KR20210126888A - Battery management system for tunnel light - Google Patents

Abstract

The present invention relates to a battery management system for a tunnel light. When the temperature of the battery cells detected by the temperature sensor connected in a one-to-one correspondence with at least one battery cell constituting the battery pack operating in discharging operation is higher than the reference temperature set automatically to prevent overheating during the on/off operation of the switch corresponding to the battery cell, the output frequency of the PWM signal corresponding to the switch is outputted lower than the output frequency of the PWM signal output immediately before, based on the temperature difference between the collected battery cell temperature and the reference temperature, refer to the temperature difference/frequency table prepared in advance to prevent overheating, so that the corresponding switch perform the cell balancing function in the overheat protection state. According to the present invention, the output frequency of the PWM signal corresponding to the switch is lowered than the output frequency of the PWM signal output immediately before output to prevent overheating during the on/off operation of the switch corresponding to the battery cell, so that the switch performs the cell balancing function in the overheat protection state, thereby reducing the voltage and current generation of the noise component at the on/off switching time of the corresponding switch (e.g., FET). As a result, the voltage and current of this noise component prevent overheating of the switch (e.g., FET) and other circuit elements (e.g., capacitors) therearound so that a failure of the battery management system is prevented.

Description

Battery management system for tunnel light

The present invention relates to a battery management system for a tunnel light, and more particularly, by detecting a temperature change of each of a plurality of battery cells constituting a battery pack, to reduce a charge state imbalance between battery cells and to maintain voltage uniformity. It relates to a battery management system for a tunnel light that performs a function.

In general, tunnel lights installed in tunnels are switched so that power is supplied to one of the plurality of wires according to the external luminance in a state in which a plurality of wires are previously connected to a plurality of tunnel lights of uniform illuminance to illuminate the tunnel. control the illuminance of

The conventional tunnel lighting system turns on or turns off the tunnel lights connected to the wiring by selectively supplying or stopping the supply of power to some wirings among a plurality of wirings according to external luminance. That is, the conventional tunnel lighting system illuminates the inside of the tunnel with a plurality of tunnel lights of uniform illuminance, and adjusts the number of the tunnel lights to be turned on according to the external luminance so that the luminance of the road in the tunnel section satisfies the standard specification.

Such a conventional tunnel lighting system has a problem in that, when any of the turned on tunnel lights is turned off due to a failure, the luminance of the road surface illuminated by the malfunctioning tunnel light becomes darker than a reference value, thereby preventing drivers from driving safely. In addition, there is a problem in that the wiring of the tunnel lighting system is complicated because it is necessary to additionally connect a spare tunnel light in case any of the tunnel lights are broken.

When the power goes out, the general tunnel lights are turned off, so a device is needed to turn on the emergency tunnel lights using the power of the secondary battery. A power supply device using such a secondary battery uses a battery pack in which a plurality of battery cells performing charge/discharge operation are connected in series and/or in parallel as a high voltage battery.

The above-described battery pack has a state of charge (State of Charge, Since SOC) imbalance inevitably occurs, a battery cell balancing function is performed to reduce the charge state imbalance between battery cells in charge/discharge operation, such as a power supply using a secondary battery, and to maintain voltage uniformity. A battery management system is provided.

For example, in Patent Document 1, the control unit determines a balancing target battery cell according to the result of measuring the voltage of each of at least one or more battery cells by the voltage measuring unit, and a switch (eg, FET) of the switching unit associated with the output of the corresponding battery cell. A battery management system that performs battery cell balancing by outputting a PWM signal is disclosed.

In the conventional battery management system as disclosed in Patent Document 1, in order to perform battery cell balancing, the control unit uses a PWM signal with a different duty cycle, that is, an on/off duty ratio for each battery cell, but the output frequency is fixed to the same value. print out

As such, in the control unit of the conventional battery management system, the duty cycle of each battery cell, that is, the on/off duty ratio is different, but the output frequency is fixed to the same value by outputting the PWM signal to the switch ( For example, when ON/OFF switching of an FET is controlled, a voltage and current of a noise component are generated at the on/off (ON/OFF) switching time of the corresponding switch (eg, FET), and this noise component There is a problem in that the corresponding switch (eg, FET) and other circuit elements (eg, capacitor, etc.) are overheated by the voltage and current of the battery management system, resulting in a failure of the battery management system.

