the cross state. It is an external type located in front of optical network security equipment such as IPS that operates in in-line mode. It checks whether the internal rechargeable battery and main power are input and supplies battery power when the power is turned off. It is equipped with a power detection and switch circuit to control the optical switch with battery power when the power is turned off, allowing the optical switch to operate as desired even when the power is off, allowing network traffic to pass through the optical network security equipment. This provides the effect of protecting the entire network and operating it effectively.

In other words, Korean Patent No. 0750371 does not relate to an Ethernet switch with a built-in battery pack, but rather has an external battery.

On the other hand, the present invention relates to an Ethernet switch with a built-in battery pack to sustain high-capacity data processing. It monitors abnormal conditions for the battery pack according to the battery pack management standards, stores it in the system log when an alarm occurs, and stores it in the system log when an alarm occurs. The network management system provides information about blocking so that the status of the battery pack can be managed in two stages.

In the end, Korean Patent No. 0750371 does not describe or suggest any technical features of the present invention at all, so there is a significant difference between the present invention and its purpose, effect, and technical configuration.

In addition, Korean Patent No. 1340660 (2013.12.05) relates to an improved wireless hotspot device including a main body containing a circuit board connected to a battery, wherein the circuit board is a first control unit connected to a second control unit. unit, the second control unit is connected to a wireless transmission unit, the first control unit is for controlling the input voltage of the external power source and the output voltage of the battery power source, and is configured to operate the second control unit. Notifying, the second control unit executes the router mode or network service mode by performing wireless access via the wireless communication unit or access via an Ethernet network. As a result, you can access data at any time via a local or wireless network, as well as supply power to other electronic products.

In other words, Korean Patent No. 1340660 simply controls the output voltage of external power and battery power, and does not relate to an Ethernet switch with a built-in battery pack as proposed in the present invention. It is a battery pack according to the management standards of the battery pack. There is also no information on how to monitor abnormal conditions in the pack.

Therefore, there are clear differences in purpose, effect, and technical composition between the present invention and Korean Patent No. 1340660.

In addition, the prior technologies mentioned above do not have a battery pack built into the Ethernet switch, and do not have a function to monitor abnormal conditions of the battery pack according to the battery pack management standards and save them as a system log or transmit them to a network management system. Therefore, there is no written information on how to inspect or replace the battery pack or power supply in a timely manner.

The present invention was created to solve the above problems, and is a battery monitoring control of a power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch that allows the 5G L2 switch to operate normally for a certain period of time with battery pack power even when a sudden power outage occurs. The purpose is to provide a method.

In addition, the present invention provides a battery pack that includes charging overvoltage, charging current abnormality, discharging low voltage, discharging current abnormality, battery cell deviation abnormality, temperature abnormality, charging state abnormality upon completion of charging, or a combination thereof according to the management standards of the battery pack. The purpose is to provide a method of providing a battery management system that monitors abnormal conditions and manages the status of the battery pack.

In addition, the purpose of the present invention is to use a battery management system to control the 5G L2 switch to operate normally and continuously without interruption even under normal power supply and power outages.

In addition, the purpose of the present invention is to provide a method for storing and managing notification information about abnormal states of the battery pack in memory in accordance with battery management standards for each battery operation mode including charging mode, discharging mode, and sleep mode. do.

In addition, the present invention monitors notification information in real time, and when a warning occurs in the notification information, the notification information is stored in the system log (syslog) as alarm information, so that the history of the status of the battery pack can be checked. The purpose is to provide a method and device.

In addition, the present invention provides a network management system with the notification information as blocking information when a fault occurs in the notification information, and displays a command to check the status of the battery pack or replace the power supply on the Ethernet switch through a display or LED. The purpose is to provide a method.

In addition, the present invention stores an alarm release message in the system log (syslog) when a cutoff occurs due to an abnormal condition (defect) of a battery cell or battery pack or when recovery from an abnormal charging condition occurs upon completion of charging, and at the same time provides it to a network management system. It is for that purpose.

In addition, in order to configure a battery management system, the present invention defines battery pack parameters including battery pack capacity, discharge cutoff voltage, current, internal resistance, cycle characteristics, etc., so that the state of the battery pack can be managed. The purpose is to provide a method for doing so.

The battery monitoring and control device of the power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch according to an embodiment of the present invention includes a battery management system for the built-in battery pack of the 5G L2 switch and the battery pack using the battery management system. It includes a battery monitoring control unit that monitors and controls the operation of the battery pack so that the switch operates normally and without interruption even under normal power supply and power outages.

In addition, when managing the battery pack through the battery management system, the battery monitoring control unit sets the battery pack in a charging mode, a discharging mode, or a sleep mode according to one of the charging mode, discharging mode, and sleep mode of the battery pack. It is characterized in that it includes controlling the supply of power to the switch by monitoring any one of them.

In addition, the battery management system has battery pack management standards corresponding to the charging mode, discharging mode, and sleep mode, stores notification information according to the management standards in the memory of the battery management system, and monitors the battery. The control unit accesses the memory to determine the state of the battery pack.

In addition, the battery management system stores standards (standards) for deviation, current, voltage, and temperature of the battery cells constituting the battery pack and notification information according to the standards (standards) in the memory, so that the battery monitoring control unit It is characterized in that the state of the battery pack can be determined by accessing the memory.

In addition, the battery management system performs a cell balancing operation on a plurality of battery cells included in the battery pack, and each of the plurality of battery cells independently performs the balancing operation based on a difference in charge state when the remaining battery power is 80% or more. It is characterized by further comprising:

In addition, the battery pack parameters managed by the battery management system include battery pack capacity, discharge cutoff voltage, current, internal resistance, charging conditions, and cycle characteristics, and the current in the battery pack parameters is the maximum charging current. , It is characterized by including standard discharge current, fast discharge current, maximum sustained discharge current, and pulse discharge current.

In addition, the battery monitoring and control device generates alarm information for the alarm when an alarm for charging overvoltage, charging current abnormality, discharging low voltage, discharging current abnormality, battery cell deviation, or temperature abnormality for the battery pack is generated from the battery management system. It further includes managing the state of the battery in two steps by storing it in a system log (syslog) and, when blocking occurs, providing blocking information about the blocking to a network management system through SNMP (simple network management protocol). It is characterized by

In addition, managing the battery state may further include generating an alarm indicating that the battery needs to be replaced when an abnormality in the charging state occurs upon completion of charging.

In addition, the power monitoring and control device is configured to cut off the voltage of the battery pack when a cutoff due to discharge low voltage and battery cell deviation occurs while discharging the battery pack in the power outage state, and sends cutoff information about the cutoff to an emergency battery failure. fail) message to the network management system.

In addition, the power monitoring and control device provides the network management system with blocking information according to charging current abnormality, discharging current abnormality, and cell deviation abnormality of the battery pack when returning to normal operation from the power failure state, or charging status upon completion of charging. In the case of the above (when the SOC is less than 70 % when charging is completed), the display further includes displaying a command message for checking the battery status of the Ethernet switch or replacing the power supply, or displaying it with a display device.

In addition, the power monitoring and control device stores an alarm release message in the system log (syslog) when a cutoff occurs due to an abnormal state of the battery cell or battery pack or when recovery from an abnormal charging state occurs upon completion of charging, and at the same time manages the network through SNMP. It is characterized by being provided as a system.

