JP2016154110A - Battery and alarm presentation method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make a user indirectly recognize the content of an alarm for a battery by varying the output pattern of a voltage output from an output control unit.SOLUTION: A battery according to the present invention comprises: a battery module 12; an output control unit 14 for controlling an output voltage b from the battery module 12; and a control unit 16 for varying an output pattern of a voltage output from the output control unit 14 according to content indicated by an alarm without including an output terminal for outputting an alarm concerning the battery module 12 to a host apparatus.SELECTED DRAWING: Figure 1

Description

  According to an embodiment of the present invention, a battery capable of indirectly recognizing an alarm by a user by changing an output pattern of a voltage to be output even when the alarm output function is not provided. , And an alarm presentation method for a battery.

  Usually, batteries such as lead batteries and lithium-ion batteries prevent overcharging for safety as well as an output control unit consisting of a contactor and FET circuit for controlling the output voltage from the battery module. And a control unit for controlling the battery module so as to heat the heater at a low temperature or stop the operation at a high temperature.

  In the case of a lithium ion battery, when an event that should generate an alarm such as overcharge, low temperature, or high temperature occurs in the battery module, the control unit grasps it based on sensor information from the battery module. The control unit is also provided with an output terminal for monitoring control. The control unit determines whether or not an alarm is necessary based on the sensor information, and if it is determined that an alarm is necessary, the output terminal The alarm information is transmitted to the host device such as a display and a speaker through communication and contact information. As a result, the user can recognize the occurrence of the alarm and grasp the contents of the alarm by viewing and listening to the alarm information output from the host device.

  On the other hand, in the case of a lead battery, since the control unit is not provided with such an output terminal for a monitoring device, alarm information cannot be transmitted to a host device. Therefore, there is no host device for transmitting alarm information. It is possible to put an indicator on the battery module itself to alert the user, but in the case of a lead battery, the battery module is usually not installed where the user can easily see it, so it is effective. It is not a countermeasure.

JP 2005-346321 A JP 2000-83325 A JP 2013-537792 A

  In this way, in the case of a lead battery at present, even when an event that should cause an alarm as described above occurs, the user recognizes not only the content of the alarm but also that an event that should cause an alarm has occurred. I can't do it.

  Recently, even if a lead battery to which a lead battery module is normally applied is used, a lithium ion battery module is increasingly applied as an alternative to the lead battery module. As described above, when the lithium ion battery module is applied as an alternative to the lead battery module, the lead battery control unit is not provided with an output terminal for the monitoring device in the first place. As such, the user is still unable to recognize the event that should trigger an alarm that occurred in the replacement lithium ion battery module.

  The present invention has been made in view of such circumstances. For example, even when a control device does not have an output terminal for a monitoring device, such as a lead battery, according to the content of the alarm. An object of the present invention is to provide a battery capable of indirectly allowing the user to recognize the contents of the alarm by changing the output pattern of the voltage output from the output control unit, and an alarm presenting method for the battery. To do.

  The battery of the embodiment is not provided with a battery module, output control means for controlling the output voltage from the battery module, and an output terminal for outputting an alarm related to the battery module to the host device. Control means for changing the output pattern of the voltage output from the output control means in accordance with the content of the alarm.

  The battery of another embodiment is provided with a battery module, output control means for controlling the output voltage from the battery module, and an output terminal for outputting an alarm related to the battery module to a host device. And a control means for changing the voltage output from the output control means instead of transmitting the alarm to the host device.

  In Patent Document 1, in the battery output control method, the battery box further includes a temperature sensor and an output control unit, and the output control unit compares other cell temperatures with the temperature of its own battery cell. However, a technique is described in which when the difference from the cell temperature is equal to or higher than a predetermined temperature, an alarm signal is transmitted to the host device to notify the occurrence of an overheat state.

  Further, Patent Document 2 discloses an improvement in safety in a battery device and a battery state monitoring circuit that can calculate the remaining amount of a secondary battery such as a lithium ion secondary battery, and calculation of the remaining amount of the secondary battery. In order to improve accuracy, a battery state monitoring circuit and a switch element for charge / discharge current control are installed in a series or parallel connection of multiple lithium ion secondary batteries. The positive electrode of the secondary battery is an FET or the like. Connected to the configured switch element, the battery status monitoring circuit can control the on / off of the regulator output by the control signal, and the microcomputer monitors each battery voltage and discharge current of the secondary battery, and A technique for protecting a battery device by controlling on / off of a switch element according to the voltage or discharge current of a secondary battery is described.