(Patent Document 1) KR10-1465693 B1

SUMMARY OF THE INVENTION The present invention is to solve the conventional problems as described above, and an object of the present invention is to detect the battery by a temperature sensor connected to at least one battery cell constituting a charging/discharging operation in a one-to-one correspondence. If the temperature of the cell is above the reference temperature that is set automatically to prevent overheating during the on/off operation of the switch corresponding to the battery cell, overheating is prevented based on the temperature difference between the collected temperature of the battery cell and the reference temperature For this purpose, referring to the temperature difference/frequency table made in advance, the output frequency of the PWM signal corresponding to the switch is lowered than the output frequency of the PWM signal output immediately before output, and the switch performs the cell balancing function in the overheating prevention state. It is to provide a battery management system for tunnel lights.

Another object of the present invention is to variably set the average temperature of the battery cells calculated by collecting temperature information of the battery cells sensed by the temperature sensor at predetermined time intervals as the reference temperature, so that the switch is set to prevent overheating. It is to provide a battery management system for tunnel lights that performs a balancing function.

In order to achieve the object of the present invention as described above, the battery management system for a tunnel light according to the present invention is composed of a rectifier that converts commercial AC power into a predetermined DC voltage and a plurality of battery cells that charge the power from the rectifier. battery pack; at least one temperature sensor connected to at least one or more battery cells constituting the battery pack in a one-to-one correspondence to sense a temperature of the corresponding battery cell; It is connected to the at least one battery cell in a one-to-one correspondence and operates on/off by the PWM signal output from the control unit to reduce the charge state imbalance between the battery cells and perform a battery cell balancing function to maintain voltage uniformity at least one or more switches; and collects the temperature information of the battery cells sensed by the temperature sensor at a predetermined time interval, and sets the temperature of the collected battery cells automatically to prevent overheating during on/off operation of a switch corresponding to the battery cell If it is higher than the reference temperature, the output frequency of the PWM signal corresponding to the switch is set immediately by referring to the temperature difference/frequency table prepared in advance to prevent overheating based on the temperature difference between the collected battery cell temperature and the reference temperature. It is characterized in that it comprises a; by outputting lower than the output frequency of the PWM signal output to the switch to perform the above-described cell balancing function in an overheating prevention state.

In the battery management system for a tunnel light according to the present invention, the control unit collects the temperature information of the battery cells sensed by the temperature sensor at a predetermined time interval and variably sets the average temperature of the battery cells calculated as the reference temperature. characterized.

In the battery management system for tunnel lights according to the present invention, the control unit lowers the output frequency of the PWM signal and outputs the output frequency of the PWM signal corresponding to the switch when the temperature of the collected battery cells is less than the reference temperature. It is characterized in that it is output by raising the output frequency of the PWM signal output immediately before.

In the battery management system for tunnel lights according to the present invention, the control unit lowers the output frequency of the PWM signal and outputs the collected battery cell temperature to prevent overheating during on/off operation of the switch corresponding to the battery cell. If it is higher than the reference temperature set in advance for It is characterized in that the output is adjusted by adjusting the ratio.

In the battery management system for a tunnel light according to the present invention, the control unit adjusts the on/off duty ratio of the PWM signal and outputs the PWM signal, and then, if the temperature of the collected battery cells is less than the reference temperature, the PWM signal corresponding to the switch It is characterized in that it is output by adjusting the on/off duty ratio of the PWM signal to the on/off duty ratio of the immediately outputted PWM signal.

In the battery management system for tunnel lights according to the present invention, the control unit adjusts and outputs the on/off duty ratio of the PWM signal, and then, if the temperature of the collected battery cells is equal to or greater than the reference temperature, the control unit sends an alarm to the corresponding switch. It is characterized by outputting an overheating alarm.