In addition, the battery monitoring and control method of a power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch according to an embodiment of the present invention includes, in the battery monitoring control unit, using a battery management system for the built-in battery pack of the 5G L2 switch. It includes a monitoring and controlling step, and is characterized by monitoring and controlling the operation of the battery pack so that the Ethernet switch operates normally and without interruption even under normal power supply and power outages.

In addition, the battery monitoring control step, when managing the battery pack through the battery management system, sets the battery pack to a charging mode, a discharging mode, or a sleep mode according to one of the charging mode, discharging mode, and sleep mode of the battery pack. It further includes controlling power supply to the switch by monitoring one of the modes.

In addition, the battery monitoring and control method includes providing battery pack management standards corresponding to the charging mode, discharging mode, and sleep mode in the battery management system, and sending notification information according to the management standards to the memory of the battery management system. It further includes a step of storing in , wherein the battery monitoring control step is characterized in that the state of the battery pack is determined by accessing the memory.

In addition, the battery monitoring and control method performs a cell balancing operation on a plurality of battery cells included in the battery pack in the battery management system, wherein each of the plurality of battery cells is affected by a SOC difference when the remaining battery capacity is 80% or more. It is characterized in that it further includes performing the balancing operation itself.

In addition, the battery monitoring and control method: When an alarm for charging overvoltage, charging current abnormality, discharging low voltage, discharging current abnormality, battery cell deviation, or temperature abnormality for the battery pack is generated from the battery management system, alarm information for the alarm is generated. A step of storing in the system log (syslog), and when the battery operation is blocked due to charging overvoltage, charging current abnormality, discharging low voltage, discharging current abnormality, battery cell deviation, and temperature abnormality for the battery pack, SNMP (simple network management protocol) It further includes providing blocking information about the blocking to the network management system, and storing the alarm information in the system log and providing the blocking information to the network management system to check the status of the battery in two steps. It is characterized by managing.

In addition, managing the battery state may further include generating an alarm indicating that the battery needs to be replaced when an abnormality in the charging state occurs upon completion of charging.

In addition, in the power monitoring and control method, when a cutoff due to discharge low voltage and battery cell deviation occurs during battery pack discharge in the power failure state, the voltage of the battery pack is cut off, and the cutoff information about the cutoff is sent to an emergency battery failure. fail) message to the network management system, and when returning to normal operation from the above power outage, blocking information due to abnormal charging current, abnormal discharging current, abnormal cell deviation of the battery pack is provided to the network management system, or when charging is completed. When an abnormality in the charging state occurs, the display further includes displaying a command message for checking the battery status of the Ethernet switch or replacing the power supply, or displaying it on a display device.

In addition, the power monitoring and control method stores an alarm release message in the system log (syslog) when a cutoff occurs due to an abnormal state of the battery cell or battery pack or when recovery from an abnormal charging state occurs upon completion of charging, and at the same time, network management is performed through SNMP. It is characterized by being provided as a system.

As described above, the battery monitoring and control method of the power device with a built-in lithium iron phosphate battery for 5G L2 switch of the present invention controls the operation between the power supply unit (SMPS) and the battery pack when power is normally supplied or a power outage occurs. It has the effect of enabling high-capacity data processing to be performed without interruption by continuously supplying it to the Ethernet switch.

In addition, the present invention monitors the status of the battery pack through a battery management system, stores and manages notification information according to the monitoring results, and stores it as a system log when an alarm occurs according to the notification information to check and inspect the history of the status of the battery pack. It has the effect of allowing you to do it.

In addition, the present invention provides information about the blockage to the network management system when a blockage occurs in the notification information, and also displays a battery check or power supply replacement command on the Ethernet switch when a charging status abnormality occurs when charging is completed in a timely manner. This has the effect of forcing you to check the battery or replace the power supply.

Figure 1 is a conceptual diagram illustrating a battery monitoring and control method of a power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch according to an embodiment of the present invention.
Figure 2 is a diagram showing the operation mode of a battery pack according to an embodiment of the present invention.
Figure 3 is a block diagram showing the configuration of a battery monitoring and control device according to an embodiment of the present invention.
Figure 4 is a diagram illustrating a method for monitoring and managing the state of a battery pack in a charging mode according to an embodiment of the present invention.
Figure 5 is a diagram illustrating a method for monitoring and managing the state of a battery pack in a discharge mode according to an embodiment of the present invention.
Figure 6 is a block diagram showing the configuration of a battery management system according to an embodiment of the present invention.
Figure 7 is a block diagram showing the configuration of a battery monitoring control unit according to an embodiment of the present invention.
Figure 8 is a flowchart showing a procedure for monitoring and controlling the status of a battery pack for a power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch according to an embodiment of the present invention.

Hereinafter, with reference to the attached drawings, a preferred embodiment of the battery monitoring and control method of the power supply device with a built-in lithium iron phosphate (LiFePo4) battery for a 5G L2 switch of the present invention will be described in detail. The same reference numerals in each drawing indicate the same member. In addition, specific structural and functional descriptions of the embodiments of the present invention are merely illustrative for the purpose of explaining the embodiments of the present invention, and unless otherwise defined, all terms used herein, including technical or scientific terms, are provided. The terms have the same meaning as generally understood by those skilled in the art to which the present invention pertains. Terms as defined in commonly used dictionaries should be interpreted as having meanings consistent with the meanings they have in the context of the related technology, and unless clearly defined in this specification, should not be interpreted in an idealized or overly formal sense. It is desirable not to.

Figure 1 is a conceptual diagram illustrating a battery monitoring and control method of a power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch according to an embodiment of the present invention.

As shown in FIG. 1, the battery monitoring control device 100 (hereinafter referred to as the battery monitoring control device) of the power supply device with a built-in lithium iron phosphate battery for the 5G L2 switch according to an embodiment of the present invention is used for the 5G L2 switch. It is provided in a power supply device with a built-in battery pack (not shown).

In addition, the battery monitoring and control device 100 performs a function of monitoring and controlling the operation of the battery so that the Ethernet switch operates normally and without interruption even when power is normally supplied from a commercial power supply or in a power outage.

An Ethernet switch refers to a network switch that processes data (information) at gigabit speeds and allows CPE (customer premises equipment) to use high-speed Ethernet services.

Here, CPE refers to subscriber terminals, including wired and wireless communication terminals, provided by subscribers who subscribe to the Ethernet service to use the Ethernet service.

A conventional Ethernet switch has a structure in which the power required for operation of the Ethernet switch is supplied from a commercial power supply.

However, in the event of a power outage, including a power failure from the commercial power supply (supply below the preset power level), the Ethernet switch may go down, resulting in a fatal problem where the Ethernet service cannot be used.

Therefore, the present invention provides a power device with a built-in battery pack, so that when a power outage occurs, power is supplied from the battery pack's power source, thereby allowing the Ethernet switch to operate without interruption.

Additionally, a battery pack is composed of a plurality of battery cells (e.g., four battery cells) connected in series.

Meanwhile, in order to prevent the Ethernet switch from being affected due to a breakdown (failure) of the battery pack, a battery monitoring and control device 100 is provided in the power supply to monitor the status of the battery pack, and there is concern about a breakdown in the battery pack. If present, the power (voltage) of the battery pack is cut off to protect the battery pack and Ethernet switch, and the battery status can be checked in a timely manner or the power supply part of the power device can be replaced.