  Further, Patent Document 3 describes a technique for generating a vibration signal that warns a user that a battery should not be recharged in a system, apparatus, and method for recharging the battery.

  However, any of Patent Documents 1 to 3 also discloses a technique for causing the user to indirectly recognize the contents of the alarm by changing the output pattern of the voltage output from the output control unit according to the contents of the alarm. I did not suggest.

It is a block diagram which shows the structural example of the battery to which the alarm presentation method of the 1st Embodiment of this invention was applied. It is a figure which shows the example of the output pattern according to a low temperature state. It is a figure which shows the example of the output pattern according to a high temperature state. It is a figure which shows the example of the output pattern according to the content of sensor information. It is a figure which shows another example of the output pattern according to the content of sensor information. It is a block diagram which shows the structural example of the battery to which the alarm presentation method of the 2nd Embodiment of this invention was applied. It is a block diagram which shows the structural example of the battery to which the alarm presentation method of the 3rd Embodiment of this invention was applied.

  Hereinafter, a battery to which an alarm presentation method according to an embodiment of the present invention is applied will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a block diagram illustrating a configuration example of a battery to which the alarm presenting method according to the first embodiment is applied.

  That is, the battery 10 includes a battery module 12, an output control unit 14, and a control unit 16.

  The battery module 12 includes a plurality of batteries connected in series or in parallel. In addition, various sensors are provided in order to grasp the state of the batteries, and these sensors output the acquired sensor information a to the control unit 16.

  The control unit 16 determines whether or not to issue an alarm based on the sensor information a. Note that the control unit 16 is not provided with an output terminal to the host device for the monitoring device for outputting an alarm or generating a sound according to the content of the alarm.

  Thus, there exists a lead battery as the battery 10 of the type in which the control part 16 is not provided with the output terminal for monitoring apparatuses. Therefore, a lead battery is suitable as a battery to which the alarm presenting method of the embodiment is applied, but the control unit 16 is not provided with an output terminal for a monitoring device even if it is other than a lead battery. This battery can be applied to any type of battery. For example, even in the case of a lead battery, the battery module 12 can be applied to a case where a lithium ion battery module is used as an alternative to a commonly used lead battery module.

  When such a control unit 16 determines that an alarm should be issued based on the sensor information a, the control unit 16 sends necessary control information f to the battery module 12 and outputs to the output control unit 14. The output pattern c corresponding to the alarm content is output to the output control unit 14.

  The output control unit 14 is a part that controls the output voltage b from the battery module 12 to the load device 20, and for example, a contactor or an FET circuit is applied. And when the output pattern c is sent from the control part 16, the output voltage b will be output to the load apparatus 20 according to the output pattern c.

  Thus, in the battery 10 of the embodiment, the control unit 16 is not provided with an output terminal for a monitoring device for outputting an alarm or generating a sound. By varying the output pattern c of the output voltage b from the control unit 14, the user is indirectly made aware of the contents of the alarm.

  As an example of an indirect alarm presentation method by the battery 10 having such a configuration, the battery 10 is applied as a power source of an electric vehicle, the battery module 12 includes a temperature sensor 18, and the output control unit 14 is used. In the case where the FET circuit is applied, a method of presenting a temperature abnormality alarm in the battery module 12 to the user at the time of cranking will be described as an example.

  The temperature sensor 18 measures the temperature of one or more batteries constituting the battery module 12 and outputs the measurement result to the control unit 16 as sensor information a. For this reason, a plurality of temperature sensors 18 may exist in the battery module 12, but only one temperature sensor 18 is typically shown in FIG.

  The control unit 16 receives the sensor information a from the temperature sensor 18 and determines whether the temperature of the battery module 12 is equal to or higher than a predetermined high temperature threshold or lower than a predetermined low temperature threshold. To do.