The present invention outputs the output frequency of the PWM signal corresponding to the switch immediately before referring to the temperature difference/frequency table prepared in advance to prevent overheating during the on/off operation of the battery cell of the battery management system for tunnel lights and the corresponding switch. By outputting one PWM signal lower than the output frequency, the switch performs the cell balancing function in the overheat prevention state, so the noise component is The voltage and current generation is reduced and, as a result, the voltage and current of this noise component prevents overheating of the switch (eg FET) and other circuitry (eg capacitors, etc.) around it, thereby causing failure of the battery management system. can prevent

The present invention variably sets the average temperature of the battery cells calculated by collecting temperature information of each battery cell sensed by a temperature sensor corresponding to at least one battery cell one-to-one at a predetermined time interval as a reference temperature, and the corresponding switch Since the battery pack performs the above-described cell balancing function in the overheating prevention state, the temperature of the battery pack, which is composed of at least one battery cell and operates for charging and discharging, can be maintained at the above-described average temperature of the battery cells, and as a result, the battery pack itself is overheated can also be prevented.

1 is a block diagram showing the configuration of a battery management system for a tunnel light according to the present invention.
2 to 3 are flowcharts for explaining the operation of the battery management system for a tunnel light according to the present invention.
4 is an embodiment showing a temperature difference/frequency table and a temperature difference/duty ratio table according to the present invention.

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

Referring to FIG. 1 , the battery management system 100 for a tunnel light according to the present invention includes at least one temperature sensor 110 , at least one switch 120 , a control unit 130 , and an alarm unit 140 . do.

The temperature sensor 110 is connected in a one-to-one correspondence with at least one battery cell 110a constituting the charging/discharging battery pack 100a to sense the temperature of the corresponding battery cell 110a.

The switch 120 is connected to the at least one or more battery cells 110a in a one-to-one correspondence and operates on/off by the PWM signal output from the control unit 130 to reduce the charge state imbalance between the battery cells 110a. It performs a battery cell balancing function to reduce and maintain voltage uniformity.

As the switch 120, any switch device that operates on/off by a PWN signal may be used, and it is preferable to use a voltage/current control switch device such as an FET.

The controller 130 collects the temperature information of the battery cell 110a sensed by the temperature sensor 110 at predetermined time intervals.

If the temperature of the collected battery cell 110a is higher than a reference temperature that is automatically set variably to prevent overheating during the on/off operation of the switch 120 corresponding to the battery cell 110a, the collected Based on the temperature difference between the temperature of the battery cell 110a and the reference temperature, the output frequency of the PWM signal corresponding to the switch 120 is set immediately before the temperature difference/frequency table prepared in advance to prevent overheating. The output frequency is lower than the output frequency of the output PWM signal so that the corresponding switch 120 performs the cell balancing function in an overheating prevention state.

The controller 130 variably sets the average temperature of the battery cells calculated by collecting the temperature information of the battery cells 110a sensed by the temperature sensor 110 at predetermined time intervals as the reference temperature.

The control unit 130 lowers the output frequency of the PWM signal and outputs, and then outputs the output frequency of the PWM signal corresponding to the switch 120 immediately before if the temperature of the collected battery cell 110a is less than the reference temperature. The output frequency of one PWM signal is raised again and output.

The control unit 130 lowers the output frequency of the PWM signal and outputs it, and then sets the collected temperature of the battery cell 110a in advance to prevent overheating during the on/off operation of the switch corresponding to the battery cell 110a. If it is higher than one reference temperature, the on/off duty of the PWM signal with reference to the temperature difference/duty ratio table prepared in advance to prevent overheating based on the temperature difference between the collected temperature of the corresponding battery cell 110a and the reference temperature Output by adjusting the ratio.