Meanwhile, the battery pack operates in three operation modes including charging mode, discharging mode, and sleep mode, and each of the operating modes will be described in detail with reference to FIG. 2.

The battery monitoring and control device 100 switches the battery pack to a charging mode to charge the battery pack when power is stably supplied from a commercial power source.

In addition, when a power outage occurs, the battery monitoring and control device 100 controls the power unit including the battery pack of the power device and switches the power supply source to the battery pack, thereby allowing the Ethernet switch to operate using the power of the battery pack.

Additionally, the battery monitoring and control device 100 switches the battery pack to sleep mode when a preset event occurs, including the battery pack being fully charged.

The battery monitoring and control device 100 manages the state of the battery pack, such as battery pack capacity, discharge cutoff, voltage, current, internal resistance, charging conditions, discharge conditions, temperature conditions, cycle (i.e., switching of each mode) characteristics, etc. Stores and manages the parameters of the battery pack including.

Current in the parameters of the battery pack includes maximum charge current, standard discharge current, fast discharge current, maximum sustained discharge current, and pulse discharge current.

The battery monitoring and control device 100 is equipped with battery management standards according to each operation mode of the battery pack, and according to the management standards, charge overvoltage (overcharge), charge current abnormality, discharge low voltage (overdischarge), discharge current abnormality, Monitor abnormal conditions of the battery pack, including battery cell deviation abnormalities, temperature abnormalities, abnormal charging status upon completion of charging, or combinations thereof.

The battery monitoring and control device 100 stores and manages alarm information in the system log when an abnormal state of the battery pack that meets the alarm criteria included in the management standard occurs. Through this, the administrator can check the history of the battery pack's status by checking the system log.

The battery monitoring and control device 100 controls the voltage of the battery pack when an abnormal state of the battery pack that meets the blocking criteria included in the management standard occurs (i.e., when the condition of the battery pack is bad enough to affect the Ethernet switch or fails). The Ethernet switch is protected by blocking, and information about the blocking (blocking information) is provided to the network management system 200.

This makes it possible for the administrator to check the status of the battery pack of the Ethernet switch or replace the power supply in a timely manner.

Meanwhile, when the battery monitoring and control device 100 provides blocking information to the network management system 200, it displays a command message for battery status check or power supply replacement through a display or LED provided on one side of the Ethernet switch to the user. can be provided to. Indication through LEDs can be accomplished by turning the LEDs off or lighting them in a specific color (e.g. red).

The network management system 200 includes a function to manage a network (network) including each Ethernet switch, and when blocking information is received, notification of blocking is included including information (e.g., identifier, location information, etc.) of the corresponding Ethernet switch. It may be configured to provide to an administrator terminal (not shown).

Figure 2 is a diagram showing the operation mode of a battery pack according to an embodiment of the present invention.

As shown in FIG. 2, the operation mode of the battery pack according to an embodiment of the present invention includes a charging mode, a discharging mode, and a sleep mode.

The battery monitoring and control device 100 determines power supply conditions including power failure, power supply hernia, turning off the power switch provided in the Ethernet switch, or a combination thereof, whether the battery pack is fully charged, whether the battery pack is fully discharged, Switching the operation mode of the battery pack by checking the status including the communication connection of the Ethernet switch or a combination thereof, and determining the transition to the next operation mode by referring to the operation mode of the previous state in each operation mode of the battery pack. do.

Here, whether the battery pack is fully charged and whether the battery pack is fully discharged is provided by the battery management system 110 of the battery monitoring and control device 100.

In addition, the power supply status and communication connection status for power supply hernia and power switch off are provided from the Ethernet switch, and the status for power failure is provided from the power supply unit.

The battery monitoring and control device 100 checks the power supply status and, if power (commercial power) is stably supplied, switches the operation mode of the battery pack to the charging mode to charge the battery pack.

Additionally, the battery monitoring and control device 100 checks the power supply status in the charging mode and, if there is a power outage, switches the operation mode of the battery pack from charging mode to discharging mode and supplies power from the battery pack to the Ethernet switch through the power supply unit.

In addition, as a result of checking the power supply status in the discharge mode, the battery monitoring control device 100 switches the operation mode of the battery pack from the discharge mode to the charge mode when the power is restored, and performs charging of the battery pack through the power supply unit. Supply the restored power to the Ethernet switch.

Meanwhile, sleep mode is an event that occurs when abnormal situations such as power supply hernia, power switch OFF, and communication interruption occur, or the battery pack is fully charged in charging mode, or the battery pack is completely discharged in discharge mode, or a combination of these. This is an operation mode that is switched when an operation occurs.

Sleep mode is an idle mode that switches the battery pack to an idle state when the battery pack is fully charged in charging mode, and protects the battery from damage when abnormal situations occur, including full discharge other than full charge. It includes a battery protection mode for

At this time, the battery monitoring and control device 100 switches the operation mode of the battery pack from the charging mode to the idle mode of the sleep mode when the battery pack is fully charged in the charging mode, and when the power unit is disconnected or the power switch of the Ethernet switch is turned off, If the Ethernet switch is blocked from communicating with the upper end or lower end of the network, or a combination thereof, the battery pack's operation mode is switched from charging mode to sleep mode battery protection mode.

In addition, even in the idle state, if an abnormal condition occurs, such as the power supply unit being disconnected, the power switch of the Ethernet switch is turned off, or communication is blocked, the mode is switched to battery protection mode, and when the abnormal condition is recovered in the battery protection mode, the idle mode is activated. converted to state.

When switching from the charging mode to the idle mode of the sleep mode, when a power outage occurs and the battery pack needs to be discharged, the battery monitoring control device 100 switches the operation mode of the battery pack from the idle mode to the discharging mode.

Additionally, when switching from charging mode to battery protection mode, the power switch is restored (i.e. turned on), communication interruption is restored (i.e. communication resumed), or power supply hernia is restored, the charging mode is switched. At this time, in the case of a power outage, the device switches to discharge mode.

Additionally, in the discharge mode, the battery monitoring and control device 100 operates when the battery pack is completely discharged, the power supply unit is disconnected, the power switch of the Ethernet switch is turned off, or the Ethernet switch communicates with the upper or lower end of the network. If this is blocked, the battery pack's operation mode switches from discharge mode to sleep mode battery protection mode.

When the battery monitoring and control device 100 switches from the discharge mode to the sleep mode (battery protection mode) due to complete discharge, it switches from the sleep mode to the charging mode when power (power recovery) is stably supplied again.

In addition, the battery monitoring and control device 100 operates in discharge mode when the operation mode of the battery pack is switched to sleep mode due to power supply hernia, power switch off, or communication interruption other than complete discharge, when the power switch is restored, or when communication is restored. , Switch back to discharge mode. At this time, when power is stably supplied, the battery monitoring and control device 100 switches from sleep mode to charging mode.

Among the operation modes of the battery pack, sleep mode protects the battery pack by preventing charging or discharging of the battery pack.

Meanwhile, when communication is not possible, it means when communication with network equipment is not possible for 1 to 6 minutes, and full discharge means when the battery pack voltage is 10V or less and the battery cell voltage is 2.5V or less. .

Figure 3 is a block diagram showing the configuration of a battery monitoring and control device according to an embodiment of the present invention.