  When the controller 16 determines that the temperature of the battery module 12 is equal to or lower than a predetermined low temperature threshold value (low temperature state), the controller 16 causes the heater 19 provided in the battery module 12 to start heating. Control information f is sent. As a result, the heater 19 starts heating, and the temperature of the battery module 12 rises, so that the battery module 12 eventually exceeds the low temperature threshold and exits the low temperature state. Until then, the control unit 16 outputs an output pattern corresponding to the content of the alarm, that is, an output pattern c1 corresponding to the low temperature state, to the output control unit 14.

  On the other hand, when the control unit 16 determines that the temperature of the battery module 12 is equal to or higher than a predetermined high temperature threshold (high temperature state), the control information f is not sent to the battery module 12, but the output control unit 14 In contrast, an output pattern corresponding to the content of the alarm, that is, an output pattern c2 corresponding to the high temperature state is output.

  FIG. 2 is an example of the output pattern c1 corresponding to the low temperature state. An FET circuit is suitable as the output control unit 14 that outputs such an output pattern c1. When the control unit 16 determines that the temperature of the battery module 12 is equal to or lower than a predetermined low temperature threshold (low temperature state) based on the sensor information a by the temperature sensor 18 of the battery module 12, By heating, an output pattern c1 in which the voltage gradually increases until the time t1 when the temperature of the battery module 12 exceeds the low temperature threshold is output to the output control unit 14 (FET circuit).

  In response to this, the output control unit 14 (FET circuit) supplies an output voltage b (c1) according to an output pattern c1 as shown in FIG. 2 to the load device 20 (cell motor). As a result, the voltage of the load device 20 (cell motor) gradually increases according to the output pattern c1 until the time t1 when the temperature of the battery module 12 exceeds the low temperature threshold. As a result, the user feels that the engine starts to rotate from the cold and grease solid state, and the battery module 12 has cooled down indirectly. Become able to recognize.

  In the meantime, when the battery module 12 is heated by the heater 19 and the temperature rises and exits from the low temperature state at time t1, the output pattern c1 is not output from the control unit 16 to the output control unit 14. Thereafter, a constant voltage is supplied from the output control unit 14 (FET circuit) to the load device 20 (cell motor), and the load device 20 (cell motor) does not vibrate.

  On the other hand, FIG. 3 is an example of an output pattern c2 corresponding to a high temperature state. The output control unit 14 that outputs such an output pattern c2 is also preferably an FET circuit. When the control unit 16 determines that the temperature of the battery module 12 is equal to or higher than a predetermined high temperature threshold (high temperature state) based on the sensor information a by the temperature sensor 18 of the battery module 12, the battery module 12 The output pattern c2 that causes the voltage to oscillate in a sawtooth waveform is output to the output control unit 14 (FET circuit) until the time t2 when the temperature of 12 falls below the high temperature threshold. However, the engine is basically set to such a voltage level while vibrating.

  In response to this, the output control unit 14 (FET circuit) supplies an output voltage b (c2) according to an output pattern c2 as shown in FIG. 3 to the load device 20 (cell motor). As a result, in the load device 20 (cell motor), the voltage oscillates in a sawtooth waveform according to the output pattern c2 until the time t2 when the temperature of the battery module 12 falls below the high temperature threshold. Due to this vibration, the user recognizes that the battery 10 is overheated and rests the battery 10.

  If the battery 10 is rested, the temperature of the battery module 12 that is in the high temperature state decreases due to natural cooling during that time, so that the battery module 12 comes out of the high temperature state at time t2 and goes from the control unit 16 to the output control unit 14. Since the output pattern c2 is not output, after that, a constant voltage is supplied from the output control unit 14 (FET circuit) to the load device 20 (cell motor), and the load device 20 (cell motor) does not vibrate. Disappear.

  The above is a description of a method of indirectly presenting an alarm regarding the temperature state of the battery module 12 based on the sensor information a from the temperature sensor 18 provided in the battery module 12. The provided sensor is not limited to the temperature sensor 18. Various sensors other than the temperature sensor 18 are provided in the battery module 12, and the sensor information a obtained from these sensors is similarly output to the control unit 16, and the control unit 16 determines whether the alarm is necessary. If it is determined that it is necessary, by outputting various output patterns c corresponding to the contents of the alarm to the output control unit 14, not only the temperature state as described above but also, for example, overcharge state information of the battery module 12 It is also possible to indirectly present other arbitrary information such as

  Hereinafter, another example of the output pattern c will be described.