After the control unit 130 adjusts the on/off duty ratio of the PWM signal and outputs it, if the temperature of the collected battery cell 110a is less than the reference temperature, the on/off duty ratio of the PWM signal corresponding to the switch 120 is turned on/off. The off duty ratio is again adjusted to the on/off duty ratio of the PWM signal output immediately before outputting, and at the same time, the output frequency of the PWM signal corresponding to the switch 120 is raised again to the output frequency of the PWM signal output immediately before output. do.

After the control unit 130 adjusts the on/off duty ratio of the PWM signal and outputs it, if the temperature of the collected battery cell 110a is equal to or higher than the reference temperature, the control unit 130 controls the corresponding switch 120 through the alarm unit 140 . Outputs an overheating alarm.

The alarm unit 140 outputs an overheating alarm in a manner such as a voice alarm, a voice message, turning on a warning lamp, flashing a warning lamp, and the like.

The battery management system 100 for a tunnel light according to the present invention configured as described above operates as follows.

2 to 3 are flowcharts illustrating the operation of the battery management system 100 for a tunnel light according to the present invention.

2 to 3 , the battery management system 100 for a tunnel light according to the present invention is a switch connected to at least one battery cell 110a in a one-to-one correspondence with at least one battery cell 110a by a PWM signal output from the control unit 130 . 120 is turned on/off to reduce the state of charge imbalance between the battery cells 110a and performs a battery cell balancing function to maintain voltage uniformity (S100).

As described above, while the switch 120 connected in a one-to-one correspondence with at least one battery cell 110a operates on/off to perform the above-described battery cell balancing function, the controller 130 controls at least one battery cell ( 110a) and the temperature information of the battery cell 110a sensed by the temperature sensor 110 connected in a one-to-one correspondence is collected at a predetermined time interval (S110).

In an embodiment of the present invention, the time interval for collecting the temperature information of the battery cell 110a may depend on the number of at least one or more battery cells 110a constituting the battery pack 100a for charging/discharging operation. It is preferable to set it in seconds or minutes.

After the temperature information of the battery cell 110a is collected at a predetermined time interval as described above, the controller 130 determines the temperature of the collected battery cell 110a of the switch 120 corresponding to the corresponding battery cell 110a. It is determined whether the reference temperature is higher than the reference temperature that is set automatically to prevent overheating during the on/off operation (S120).

At this time, the control unit 130 collects temperature information of each battery cell 110a sensed by the temperature sensor 110 corresponding to at least one battery cell 110a one-to-one at a predetermined time interval and calculates it. By variably setting the average temperature of one battery cell as the reference temperature, the switch 120 performs the cell balancing function in an overheating prevention state.

In this way, when the control unit 130 variably sets the average temperature of the battery cells calculated as described above as the reference temperature and the switch 120 performs the cell balancing function in the overheat prevention state, at least one or more battery cells ( 110a), the temperature of the battery pack 100a for charging and discharging can be maintained at the above-described average temperature of the battery cells, and as a result, overheating of the battery pack 100a itself can be prevented.

If, in the process S120, the temperature of the collected battery cell 110a is higher than the reference temperature set automatically to prevent overheating during the on/off operation of the switch 120 corresponding to the battery cell 110a When it is determined, the control unit 130 refers to the temperature difference/frequency table prepared in advance to prevent overheating based on the temperature difference between the collected temperature of the battery cell 110a and the reference temperature, and the corresponding switch 120. The output frequency of the PWM signal corresponding to the output frequency is lower than the output frequency of the PWM signal output immediately before output (S130).

At this time, it is preferable that the on/off duty ratio of the PWM signal output immediately before corresponding to the switch 120 and the PWM signal output by lowering the output frequency remain the same without changing.

For reference, in FIG. 4, the collected temperature (°C) of the corresponding battery cell 110a (eg, #1 or #2, ..., or #n) and the reference temperature (variably set as the average battery cell temperature as described above) ℃) (eg, #1 or #2, …, or #n) and the temperature difference (℃) (eg, #1 or #2, …, or #n) based on the output frequency set in advance to prevent overheating A temperature difference/frequency table indicating (KHz) (eg, #1 or #2, ..., or #n) is illustrated.