As shown in FIG. 3, the battery monitoring and control device 100 of the power device with a built-in lithium iron phosphate battery for a 5G L2 switch according to an embodiment of the present invention is provided in the power device with a built-in lithium iron phosphate battery for a 5G L2 switch. .

That is, the power supply device includes a battery pack, a power supply unit including a switched mode power supply (SMPS), and a battery monitoring and control device 100.

The battery pack is constructed by connecting multiple battery cells in series and includes four battery cells. However, it is not limited to this and the battery pack can be composed of four or more battery cells.

In addition, the battery pack is configured to operate the Ethernet switch for more than 10 minutes when using full traffic based on the capacity of all subscriber and uplink ports during a power outage, and for more than 15 minutes when using full traffic based on capacity of 50% of all subscriber and uplink ports. It is configured to operate an Ethernet switch.

When power (AC power) is normally supplied from a commercial power source, the power unit converts it to direct current power through SMPS to supply the power necessary for the operation of the Ethernet switch and to charge the battery pack. Meanwhile, the power supply unit supplies power to the battery pack to the Ethernet switch when the battery pack is in discharge mode (i.e., power outage).

The battery monitoring and control device 100 includes a battery management system 110 (BMS) for managing the status of the battery pack and a battery monitoring control unit 120 for monitoring and controlling the battery pack using the battery management system. .

The battery management system 100 monitors temperature conditions, voltage/current conditions, etc. according to the parameters of the battery pack so that the battery pack can always operate normally, and has a function to charge and discharge the battery only within the normal operating range and overvoltage/overcurrent settings. It performs a protection function for the battery pack.

The battery management system 100 stores and manages battery pack parameters for managing the state of the battery pack. Since battery pack parameters have been described with reference to FIG. 1, further detailed description will be omitted.

In addition, the battery management system 100 has battery management standards according to each operation mode of the battery pack and stores notification information according to abnormal conditions of the battery pack in memory, and the battery monitoring control unit 120 records the memory in real time. By accessing and monitoring the notification information, abnormal conditions of the battery pack can be identified.

Battery management specifications include charging overvoltage (overcharge), charge current abnormality, discharge undervoltage (overdischarge), discharge current abnormality, battery cell deviation abnormality, temperature abnormality, charging status abnormality when charging is completed, or a combination of these for each mode. It defines the standards (or also called standards) for abnormal conditions.

Each management standard is composed of alarm standards and blocking standards for blocking the voltage of the battery pack.

The notification information consists of an alarm message indicating an alarm based on the results of monitoring the status of the battery pack and a blocking message requiring the voltage of the battery pack to be cut off.

Meanwhile, monitoring of abnormal states of the battery pack according to the battery management standard and each mode of the battery pack will be described in detail with reference to FIGS. 4 to 6.

Additionally, as a result of monitoring the battery cell deviation, the battery management system 110 controls the power supply unit to perform a cell balancing operation on a plurality of cells constituting the battery pack.

At this time, the cell balancing operation adjusts the charging voltage for each battery cell according to the difference in charge when the state of charge (SOC) of each battery cell is more than 80%, or adjusts the discharge voltage so that each battery cell is charged evenly. to be discharged or discharged.

The battery monitoring control unit 120 switches each mode of the battery pack and controls the power unit to supply power.

For example, in the case of a power outage, the battery monitoring control unit 120 switches the battery pack to a discharge mode and controls the power unit to switch the power supply to the battery pack to provide power required for the operation of the Ethernet switch.

In addition, when power is stably supplied from the commercial power supply, the battery monitoring control unit 120 switches the battery pack to charging mode, controls the power unit, converts it to direct current power through SMPS, and provides power required for the operation of the Ethernet switch. and charge the battery pack.

Additionally, when the operation mode of the battery pack is switched to sleep mode, the battery monitoring control unit 120 controls the power supply unit to stop charging and discharging the battery pack.

The battery monitoring control unit 120 accesses the memory of the battery management system 100 and monitors notification information in real time to determine the state (abnormal state) of the battery pack.

When an alarm occurs in the notification information, the battery monitoring control unit 120 stores the corresponding notification information (i.e., alarm information) in the system log (syslog).

Here, the occurrence of an alarm in the notification information means that the notification information includes an alarm message about an abnormal state of the battery pack.

In other words, the notification information in which an alarm has occurred includes an alarm message, and the notification information including the alarm message becomes the alarm information.

Additionally, the battery monitoring control unit 120 immediately cuts off the voltage of the battery pack when a cutoff occurs in the notification information.

Additionally, when the voltage of the battery pack is cut off, corresponding notification information (i.e., cutoff information) is provided to the network management system 200.

In other words, the notification information where blocking has occurred includes a blocking message, and the notification information including the blocking message becomes blocking information.

At this time, blocking information can also be stored and managed as a system log.

That is, the battery monitoring and control device 100 manages the state of the battery pack through two steps by storing alarm information as a system log and providing blocking information to the network management system 200.

Figure 4 is a diagram illustrating a method for monitoring and managing the state of a battery pack in a charging mode according to an embodiment of the present invention.

As shown in FIG. 4, the method for monitoring and managing the state of the battery pack in charging mode according to an embodiment of the present invention is to first measure the external temperature (inside the Ethernet switch device) measured by the battery management system 100. At the same time, the status of the battery pack is monitored, including the temperature measured from the outside of the power supply unit.

When in the charging mode, the battery management system 100 monitors management standards including warning and blocking standards for charging overvoltage, including the charging overvoltage for each battery cell and the charging overvoltage for the battery pack, and management standards for battery cell deviation abnormalities. Management standards including alarm standards and blocking standards, management standards including alarm standards and blocking standards for abnormal charging current, external temperature (temperature measured inside the Ethernet switch device and outside the power supply), and temperature abnormalities during charging. Battery management standards for charging mode, including management standards including warning and blocking standards, and battery management standards for charging mode including abnormal charging status upon completion of charging (if SOC is less than 70%) of the battery pack. Monitor abnormal conditions.

The alarm standard for charging overvoltage of battery cells can be set to a voltage of 3700 mV or higher for each battery cell, and the cutoff standard can be set to 3900 mV or higher.

Additionally, the alarm standard for charging overvoltage of the battery pack can be set to 14800 mV or higher, and the blocking standard can be set to 15600 mV or higher.

Additionally, the alarm standard for battery cell deviation abnormalities can be set to a 500 mV difference for each cell voltage of 3300 mV or more, and the blocking standard can be set to a 600 mV difference for each cell voltage to be 3300 mV or more.

Additionally, the alarm standard for abnormal charging current can be set to 1.2A (0.4C) or higher, and the blocking standard can be set to 1.5A (0.5C) or higher.

In addition, the alarm standard for abnormal external temperature (temperature measured inside the Ethernet switch device and outside the power unit) during discharge can be set to a high temperature of 60 degrees Celsius or higher and a low temperature of -15 degrees Celsius or lower, and the blocking standard is 65 degrees Celsius. It can be set to a high temperature of over 100 degrees and a low temperature of -20 degrees or lower.

Additionally, the alarm standard for the temperature of the battery pack during charging can be set to a high temperature of 60 degrees or higher and a low temperature of 0 degrees or lower, and the cutoff standard can be set to a high temperature of 65 degrees or higher and a low temperature of -5 degrees or lower.