  FIG. 4 shows another example of the output pattern c output by the control unit 16 according to the content of the sensor information a. The control unit 16 requires an alarm according to the content of the sensor information a. If it is determined, the output pattern c for raising and lowering the voltage in a rectangular wave shape at a different frequency is output to the output control unit 14. A contactor is suitable as the output control unit 14 that outputs such an output pattern c.

  For example, when the control unit 16 determines that an alarm with high importance should be issued based on the content of the sensor information a, the voltage is changed at high frequency as shown in FIG. When it is determined that an alarm should be issued, the voltage is varied at a low frequency as shown in FIG. 4C, and when it is determined that an alarm with a medium importance level should be issued, the alarm shown in FIG. Thus, the output pattern c that varies the voltage at an intermediate frequency is output to the output control unit 14.

  FIG. 5 shows another example of the output pattern c. The control unit 16 raises and lowers the voltage in a rectangular wave shape at the same frequency regardless of the content of the sensor information a, but the content of the sensor information a. In response to this, an output pattern c that changes the ratio (d / T) of the time length d, which is a high voltage, to one period T of the rectangular wave, that is, the duty ratio, is output to the output control unit 14. A contactor is suitable as the output control unit 14 that outputs such an output pattern c.

  For example, in FIG. 5, the period T of the rectangular wave is the sum (T = d + e) of the time length d that is a high voltage and the time length e that is a low voltage. Then, for example, when the control unit 16 determines that an alarm with high importance should be issued, the voltage is changed with a high duty ratio as shown in FIG. 5A and an alarm with low importance should be issued. If it is determined, the voltage is varied with a low duty ratio as shown in FIG. 5C, and if it is determined that an alarm having a medium importance level should be issued, an intermediate as shown in FIG. An output pattern c that varies the voltage at a proper duty ratio is output to the output control unit 14.

  The output control unit 14 inputs the output voltage b according to these output patterns c to the load device 20.

  The output pattern c output from the control unit 16 to the output control unit 14 is, for example, from FIG. 4 (A) to FIG. 4 (B), and further from FIG. 4 (B) to FIG. If it changes to (C) or, for example, from FIG. 5 (A) to FIG. 5 (B), and further from FIG. 5 (B) to FIG. 5 (C), the user is as if the battery 10 It becomes possible to recognize that the state of is improving every moment.

  Conversely, the output pattern c output from the control unit 16 to the output control unit 14 is changed from, for example, FIG. 4C to FIG. 4B according to the contents of the sensor information a, and further to FIG. From FIG. 4A to FIG. 4A, or from FIG. 5C to FIG. 5B, and further from FIG. 5B to FIG. It becomes possible to recognize that the state of the battery 10 is deteriorating every moment.

  4 and 5 both show an output pattern c using a rectangular wave, it is also possible to use an output pattern c using a sine wave. In this case, for example, the importance of the alarm can be indirectly communicated to the user by changing the period of the sine wave. For example, by shortening the period of the sine wave as charging progresses, the overcharge state can be indirectly communicated to the user.

  Alternatively, a Morse code pattern uniquely corresponding to the alarm content may be determined in advance, and the control unit 16 may output the corresponding Morse signal pattern as an output pattern c according to the alarm content. As a result, the contents of the alarm can be indirectly communicated to the user.

  In the above description, the engine of an electric vehicle has been described as an example of the load device 20. However, the load device 20 is not limited to this, and can be any as long as the battery 10 is applicable. It may be a motor of a machine or a fan, or a flashlight. Even an electric vehicle may be a headlight, for example, instead of an engine.

  For example, when the load device 20 is a motor of an electric vacuum cleaner or a fan, the control unit 16 determines that an alarm should be issued based on sensor information (for example, a decrease in the charge amount) from a sensor (not shown). The output control unit 14 outputs an output pattern c that changes the number of revolutions of the motor within a range that does not hinder practical use according to the content of the alarm. Then, the output control unit 14 outputs the output voltage b (c) to the motor according to the output pattern c, and the user feels the change pattern of the rotation speed of the motor, whereby the content of the alarm (for example, charging) Can be recognized.