For example, as shown in FIG. 4 , if the collected temperature of the corresponding battery cell 110a is #1°C, the reference temperature variably set as the average battery cell temperature is #1°C, and the temperature difference between the two is #1°C, The control unit 130 lowers the output frequency of the PWM signal corresponding to the switch 120 lower than the output frequency of the PWM signal output immediately before and outputs it at a frequency of #1KHz.

As described above, in the process S130, the control unit 130 lowers the output frequency of the PWM signal corresponding to the switch 120 by referring to the temperature difference/frequency table lower than the output frequency of the PWM signal output immediately before. By doing so, when the corresponding switch 120 performs the cell balancing function in the overheat protection state, the voltage and current of the noise component are generated at the ON/OFF switching time of the corresponding switch 120 (eg, FET). is reduced, and as a result, the voltage and current of this noise component prevents overheating of the switch 120 (eg, FET) and other circuit elements (eg, capacitors, etc.) around it, thereby preventing the battery management system 100 from overheating. failure can be prevented.

As described in step S130, after the control unit 130 lowers the output frequency of the PWM signal and outputs it, the control unit 130 determines whether the temperature of the battery cell 110a collected thereafter is less than the reference temperature or It is determined whether the reference temperature is higher than the reference temperature (S140).

If, in the process S140, the temperature of the collected battery cells 110a is determined to be less than the reference temperature, the control unit 130 outputs the PWM output frequency of the PWM signal corresponding to the switch 120 immediately before. The output frequency of the signal is increased again (S150), and the process returns to the above-described S120 process.

On the other hand, if the temperature of the collected battery cell 110a is determined to be higher than or equal to the reference temperature in the step S140, the controller 130 controls the temperature between the collected temperature of the corresponding battery cell 110a and the reference temperature. Based on the difference, the on/off duty ratio of the PWM signal is adjusted and output with reference to the temperature difference/duty ratio table prepared in advance to prevent overheating (S160).

At this time, it is preferable to maintain the same output frequency without changing the PWM signal output immediately in response to the switch 120 and the PWM signal output by adjusting the on/off duty ratio.

For reference, in FIG. 4, the collected temperature (°C) of the corresponding battery cell 110a (eg, #1 or #2, ..., or #n) and the reference temperature (variably set as the average battery cell temperature as described above) ℃) (eg, #1 or #2, …, or #n) and a temperature difference (℃) (eg, #1 or #2, …, or #n) A temperature difference/duty ratio table indicating the off duty ratio (%) (eg, #1 or #2, ..., or #n) is exemplified.

For example, as shown in FIG. 4 , if the collected temperature of the corresponding battery cell 110a is #1°C, the reference temperature variably set as the average battery cell temperature is #1°C, and the temperature difference between the two is #1°C, The control unit 130 adjusts the on/off duty ratio of the PWM signal corresponding to the corresponding switch 120 to #1% and outputs it.

As described above, in the process S160, the control unit 130 refers to the temperature difference/duty ratio table and adjusts and outputs the on/off duty ratio of the PWM signal corresponding to the switch 120 to output the corresponding switch 120. When the cell balancing function is performed in the overheat protection state, the voltage and current generation of the noise component is reduced at the on/off switching time of the corresponding switch 120 (eg, FET), as a result By preventing overheating of the switch 120 (eg, FET) and other circuit elements (eg, capacitors, etc.) around the switch 120 (eg, FET) by the voltage and current of this noise component, the failure of the battery management system 100 can be prevented. .

As described in step S160, after the control unit 130 adjusts and outputs the on/off duty ratio of the PWM signal, the control unit 130 successively sets the temperature of the battery cell 110a collected thereafter as a reference. It is determined whether the temperature is lower than or higher than the reference temperature (S170).

If, in the process S170, the temperature of the collected battery cells 110a is determined to be less than the reference temperature, the control unit 130 adjusts the on/off duty ratio of the PWM signal corresponding to the corresponding switch 120 immediately before. The output is again adjusted to the on/off duty ratio of the output PWM signal (S180), and the process returns to the above-described S120 process.