In addition, the battery management system 100 monitors the battery pack status including the external temperature (temperature measured inside the Ethernet switch device and outside the power unit), and as a result, charging overvoltage, charging current abnormality, charging temperature, and battery cell deviation are measured. When the external temperature, which is the temperature measured inside the Ethernet switch device and outside the power supply, or a combination thereof, meets the alarm or blocking criteria, notification information including an alarm message or blocking message for each monitoring result is generated and the battery is activated. Stored in the memory of the management system 100.

Additionally, if an abnormality in the charging state occurs upon completion of charging, the alarm standard for generating the corresponding alarm can be set to when charging is completed but the SOC of the battery pack is still less than 70%.

The memory may be configured as a flash memory, and when the memory capacity is full, the battery management system 110 may be configured to create storage space by deleting previously stored notification information.

The battery monitoring control unit 120 accesses the memory of the battery management system 110 and monitors notification information in real time to determine the state (i.e., abnormal state) of the battery pack.

In addition, when an alarm is generated in the notification information about the status of each battery pack in the charging mode according to the result of monitoring the notification information, the battery monitoring control unit 120 stores the notification information as alarm information in the system log. The system log is stored and managed in a system log memory (not shown) provided in the battery monitoring control unit 120.

Meanwhile, the battery monitoring control unit 120 immediately cuts off the voltage of the battery pack when the notification information about the status of each battery pack in the charging mode is interrupted according to the result of monitoring the notification information.

At this time, the battery monitoring control unit 120 is preferably configured to cut off the voltage of the battery pack within 3 seconds after the cutoff occurs.

Additionally, the battery monitoring control unit 120 transmits notification information that a blockage has occurred to the network management system 200 as blocking information.

Meanwhile, the management standard further includes standards for unblocking. In other words, the unblocking standard is a standard for unblocking according to the state of each battery pack.

On the other hand, if the voltage of the battery pack is blocked because the battery cell deviation meets the blocking standard, the blocking is not released. This is because the battery cell deviation is applied equally in charging mode and discharging mode, and it is obvious that the battery cell deviation will not change even if the voltage of the battery pack is cut off during charging and discharging and return to charging mode or discharging mode. However, when the power supply is replaced, the blocking is released.

In addition, the external temperature abnormality, which is the temperature measured inside the Ethernet switch device and outside the power supply, also applies in the same way in discharge mode.

Additionally, the release standard for unlocking the charging overvoltage block of a battery cell can be set to 3650 mV or less in an alarm or blocking state, and the release standard for unlocking the charging overvoltage block of a battery pack can be set to 14600 mV or less in an alarm or blocking state. .

In addition, when discharging, the release standard for disconnection exceeding the external temperature, which is the temperature measured inside the Ethernet switch device and outside the power supply, is set to an external temperature of 55 degrees or lower or -15 degrees or higher in an alarm or blocking state for high or low temperature. It can be.

In addition, the release standard for unlocking the block due to abnormal temperature during charging can be set to a charging temperature of 55 degrees or less or 0 degrees or more in an alarm or block state due to high or low temperature.

Accordingly, the battery management system 110 generates and stores notification information including an alarm or blocking message for each state as a result of monitoring the battery pack status, and releases the blocking when the monitoring result satisfies the release criteria. Notification information including messages are stored in memory.

At this time, when unblocking occurs in the monitored notification information, the battery monitoring control unit 120 releases the blocking of the voltage of the battery pack according to the previous state of the battery pack.

At this time, the battery monitoring control unit 120 may store the blocking release information (alarm release message) as a system log, and may also provide the alarm release message to the network management system 200.

Here, the fact that unblocking occurred in the notification information means that the notification information includes an unblocking message, and the unblocking information is notification information that includes an unblocking message.

On the other hand, if the voltage of the battery pack is cut off due to abnormal discharge current (e.g. overcurrent), it may be impossible to save it as a system log and provide blocking information to the network management system 200 due to a problem with the main board of the Ethernet switch. there is.

Additionally, the battery management system 110 monitors the status of the battery pack in the charging mode and stores notification information including an alarm message in the memory when the battery pack is fully charged.

Thereafter, as a result of monitoring the notification information in the battery monitoring control unit 120, if notification information including an alarm message indicating that the battery pack is fully charged is confirmed, the operation mode of the battery pack is switched to sleep mode (more specifically, idle mode).

Then, when a power outage occurs, the battery monitoring control unit 120 switches the operation mode of the battery pack from sleep mode to discharge mode so that power from the fully charged battery pack can be supplied to the Ethernet switch through the power supply unit.

Figure 5 is a diagram illustrating a method for monitoring and managing the state of a battery pack in a discharge mode according to an embodiment of the present invention.

As shown in FIG. 5, the method of monitoring and managing the state of the battery pack in discharge mode according to an embodiment of the present invention is first, in the battery management system 100, inside the Ethernet switch device and outside the power supply unit. Monitors the status of the battery pack, including the measured external temperature.

When in the discharge mode, the battery management system 100 provides management standards including alarm and blocking standards for discharge low voltage, including the discharge low voltage of each battery cell and the discharge low voltage for the battery pack, and alarms for battery cell deviation abnormalities. Management standards including standards and blocking standards, management standards including alarm standards and blocking standards for discharge current abnormalities, and alarm standards for external temperature, which is the temperature measured inside the Ethernet switch device and outside the power supply, and temperature during discharge. The status of the battery pack is monitored according to the battery management standards for discharge mode, including management standards including protection and blocking standards.

The alarm standard for low discharge voltage of battery cells can be set to the voltage of each battery cell below 2800mV, and the cutoff standard can be set to 2700mV or less.

Additionally, the alarm standard for low discharge voltage of the battery pack can be set to the voltage of the battery pack below 11200mV, and the cutoff standard can be set to 10800mV or less.

Additionally, the alarm standards and blocking standards for battery cell deviation abnormalities are the same as the charging mode.

Additionally, the alarm standard for abnormal discharge current can be set to 15.0A (5C) or higher, and the blocking standard can be set to 20.0A (6.7C) or higher.

In addition, the external temperature, which is the temperature measured inside the Ethernet switch device and outside the power supply, and the alarm and blocking standards for the temperature in discharge mode are the same as those in charge mode.

In addition, the battery management system 100 monitors the battery pack status including external temperature in the discharge mode, and as a result, an alarm or blocking standard is set based on discharge low voltage, discharge current abnormality, temperature abnormality, battery cell deviation abnormality, or a combination thereof. If it meets, notification information including an alarm message or blocking message about the status of each battery pack is generated and stored in the memory of the battery management system 100.

The battery monitoring control unit 120 accesses the memory of the battery management system 110 to monitor notification information in real time, and according to the monitoring results, an alarm is generated from notification information about the state (abnormal state) of the battery pack in the discharge mode. In the event that occurs, the corresponding notification information is converted into alarm information and stored in the system log.

In addition, when a cutoff occurs in the notification information about the abnormal state of each battery pack, the voltage of the battery pack is immediately cut off and information about the cutoff (blocking information) is transmitted to the network management system 200.

Meanwhile, each management standard in discharge mode further includes a standard for unblocking, and the release standard for unblocking the discharge low voltage of the battery cell can be set to 3000 mV or more, and the release standard for unblocking the low voltage discharge of the battery pack can be set to 3000 mV or higher. The standard can be set above 12000mV.

Additionally, the criteria for releasing the temperature cutoff are the same as for the charging mode.