  For example, when the load device 20 is a light of an electric vehicle or a flashlight, the control unit 16 determines that an alarm should be issued based on sensor information (for example, a decrease in the charge amount) from a sensor (not shown). Then, an output pattern c is output to the output control unit 14 so as to change the brightness of the light within a range that does not hinder practical use according to the contents of the alarm. Then, the output control unit 14 outputs the output voltage b (c) to the light in accordance with the output pattern c, and the user feels the light / dark pattern of the light, so that the content of the alarm (for example, the reduction in the charge amount) is detected. Can be recognized.

  As described above, according to the battery 10 to which the alarm presentation method of the present embodiment is applied, for example, a lead battery, the control unit 16 does not have an output terminal for the monitoring device. However, by changing the output pattern of the voltage output from the output control unit 14 according to the content of the alarm, the user can indirectly recognize the content of the alarm.

(Second Embodiment)
FIG. 6 is a block diagram illustrating a configuration example of a battery to which the alarm presentation method according to the second embodiment is applied.

  Since the second embodiment is a modification of the first embodiment, only differences from the first embodiment will be described here, and descriptions of common contents will be omitted.

  That is, in the battery 10 ′ to which the alarm presenting method of the present embodiment is applied, when the control unit 16 determines that an alarm should be issued based on the sensor information a, the battery module 12 Necessary control information f is sent. In this case, the control unit 16 outputs the output pattern c corresponding to the content of the alarm to the output control unit 14 in the first embodiment. However, in the present embodiment, the control unit 16 responds to the content of the alarm. Instead of the output pattern c, the output fluctuation value d corresponding to the content of the alarm is output to the output control unit 14.

  As a result, the output control unit 14 adds or subtracts the output voltage b from the battery module 12 by the amount corresponding to the output fluctuation value d, and outputs the result to the host device 30 side. That is, (output voltage b−output fluctuation value d) or (output voltage b + output fluctuation value d) is output to the host device 30 side.

  The host device 30 includes a voltage fluctuation monitoring device 32, and the output from the output control unit 14 (output voltage b−output fluctuation value d) or (output voltage b + output fluctuation value d) is converted into a voltage fluctuation monitoring device. 32 receives.

  When the control unit 16 determines that an alarm should not be issued, the output fluctuation value d is not sent to the output control unit 14, so the voltage sent from the output control unit 14 to the voltage fluctuation monitoring device 32 is It becomes the output voltage b itself at the time of steady operation.

  However, when the control unit 16 determines that an alarm should be issued, the output fluctuation value d is sent to the output control unit 14, so the voltage sent from the output control unit 14 to the voltage fluctuation monitoring device 32 is The output voltage b is higher or lower than the output voltage b during steady operation by the output fluctuation value d.

  By monitoring such voltage fluctuation, the voltage fluctuation monitoring device 32 can grasp whether or not an event that should generate an alarm has occurred.

  In addition, by determining the correspondence between the contents of the alarm and the output fluctuation value d in advance, the voltage fluctuation monitoring device 32 monitors such a voltage fluctuation to generate an event that should generate an alarm. As well as grasping the content of alarms according to the direction of voltage fluctuation increase / decrease (for example, plus or minus), fluctuation amount, and combination of increase / decrease direction and fluctuation amount Is also possible.

(Third embodiment)
FIG. 7 is a block diagram illustrating a configuration example of a battery to which the alarm presentation method according to the third embodiment is applied.

  Since the third embodiment is also a modification of the first embodiment, only differences from the first embodiment will be described here, and descriptions of common contents will be omitted.

  That is, in the battery 11 to which the alarm presentation method of the present embodiment is applied, when the control unit 16 determines that an alarm should be issued based on the sensor information a, the output control unit 14 Send alarm information or monitor information e specifying the alarm contents.

  As a result, the output control unit 14 outputs the output voltage b from the battery module 12 and the alarm information or monitor information e from the control unit 16 to the host device 40 side.

  The transmission line from the output control unit 14 to the host device 40 is originally for transmitting power, but by applying a known PLC (power line communication) technique, alarm information or monitor information e Information can also be transmitted.