On the other hand, if the temperature of the collected battery cells 110a is determined to be higher than or equal to the reference temperature in the process S170 , the control unit 130 outputs an overheat alarm for the corresponding switch 120 through the alarm unit 140 . do (S190).

In this case, it is preferable that the alarm unit 140 outputs an overheating alarm in a manner such as a voice alarm, a voice message, a warning lamp on, and a warning lamp blinking.

When the overheating alarm of the alarm unit 140 is output as described above, the manager or the user of the battery management system 100 for tunnel lights according to the present invention checks the battery pack 100a and, if necessary, a battery cell determined to be defective due to overheating. Maintenance work to replace (110a) with a new one will be performed.

The battery management system for tunnel lights according to the present invention described above is not limited to the above embodiments, and those of ordinary skill in the art to which the present invention pertains without departing from the gist of the present invention as claimed in the claims below It has the technical spirit to the extent that anyone can change it in various ways.

100: battery management system for tunnel lights
100a: battery pack 110: temperature sensor
110a: battery cell 120: switch
130: control unit 140: alarm unit

Claims (6)

a battery pack comprising a rectifying unit for converting commercial AC power into a predetermined DC voltage and a plurality of battery cells for charging power from the rectifying unit;
at least one temperature sensor connected to at least one or more battery cells constituting the battery pack in a one-to-one correspondence to sense a temperature of the corresponding battery cell;
It is connected to the at least one battery cell in a one-to-one correspondence and operates on/off by the PWM signal output from the control unit to reduce the unbalance of the state of charge between the battery cells and perform a battery cell balancing function to maintain voltage uniformity at least one or more switches; and
The temperature information of the battery cells sensed by the temperature sensor is collected at a predetermined time interval, and the temperature of the collected battery cells is automatically variably set to prevent overheating during the on/off operation of a switch corresponding to the battery cell. If the temperature is higher than the reference temperature, the output frequency of the PWM signal corresponding to the switch is set immediately before the temperature difference/frequency table prepared in advance to prevent overheating based on the temperature difference between the collected battery cell temperature and the reference temperature. a control unit for outputting a lower frequency than the output frequency of the output PWM signal so that the corresponding switch performs the cell balancing function in an overheating prevention state;
A battery management system for tunnel lights, characterized in that it comprises a. The battery for tunnel light according to claim 1, wherein the controller variably sets the average temperature of the battery cells calculated by collecting temperature information of the battery cells sensed by the temperature sensor at a predetermined time interval as the reference temperature. management system. The PWM signal according to claim 1, wherein the control unit lowers the output frequency of the PWM signal and outputs the PWM signal immediately before outputting the output frequency of the PWM signal corresponding to the switch if the temperature of the collected battery cells is less than the reference temperature. A battery management system for tunnel lights, characterized in that it is output by raising the output frequency again. The reference temperature according to claim 1, wherein the controller lowers the output frequency of the PWM signal and outputs it, and then sets the temperature of the collected battery cells to a preset reference temperature to prevent overheating during on/off operation of a switch corresponding to the battery cell. If it is abnormal, the on/off duty ratio of the PWM signal is adjusted and output by referring to the temperature difference/duty ratio table prepared in advance to prevent overheating based on the temperature difference between the collected temperature of the corresponding battery cell and the reference temperature. Battery management system for tunnel lights, characterized in that. The on/off duty ratio of the PWM signal corresponding to the switch according to claim 4, wherein the controller adjusts the on/off duty ratio of the PWM signal and outputs the output, and then when the temperature of the collected battery cells is less than the reference temperature A battery management system for tunnel lights, characterized in that the output is adjusted again by the on/off duty ratio of the PWM signal output immediately before. 5. The method of claim 4, wherein the control unit outputs an overheat alarm for the corresponding switch through the alarm unit when the temperature of the collected battery cells is greater than or equal to the reference temperature after adjusting and outputting the on/off duty ratio of the PWM signal. A battery management system for tunnel lights.

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