KR102386225B1 - Remote controller with lithium ion capacitor - Google Patents

Abstract

According to the present invention, by using a lithium ion capacitor as an energy storage device, it is possible to have the advantages of a lithium ion secondary battery having a high voltage and high capacity and an electric double layer capacitor having a high output and withstand tens of thousands of cycles of charging and discharging. When the temperature of the device exceeds the threshold, charging is stopped, so that the lifespan of the energy storage device or performance degradation due to overheating can be prevented, and the remaining amount of the energy storage device exceeds a preset value In this case, it is possible to prevent the energy storage device from being overcharged and reducing its lifespan and performance by stopping the charging, and two energy storage devices are installed, and when the energy storage device in use is overheated or the remaining energy storage device By configuring to change the energy storage device used when the remaining amount of the battery differs by more than a certain value, the lifespan is increased compared to when a single energy storage device is used, and performance degradation due to overheating can be prevented. It is about a remote controller that can

Description

Remote controller with lithium ion capacitor

The present invention relates to a remote controller, and specifically, by using a lithium ion capacitor as an energy storage device, the charging speed and the lifespan of the energy storage device are extended, and the energy storage device is prevented from being overcharged or overheated during the charging process It relates to a remote controller capable of preventing the lifespan and performance degradation of storage devices.

In general, since a disposable battery is used in the remote controller, problems such as inconvenience due to battery replacement, economic loss due to purchase of a new battery, and malfunction of the locking device due to frequent opening and closing of the battery case occur.

In addition, since disposable batteries contain a large amount of heavy metals such as manganese, alkaline, nickel or cadmium and toxic substances harmful to the human body, there is a problem that serious environmental pollution occurs when the battery is disposed of.

To solve this problem, rechargeable secondary batteries have been developed.

However, rechargeable secondary batteries generate heat during charging, which causes problems such as malfunction, damage, and reduction in charging efficiency.

In order to solve this problem, Domestic Utility Model No. 10-1738846 (Title of the Invention: Overheated Battery Cooling and Charging Device and Method) was developed.

1 is a block diagram of the prior art.

The prior art 100 includes a temperature measuring unit 110 , a voltage measuring unit 120 , a battery charging unit 130 , a charging mode setting unit 140 , and a battery 150 .

The temperature measuring unit 110 measures the temperature of the battery 150 being charged. At this time, the temperature measuring unit 110 transmits the measured temperature of the battery 150 to the charging mode setting unit 140 .

The voltage measuring unit 120 measures the voltage of the battery 150 being charged. At this time, the voltage measuring unit 120 transmits the measured battery voltage to the battery charging unit 130 .

The charging mode setting unit 140 sets the cooling charging mode based on the battery temperature and the set temperature received from the temperature measuring unit 110 . At this time, the charging mode setting unit 140 sets the cooling charging mode when the temperature of the battery 150 is equal to or greater than a preset threshold temperature value.

When the battery charging unit 130 is set to the cooling charging mode by the charging mode setting unit 140 , the charging section pulse width is changed according to the temperature of the battery 150 .

That is, when the battery charging unit 130 is set to the cooling charging mode, when the temperature of the battery 150 increases, the pulse width of the charging section is decreased, and when the temperature of the battery 150 is decreased, the pulse width of the charging section is decreased. By increasing it, the battery 150 can be continuously charged without overheating.

In addition, when the voltage is greater than or equal to a preset threshold voltage, the battery charging unit 130 reduces the current in stages to charge the battery.

In the prior art 100 configured as described above, when the battery 150 is charged, the battery 150 is not overheated by adjusting the pulse width when the temperature of the battery 150 exceeds the threshold temperature value. Charging can be completed in the , and when the voltage rises above a certain amount, the charging speed of the battery is reduced.

However, since the prior art 100 configured in this way controls the charging speed through pulse width conversion when overheated, an additional complicated driving circuit is required, which causes a problem in that the size and cost of equipment increase, as well as power consumption will increase.

The present invention relates to a remote controller capable of increasing the charging speed and lifespan of an energy storage device by using a lithium ion capacitor as an energy storage device in order to solve this problem.