  The host device 40 includes a splitter 42, separates the output voltage b from the output control unit 14 from alarm information or monitor information e, outputs the output voltage b to the load device 20, and outputs alarm information or monitor information e. Is output to a monitor device 44 comprising a display or the like.

  The load device 20 performs the original operation by being supplied with the output voltage b in this manner, while the monitor device 44 displays alarm information or monitor information e from, for example, a display. As a result, the user can grasp the contents of the alarm.

  When analog processing is performed in the host device 40, FM modulation is applied to the output voltage b output from the output control unit 14 and alarm information or monitor information e, and further, a detector (not shown) is used. The output voltage b and the alarm information or the monitor information e may be separated.

  Furthermore, it is possible to identify the type of alarm according to the frequency of FM modulation, or to place alarm audio information during FM modulation.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

10, 10 ', 11 Battery, 12 Battery module, 14 Output control unit, 16 Control unit, 18 Temperature sensor, 19 Heater, 20 Load device, 30, 40 Host device, 32 Voltage fluctuation monitoring device, 42 Splitter, 44 Monitor apparatus

Claims (16)

A battery,
A battery module;
Output control means for controlling the output voltage from the battery module;
An output terminal for outputting an alarm related to the battery module to a host device is not provided, and a control unit that varies an output pattern of a voltage output from the output control unit according to the content of the alarm;
With battery.   The battery according to claim 1, wherein the control unit varies the output pattern by raising and lowering a voltage in a rectangular wave shape at different frequencies according to the content of the alarm.   The control means raises and lowers the voltage in the form of a rectangular wave at the same frequency regardless of the content of the alarm, but according to the content of the alarm, the length of time that is a high voltage for one period of the rectangular wave The battery according to claim 1, wherein the output pattern is varied by changing a ratio of the output.   The battery according to claim 1, wherein when the alarm indicates a high temperature state of the battery module, the output pattern is changed by raising and lowering a voltage in a sawtooth waveform.   The battery of claim 1, wherein if the alarm indicates a low temperature condition of the battery module, the output pattern is varied by gradually increasing the voltage.   The battery according to claim 1, wherein when the alarm indicates an overcharged state of the battery module, the output pattern is varied by raising and lowering a voltage in a sine wave shape.   The battery according to claim 1, wherein the control means varies the output pattern according to a Morse code pattern determined according to the content of the alarm. A battery,
A battery module;
Output control means for controlling the output voltage from the battery module;
An output terminal for outputting an alarm related to the battery module to a host device is not provided, and instead of transmitting the alarm to the host device, a control unit that varies the voltage output from the output control unit;
With battery.   The control means changes at least one of a fluctuation direction in which the voltage is fluctuated, a fluctuation amount, or a combination of the fluctuation direction and the fluctuation amount in accordance with the content of the alarm. The battery described in. A battery,
A battery module;
Output control means for controlling the output voltage from the battery module;
An output terminal for outputting an alarm related to the battery module to a host device is not provided, and alarm information corresponding to the content of the alarm is provided to the output control means, and control means for outputting to the output control means,
The output control means is a battery that outputs the output voltage to the host device and transmits the alarm information by PLC (power line communication).   The battery according to any one of claims 1 to 9, wherein the alarm indicates at least one of an overcharged state, a low temperature state, and a high temperature state of the battery module.   The battery according to claim 1, wherein the battery module is a lead battery module.   The battery according to any one of claims 1 to 11, wherein the battery is a lead battery, and the battery module is a lithium ion battery module applied as an alternative to a lead battery module. . An alarm notification method applied to a battery that does not have an output terminal for outputting an alarm related to a battery module to a host device,
An alarm notification method in which an alarm is indirectly notified by changing an output pattern of a voltage output from the battery module according to the content of the alarm. An alarm notification method applied to a battery that does not have an output terminal for outputting an alarm related to a battery module to a host device,
An alarm notification method that indirectly notifies an alarm by changing a value of a voltage output from the battery module instead of transmitting the alarm to the host device. An alarm notification method applied to a battery that does not have an output terminal for outputting an alarm related to a battery module to a host device,
An alarm notification method in which alarm information corresponding to the content of the alarm is transmitted to the host device by PLC (power line communication).

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