In discharge mode, the notification information of the battery management system 100 is stored, and the battery monitoring control unit 120 blocks or releases the voltage of the battery pack according to the notification information, stores it as a system log, or sends information about the blocking to the network. What is provided to the management system 200 is different from the state of the battery pack in charging mode, but is performed through the same process.

On the other hand, if the voltage of the battery pack is cut off due to a discharge current exceeding the discharge mode, it may be impossible to save the system log and transmit information about it beyond the main board.

Additionally, the battery management system 110 monitors the status of the battery pack in the discharge mode and stores notification information including an alarm message in the memory when the battery pack is completely discharged.

Afterwards, as a result of monitoring the notification information in the battery monitoring control unit 120, if notification information including an alarm message about complete discharge of the battery pack is confirmed, the operation mode of the battery pack is changed to sleep mode (more specifically, battery pack protection mode). Switch.

Then, when power is stably supplied, the battery monitoring control unit 120 switches the operation mode of the battery pack that has switched to sleep mode to charging mode to charge the battery pack in the power supply unit and supplies the supplied power to the Ethernet switch. Let it happen.

Meanwhile, although FIGS. 4 and 5 do not illustrate a method for managing the state of the battery pack in the sleep mode, the battery management system 100 complies with battery management standards for temperature abnormality, current abnormality, and voltage abnormality according to the sleep mode. Accordingly, the status of the battery pack is monitored and notification information is stored in memory, and the battery monitoring control unit 120 monitors the notification information and stores the alarm information in the system log according to the occurrence of an alarm or blocking, or the network management system (200) ) is configured to provide blocking information.

Figure 6 is a block diagram showing the configuration of a battery management system according to an embodiment of the present invention.

As shown in FIG. 6, the battery management system 100 according to an embodiment of the present invention is for managing the status of the battery pack built into the power device of the Ethernet switch, and includes a battery pack status monitoring unit 111, It is comprised of a notification information generation unit 112, a notification information storage unit 113, a battery cell balancing unit 114, and a memory 115.

The battery pack status monitoring unit 111 monitors the status of the battery pack according to battery management parameters including self-managed battery pack capacity, discharge cutoff, voltage, current, internal resistance, charging conditions, temperature conditions, and discharging conditions. do.

In addition, the battery pack status monitoring unit 111 uses battery management parameters to include charging voltage, charging current, discharge voltage, discharge current, battery cell deviation, temperature, etc. for the battery pack according to charging mode, discharging mode, and sleep mode. Monitor the status of the battery pack.

The notification information generator 112 uses battery management standards corresponding to each of the charging mode, discharging mode, and sleep mode to detect charging overvoltage, charging current abnormality, discharging low voltage, discharging current abnormality, and battery cell deviation abnormality according to each monitoring result. , temperature abnormalities, or a combination of these generates notification information about abnormal conditions.

At this time, the notification information generator 112 generates notification information including the corresponding monitoring result and an alarm message when each monitoring result meets the alarm conditions included in the battery management standard, and each monitoring result complies with the battery management standard. If each of the included blocking conditions is met, notification information including the corresponding monitoring results and blocking message is generated.

Meanwhile, the notification information may include an unblocking message, and the unblocking message is notification information when it is necessary to unblock the voltage of the battery pack previously performed according to the results of monitoring the status of each battery pack. As described above, it is included in . Since the notification information including the unblocking message has been described with reference to FIGS. 4 and 5, further detailed description will be omitted.

The notification information storage unit 113 functions to store the notification information generated by the notification information generation unit 112 in the memory 115.

The battery cell balancing unit 114 performs balancing of battery cells according to the battery cell deviation monitored in charging mode or discharging mode.

Battery cell balancing is to ensure that each battery cell is charged or discharged uniformly and has been described with reference to FIG. 1, so further detailed description will be omitted.

In addition, the memory 115 performs the function of storing and managing notification information, battery management standards according to the operation mode of the battery pack, and battery pack management parameters.

Figure 7 is a block diagram showing the configuration of a battery monitoring control unit according to an embodiment of the present invention.

As shown in FIG. 7, the battery monitoring control unit 120 according to an embodiment of the present invention includes a battery pack operation mode switching unit 121, a power supply control unit 122, a notification information monitoring unit 123, and a system log. It is comprised of a storage unit 124, a battery pack voltage processing unit 125, a blocking information providing unit 126, and a system log memory 127.

The battery pack operation mode switching unit 121 performs the function of switching the operation modes of the battery pack including charging mode, discharging mode, and sleep mode.

The battery pack operation mode switching unit 121 monitors the power supply status including power failure, power supply hernia, and turning off the power switch for the Ethernet switch, whether the battery pack is fully charged in the charging mode, and the completeness of the battery pack in the discharging mode. It performs the function of switching the operation mode of the battery pack by checking the status including discharge.

As described above, power supply status including power supply hernia and turning off the power switch for the Ethernet switch can be provided from the Ethernet switch, and power supply status for power failure can be provided from the power supply unit.

Since switching the operation mode of each battery pack has been described with reference to FIG. 2, further detailed description will be omitted.

In addition, whether the battery pack is fully charged or fully discharged is provided by the notification information monitoring unit 123 described below, and the notification information monitoring unit 123 monitors the notification information and reports when the battery pack is fully charged in charging mode. When notification information including an alarm message or notification information including an alarm message for a case in which the battery pack is completely discharged in discharge mode is confirmed, this information is provided to the battery pack operation mode switching unit 121 and the battery pack is activated. Switch the operation mode to sleep mode.

The power supply control unit 122 controls the power supply unit according to the charging mode or discharging mode to supply power supplied from a commercial power supply to the Ethernet switch, or to supply power from the battery pack to the Ethernet switch.

The notification information monitoring unit 123 accesses the memory of the battery management system 100 and monitors notification information in real time to determine the status of the battery pack.

That is, the notification information monitoring unit 123 generates an alarm and cancels the blocking for abnormal conditions including charging overvoltage, charging current abnormality, discharging low voltage, discharging current abnormality, battery cell deviation abnormality, temperature abnormality, or a combination thereof. It is monitoring.

As a result of monitoring the notification information, the system log storage unit 125 performs a function of storing the notification information in the system log as alarm information when an alarm is generated from the notification information.

System logs are stored and managed in the system log memory 127.

The battery pack voltage processing unit 125 performs a function of immediately blocking the voltage of the battery pack when a cutoff occurs in the notification information, thereby preventing the Ethernet switch from being affected by a failure of the battery pack or a failure of the power supply unit. Perform.

The blocking information provider 126 performs the function of providing the notification information as blocking information to the network management system 200 when a blocking occurs in the notification information.

Hereinafter, the operations of the battery pack voltage processing unit 125 and the blocking information providing unit 126 will be described in detail according to individual cases.

The battery pack voltage processing unit 125 blocks the voltage of the battery pack when a discharge low voltage, battery cell deviation abnormality, temperature abnormality, or a combination thereof occurs in the notification information while discharging the battery pack in a power outage, and the blocking information providing unit 126 provides blocking information about this to the network management system 200 as an emergency battery failure message.

In addition, when returning to normal operation from a power outage (i.e., when power is normally supplied), the battery pack voltage processing unit 125 detects a charging current abnormality, a discharging current abnormality, a battery cell deviation abnormality, a temperature abnormality, or a combination thereof. When blocking occurs in the notification information, the voltage of the battery pack is cut off, and the blocking information providing unit 126 provides the blocking information to the network management system 200.