In addition, another solution to the present invention relates to a remote controller capable of preventing deterioration of the life and performance of the energy storage device due to overheating by stopping charging when the temperature of the energy storage device exceeds a threshold value.

Another object of the present invention relates to a remote controller capable of preventing the energy storage device from being overcharged, thereby preventing the lifespan and performance of the energy storage device from being deteriorated.

In addition, another solution to the present invention is to change the energy storage device to be used when two energy storage devices are installed, and when the energy storage device in use is overheated or when the remaining amount with the remaining energy storage device differs by more than a certain value It relates to a remote controller capable of not only increasing the lifespan compared to when a single energy storage device is used by being configured, but also preventing performance degradation caused by overheating.

The solution means of the present invention for solving the above problem is an input means operated by a user to receive information; output means for outputting a signal to the equipment based on the information input by the input means; a first energy storage device; a second energy storage device installed to be spaced apart from the first energy storage device; a temperature sensor for sensing temperatures of the first energy storage device and the second energy storage device; and a control unit stopping charging of the first energy storage device or the second energy storage device when the temperature sensed by the temperature sensor exceeds a preset threshold temperature value, wherein the control unit is configured to store the first energy a temperature measuring module for measuring the temperature of the device and the second energy storage device; a residual energy detection module configured to detect residual energy amounts of the first energy storage device and the second energy storage device; a charging control module for controlling charging of the first energy storage device and the second energy storage device based on information input from the temperature measurement module and the residual energy detection module; and an energy storage device selection module configured to select and use one of the first energy storage device and the second energy storage device, wherein the charging control module includes the first energy storage device or the second energy storage device a first determination module for outputting a charging stop signal of the corresponding energy storage device when the remaining energy of the storage device exceeds a preset threshold energy value; a second determination module for outputting a charging stop signal of the corresponding energy storage device when the temperature of the first energy storage device or the second energy storage device exceeds a preset threshold temperature value; and a final determination module for limiting charging of a corresponding energy storage device when a charging stop signal is output from the first determination module or the second determination module, wherein the energy storage device selection module 1) the temperature measurement module When the temperatures of the first energy storage device and the second energy storage device measured by When the temperature of any one of the first energy storage device and the second energy storage device exceeds a threshold temperature value, but the other temperature is below the threshold temperature value, an energy storage device having a temperature below the threshold temperature value is used It determines that it is possible and outputs a use signal of the corresponding energy storage device. 3) When the temperatures of the first energy storage device and the second energy storage device both exceed the threshold temperature value, an energy storage device having a lower temperature is used a first comparison module that determines that it is possible and outputs a use signal of the corresponding energy storage device; In the first comparison module, it is determined that both the first energy storage device and the second energy storage device can be used because the temperatures of the first energy storage device and the second energy storage device are both below a threshold temperature value. After calculating the difference between the residual energy of the first energy storage device and the second energy storage device detected by the residual energy detection module, 1) when the difference between the calculated residual amount is less than or equal to a preset value, Outputs a use signal of the energy storage device currently being used, and 2) when the calculated difference exceeds a preset value, the energy storage device of the first energy storage device and the second energy storage device has a larger remaining energy. a second comparison module for outputting a use signal; and an energy storage device determination module that determines to use the energy storage device outputted from the use signal from the first comparison module or the second comparison module.

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According to the present invention having the above problems and solutions, by using a lithium ion capacitor as an energy storage device, the advantages of a lithium ion secondary battery having a high voltage and a high capacity and an electric double layer capacitor having a high output that withstands charge and discharge of tens of thousands of cycles or more can have it together.

In addition, according to the present invention, when the temperature of the energy storage device exceeds a threshold value, charging is stopped, so that the lifespan of the energy storage device or performance degradation due to overheating can be prevented from being reduced.

In addition, according to the present invention, when the remaining amount of the energy storage device exceeds a preset value, it is possible to prevent the energy storage device from being overcharged and deterioration in life and performance by stopping charging.

In addition, according to the present invention, two energy storage devices are installed, and when the energy storage device in use is overheated or when the remaining amount of the energy storage device and the remaining energy storage device differ by more than a certain value, the energy storage device used is configured to be changed. Not only will the lifespan of the energy storage device be longer than when used, but also it will be possible to prevent performance degradation caused by overheating.

1 is an exploded perspective view of the prior art.
2 is a block diagram of the remote controller according to the first embodiment of the present invention.
3 is a block diagram of a control unit of FIG. 2 .
FIG. 4 is a block diagram of the charging control module of FIG. 3 .
5 is a block diagram of a remote controller according to a second embodiment of the present invention.
6 is a block diagram of a second control unit of FIG. 5 .
7 is a block diagram of the energy storage device selection module of FIG. 6 .

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

2 is a block diagram of the remote controller according to the first embodiment of the present invention.

As shown in FIG. 2 , the remote controller 1 of the first embodiment includes an input unit 11 , an output unit 12 , a receiving coil 13 , a first energy storage device 14 , and a temperature sensor 15 . and a control unit 16 .

The input unit 11 includes a plurality of buttons (not shown) or a touch panel, and is operated by a user, and the manipulated information is transmitted to the control unit 16 .

The output unit 12 outputs a signal to the equipment to be operated based on the information transmitted to the control unit 16 by the input unit 11 . In this case, infrared rays, ultrasonic waves, etc. are used as signals output from the remote controller 1 .

When the receiving coil 13 is in proximity to the charging device 200 to be described later, electromagnetic induced electrons begin to flow therein, and the first energy storage device 14 is charged by the flow of these electrons to store the first energy. Device 14 may be charged wirelessly.

At this time, in the present invention, the first energy storage device 14 is wirelessly charged by the charging device 200 in an electromagnetic induction method using a coil. It is not limited, and a magnetic revolution method or a wired charging method may be applied.

The first energy storage device 14 is installed inside the remote controller and is made of a lithium ion capacitor.

The lithium ion capacitor includes a housing, a negative electrode sheet made of a negative electrode current collector and a negative electrode active material, a positive electrode sheet formed of a positive electrode current collector and a positive electrode active material, a separator installed between the positive electrode sheet and the negative electrode sheet, and a housing inside It consists of an electrolyte that is injected and impregnates the negative electrode sheet and the positive electrode sheet.

At this time, the positive electrode is composed of a mixture of activated carbon (3% to 70%) and lithium compounds (LNCM, LNO, LTO, LNMO, etc.) (30% to 97%), and the negative electrode is graphite, hard carbon, soft carbon, carbon nanotube It is composed of at least any one or more of carbons such as.

In addition, the solute used in the electrolyte of the lithium ion capacitor of the present invention is not divided into a positive electrode and a negative electrode, and lithium perchlorate (LiClO4), hexafluoride, which is a solute capable of adsorbing and releasing lithium ions in addition to the electric double layer expression solute Lithium hexafluorophosphate (LiPF6), Lithium tetrafluoroborate (LiBF4), Lithium trifluoromethanesulfonate (LiCF3SO3, LiTFS), Lithium bis(trifluoromethanesulfonyl) )imide, LiN(CF3SO2)2, LiTFSI), and lithium bispentafluoroethanesulfonylimidium (Lithiumbis(pentafluoroethanesulfony)imide, LiN(SO2C2F5)2, LiBETI) is selected and mixed.

In addition, in the present invention, the separator is preferably one of glass fiber, PPS, PEEK nonwoven fabric, PP, and PE, or two or more of them are selected and laminated.

Since the lithium ion capacitor configured in this way has a low self-discharge voltage (SDV), the voltage is prevented from automatically dropping even when not operated for a long time. On the other hand, the previously developed electric double layer capacitor has a high self-discharge rate, so even when the remote controller is not operated, the voltage automatically drops, making it difficult to use in real life.

In addition, lithium-ion capacitors combine the advantages of lithium-ion batteries with high capacity and high-density energy with the advantages of electric double-layer capacitors with excellent output. has

In addition, in the case of a conventional secondary battery, it takes about 2 to 4 hours to charge, and the lifespan decreases as the charging speed increases. have an advantage

The temperature sensor 15 detects an internal temperature, and outputs the sensed temperature information to a temperature measurement module 163 to be described later.

The charging device 200 includes a transmission coil 201 therein.

The charging device 200 electromagnetically induces the receiving coil 13 inside the remote controller 1 by the transmitting coil 201 to charge the first energy storage device 14 .