At this time, the battery monitoring control unit 120 displays or displays a command message for checking the battery status or replacing the power supply to the user on a display or display device (LED) provided on one side of the Ethernet switch.

In addition, the battery voltage processing unit 125 blocks the voltage of the battery pack when a cutoff due to low discharge voltage occurs in the notification information, and thereafter, a release message for low discharge voltage occurs in the notification information (i.e., a release message according to the case of recharging). If you do so, the blocking will be canceled.

In addition, when a cutoff due to charging overvoltage occurs in the notification information, the battery voltage processing unit 125 cuts off the voltage of the battery pack, and the cutoff information provider 126 transmits the cutoff information to the network management system 200.

At this time, the battery monitoring control unit 120 displays or displays a command message for checking the battery status or replacing the power supply to the user on a display or display device (LED) provided on one side of the Ethernet switch.

The system log memory 127 performs the function of storing and managing system logs.

Meanwhile, blocking information is transmitted and received through SNMP (simple network management protocol).

As described above, the status of the battery pack is managed in two stages by storing alarm information in the system log when an alarm occurs and providing blocking information to the network management system 200 when an alarm occurs.

In addition, managing the state of the battery pack further includes generating an alarm indicating that the battery pack needs to be replaced when a charging state abnormality occurs upon completion of charging.

In addition, as a result of monitoring the notification information, the battery monitoring control unit 120 replaces the power supply unit (battery enclosure) to recover from blockage due to battery cell charging overvoltage, battery pack charging overvoltage, battery cell deviation abnormality, and charging current abnormality, or when charging is completed. When recovery from an abnormal charging condition is confirmed, an alarm release message regarding this is stored in the system log and provided to the network management system through SNMP.

Meanwhile, replacement of the power supply can be confirmed by detecting a change in the unique number of the battery pack built into the battery pack.

In addition, the blocking for abnormal discharge current is canceled when the network (subscriber network) equipment is replaced or the power supply unit is replaced, but since the blocking information for abnormal discharge current is not provided to the network management system 100, an alarm cancellation message for abnormal discharge current is sent. Again, it is not transmitted to the network management system 200.

That is, the battery monitoring and control device 100 of the present invention automatically sends an alarm release message when a cutoff occurs due to an abnormal state of the battery cell or battery pack, or when a charging condition abnormality occurs upon completion of charging and the battery pack is replaced with a normal battery pack. is stored in the system log and transmitted to the network management system 200.

The alarm release message for battery cell charging overvoltage includes messages for battery replacement and overcharge release for each cell, and the alarm release message for battery pack charging overvoltage includes messages for battery replacement and overcharge release for each cell. It consists of messages about battery replacement and over charge release for pack.

In addition, the alarm release message for battery cell deviation abnormality includes messages for battery replacement and battery cell quality release, and the alarm release message for charging current abnormality includes battery replacement and charge overcurrent release. It consists of a message about the current release.

Upon completion of charging, the alarm cancellation message for abnormal charging status includes a message indicating that battery replacement and full charging are possible (full charge is ok).

Figure 8 is a flowchart showing a procedure for monitoring and controlling the status of a battery pack for a power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch according to an embodiment of the present invention.

As shown in FIG. 8, the procedure for monitoring and controlling the status of the battery pack for the power device with a built-in lithium iron phosphate battery for a 5G L2 switch according to an embodiment of the present invention first involves the use of the battery detection control device 100. In the battery management system 110, a step is performed to monitor the state of the battery pack according to the operation mode of the battery pack, including charging mode, discharging mode, and sleep mode (S110).

The monitoring step is to monitor the status of the battery pack according to the battery pack management parameters.

Next, the battery management system 110 performs a notification information generation step of generating notification information for each monitoring result according to the management standards of the battery pack according to the operation mode of the battery pack (S120).

In other words, the notification information includes charging overvoltage, charging current abnormality, discharging low voltage, discharging current abnormality, battery cell deviation abnormality, temperature abnormality, or a combination thereof according to the management standards of the battery pack corresponding to the operation mode of the battery pack. As described above, it is configured to include an alarm message and a blocking message regarding an abnormal state of the battery pack.

Next, the battery monitoring control unit 120 of the battery monitoring control device 100 accesses the memory 115 of the battery management system 110 to perform a notification information monitoring step to monitor notification information (S130).

The notification information monitoring step monitors the occurrence of an alarm or blocking occurrence of an abnormal state of the battery pack. Meanwhile, as described above, monitoring notification information further includes monitoring the occurrence of unblocking in the notification information.

Next, if an alarm occurs in the notification information as a result of monitoring the notification information (S140), a system log storage step is performed in which the notification information in which the alarm occurred is saved as alarm information in the system log (S150).

Additionally, as a result of monitoring the notification information, if a blocking occurs in the corresponding notification information (S141), the battery monitoring control unit 120 performs a battery pack voltage processing step to block the voltage of the battery pack (S151).

Meanwhile, as a result of monitoring the notification information, if unblocking occurs in the corresponding notification information, the battery monitoring control unit 120 performs a step of unblocking the battery pack voltage previously.

Since the process of unblocking the battery pack voltage has been described with reference to FIGS. 4 to 7, further detailed description will be omitted.

Next, the battery monitoring control unit 120 performs a blocking information provision step in which notification information that a blocking has occurred is provided to the network management system 200 as blocking information (S161).

Meanwhile, as described above, notification information that has occurred blocking and notification information that has resulted in unblocking can also be stored and managed as a system log.

As such, the present invention has the effect of providing an uninterrupted Ethernet service by providing a battery monitoring and control device for a battery-embedded power supply device to allow the Ethernet switch to continuously operate normally even under normal power supply and power outages.

In addition, the present invention monitors charging overvoltage, discharging undervoltage, charging current abnormality, discharging current abnormality, battery cell deviation abnormality, temperature abnormality, or a combination of these for the battery pack, and stores it in the system log when an alarm occurs and sends it to SNMP when blocked. It is provided as a network management system to manage the status of the battery pack in two stages. In addition, if an abnormality in the charging state occurs upon completion of charging, it further includes generating an alarm indicating that the battery needs to be replaced.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and various modifications and other equivalent embodiments can be made by those skilled in the art. You will understand that it is possible. Therefore, the scope of technical protection of the present invention should be determined by the scope of the patent claims below.

100: Battery monitoring control device 110: Battery management system
111: Battery pack status monitoring unit 112: Notification information generating unit
113: Notification information storage unit 114: Battery cell balancing unit
115: memory 120: battery monitoring control unit
121: Battery pack operation mode switching unit 122: Power supply control unit
123: Notification information monitoring unit 124: System log storage unit
125: Battery pack voltage processing unit 126: Blocking information provision unit
127: System log memory

Claims (19)

Battery management system for the built-in battery pack of the 5G L2 switch; and
It includes a battery monitoring and control unit that monitors and controls the battery pack using the battery management system,
A battery monitoring and control device for a power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch, characterized in that it monitors and controls the operation of the battery pack so that the switch operates normally and without interruption even in normal power supply and power outage conditions. In claim 1,
The battery monitoring control unit,
In managing the battery pack through the battery management system, the battery pack is monitored for charging mode, discharging mode, or sleep mode according to one of the charging mode, discharging mode, and sleep mode of the battery pack. A battery monitoring control device for a power supply device embedded with a lithium iron phosphate battery for a 5G L2 switch, comprising controlling the supply of power to the switch. In claim 2,
The battery management system is,
Provides corresponding battery pack management standards according to the charging mode, discharging mode, and sleep mode, and stores notification information according to the management standards in the memory of the battery management system,
A battery monitoring and control device for a power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch, characterized in that the battery monitoring control unit accesses the memory to determine the state of the battery pack. In claim 2,
The battery management system is,
By storing the standards for deviation, current, voltage, and temperature of the battery cells constituting the battery pack and notification information according to the standards in the memory, the battery monitoring control unit can access the memory to determine the status of the battery pack. A battery monitoring and control device for a power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch. In claim 1,
The battery management system is,
A cell balancing operation is performed on a plurality of battery cells included in the battery pack, and each of the plurality of battery cells independently performs the balancing operation based on a difference in state of charge when the remaining battery power is 80% or more. A battery monitoring and control device for a power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch. In claim 1,
The parameters of the battery pack managed by the battery management system are:
Includes battery pack capacity, discharge cutoff voltage, current, internal resistance, charging conditions, and cycle characteristics.
The current in the parameters of the battery pack includes maximum charge current, standard discharge current, fast discharge current, maximum sustained discharge current, and pulse discharge current. Battery monitoring of the power supply device with a built-in lithium iron phosphate battery for 5G L2 switch. controller. In claim 1,
The battery monitoring and control device,
When an alarm for charging overvoltage, charging current abnormality, discharging low voltage, discharging current abnormality, battery cell deviation, or temperature abnormality for the battery pack is generated from the battery management system, the alarm information regarding the alarm is stored in the system log (syslog). When the battery operation is blocked due to charging overvoltage, charging current abnormality, discharging low voltage, discharging current abnormality, battery cell deviation, or temperature abnormality for the battery pack, the reminder is sent to the network management system through SNMP (simple network management protocol). A battery monitoring and control device for a power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch, further comprising managing the state of the battery in two stages by providing blocking information about blocking. In claim 1,
The power monitoring and control device,
If a cutoff due to low discharge voltage or battery cell deviation occurs while discharging the battery pack in the above power failure state, the voltage of the battery pack is cut off, and the cutoff information is sent to the network management system as an emergency battery failure message. A battery supervisory control device for a power supply device embedded with a lithium iron phosphate battery for a 5G L2 switch, further comprising providing. In claim 8,
The power monitoring and control device,
When returning to normal operation from the above power outage, when blocking information due to charging current abnormality, discharging current abnormality, and cell deviation abnormality of the battery pack is provided to the network management system, or when charging status is abnormal upon completion of charging (SOC upon completion of charging) is less than 70 % ), the power supply device with a built-in lithium iron phosphate battery for the 5G L2 switch further comprises displaying a command message for checking the battery status of the Ethernet switch or replacing the power supply, or displaying it with a display device. Battery supervisory control device. In claim 9,
The power monitoring and control device,
5G L2, which is characterized by storing an alarm release message in the system log (syslog) when a shutdown occurs due to an abnormal state of the battery pack or when recovering from an abnormal charging state upon completion of charging, and at the same time providing it to the network management system through SNMP. Battery supervisory control device for power supply with built-in lithium iron phosphate battery for switch. In a battery monitoring and control unit, monitoring and controlling the battery pack using a battery management system for the built-in battery pack of the 5G L2 switch,
A battery monitoring and control method for a power device with a built-in lithium iron phosphate battery for a 5G L2 switch, characterized in that the operation of the battery pack is monitored and controlled so that the Ethernet switch operates normally and without interruption even in normal power supply and power outage conditions. In claim 11,
The battery monitoring control step is,
In managing the battery pack through the battery management system, the battery pack is monitored for charging mode, discharging mode, or sleep mode according to one of the charging mode, discharging mode, and sleep mode of the battery pack. A battery monitoring and control method for a power device with a built-in lithium iron phosphate battery for a 5G L2 switch, further comprising controlling the supply of power to the switch. In claim 12,
The battery monitoring control method is,
In the battery management system, providing corresponding battery pack management standards according to the charging mode, discharging mode, and sleep mode, and storing notification information according to the management standards in the memory of the battery management system. And
The battery monitoring and control step is a battery monitoring and controlling method of a power device with a built-in lithium iron phosphate battery for a 5G L2 switch, characterized in that the state of the battery pack is determined by accessing the memory. In claim 12,
The battery management system is,
By storing the standards for deviation, current, voltage, and temperature of the battery cells constituting the battery pack and notification information according to the standards in the memory, in the battery monitoring control step, the memory is accessed to check the status of the battery pack. A battery monitoring and control method for a power supply device with a built-in lithium iron phosphate battery for a 5G L2 switch. In claim 11,
The battery monitoring control method is,
In the battery management system, a cell balancing operation is performed on a plurality of battery cells included in the battery pack, and each of the plurality of battery cells independently performs the balancing operation due to a SOC difference when the remaining battery power is 80% or more. A battery monitoring and control method for a power device with a built-in lithium iron phosphate battery for a 5G L2 switch, further comprising: In claim 11,
The parameters of the battery pack managed by the battery management system are:
Includes capacity, discharge cutoff voltage, current, internal resistance, charging conditions, and cycle characteristics of the battery pack,
The current in the parameters of the battery pack includes maximum charge current, standard discharge current, fast discharge current, maximum sustained discharge current, and pulse discharge current. Battery monitoring of the power supply device with a built-in lithium iron phosphate battery for 5G L2 switch. Control method. In claim 11,
The battery monitoring control method is,
When an alarm for charging overvoltage, charging current abnormality, discharging low voltage, discharging current abnormality, battery cell deviation, or temperature abnormality for the battery pack is generated from the battery management system, the alarm information regarding the alarm is stored in the system log (syslog). saving; and
When battery operation is blocked due to charging overvoltage, charging current abnormality, discharging low voltage, discharging current abnormality, battery cell deviation, or temperature abnormality for the battery pack, the blocking information about the blocking is sent to the network through SNMP (simple network management protocol). It further includes providing a management system,
Battery monitoring of a power device with a built-in lithium iron phosphate battery for a 5G L2 switch, characterized in that the status of the battery is managed in two stages by storing the alarm information in the system log and providing the blocking information to the network management system. Control method. In claim 11,
The power monitoring and control method is,
If a cutoff due to low discharge voltage or battery cell deviation occurs while discharging the battery pack in the above power failure state, the voltage of the battery pack is cut off, and the cutoff information is sent to the network management system as an emergency battery failure message. Provides,
When returning to normal operation from the power outage, if blocking information due to charging current abnormality, discharging current abnormality, or battery pack cell deviation abnormality is provided to the network management system, or if a charging status abnormality occurs upon completion of charging, the Ethernet switch A battery monitoring and control method for a power device with a built-in lithium iron phosphate battery for a 5G L2 switch, further comprising displaying a command message for checking the battery status or replacing the power unit, or displaying it with a display device. In claim 18,
The power monitoring and control method is,
5G L2, which is characterized by storing an alarm release message in the system log (syslog) when a shutdown occurs due to an abnormal state of the battery pack or when recovering from an abnormal charging state upon completion of charging, and at the same time providing it to the network management system through SNMP. Battery monitoring and control method for power supply device with built-in lithium iron phosphate battery for switch.