When the remote controller 1 configured as described above is positioned adjacent to the charging device 200 , the receiving coil 13 is electromagnetically induced by the transmitting coil 201 , thereby charging the first energy storage device 14 . .

3 is a block diagram of the control unit of FIG. 2 .

As shown in FIG. 3 , the control unit 16 includes a control module 161 , a memory 162 , a temperature measurement module 163 , a residual energy detection module 164 , and a charging control module 165 .

The control module 161 is an OS (Operating System) of the control unit 16 , and controls each of the configuration modules 163 , 164 , and 165 .

The memory 162 stores a threshold temperature value and a threshold energy value.

The temperature measurement module 163 measures the temperature of the first energy storage device 14 , and outputs the measured temperature of the first energy storage device 14 to the charge control module 165 .

The remaining energy detection module 164 detects the remaining energy of the first energy storage device 14 and outputs it to the charging control module 165 .

The charging control module 165 controls the charging of the first energy storage device 14 based on information input from the temperature measuring module 163 and the remaining energy detecting module 164 .

FIG. 4 is a block diagram of the charging control module of FIG. 3 .

As shown in FIG. 4 , the charging control module 165 includes an input module 1651 , a first determination module 1652 , a second determination module 1653 , and a final determination module 1654 .

The input module 1651 receives the residual energy of the first energy storage device 14 from the residual energy detection module 164 , and receives the temperature of the first energy storage device 14 from the temperature measurement module 163 .

When the remaining energy of the first energy storage device 14 received through the input module 1651 is less than or equal to the threshold energy value stored in the memory 162 , the first determination module 1652 is configured to store the energy of the first energy storage device 14 . It is determined that charging is necessary and the second determination module 1653 is driven.

In addition, when the remaining energy of the first energy storage device 14 exceeds the threshold energy value, the first determination module 1652 determines that the first energy storage device 14 is overcharged and charges the first energy storage device 14 with the final determination module 1654 . Output a stop signal.

When the temperature of the first energy storage device 14 received through the input module 1651 is less than or equal to the threshold temperature value stored in the memory 162, the second determination module 1653 determines that it is a chargeable temperature and determines the final determination module ( 1654) to output a charging signal.

In addition, when the temperature of the first energy storage device 14 exceeds the threshold temperature value, the second determination module 1653 determines that the first energy storage device 14 is in an overheated state and sends the final determination module 1654 to the final determination module 1654 . Outputs a charging stop signal.

The final determination module 1654 causes the first energy storage device 14 to be charged when receiving a charging signal from the second determination module 1653, and from the first determination module 1652 or the second determination module 1653 When the charging stop signal is received, the first energy storage device 14 is prevented from being charged.

The charging control module 165 configured in this way prevents the first energy storage device 14 from being overheated or overcharged, thereby preventing the performance of the first energy storage device 14 from being deteriorated or the lifespan of the first energy storage device 14 from being reduced.

5 is a configuration diagram of a remote controller according to a second embodiment of the present invention, and FIG. 6 is a block diagram of the second control unit of FIG. 5 .

The remote controller 2 of FIG. 5 is a second embodiment of the present invention, and the input unit 21, the output unit 22, the receiving coil 23, the first energy storage device 24 of FIG. and a temperature sensor 25 , and further includes a second energy storage device 26 and a control unit 27 .

The second energy storage device 26 is made of a lithium ion capacitor like the first energy storage device 24 . In this case, the first energy storage device 24 and the second energy storage device 26 are installed to be spaced apart from each other to prevent heat generated during charging or use from being transmitted to each other.

In addition, since the first energy storage device 24 and the second energy storage device 26 are connected in parallel, charging and discharging are performed separately.

In addition, the control unit 27 is composed of the control module 271 of FIG. 3 described above, the memory 272, the temperature measurement module 273, the residual energy detection module 274, and the charge control module 275, and energy storage It further includes a device selection module (276).

7 is a block diagram of the energy storage device selection module of FIG. 6 .

The energy storage device selection module 276 includes a first comparison module 2761 , a second comparison module 2762 , and an energy storage device determination module 2763 .

The first comparison module 2761 1) stores both energy when the temperatures of the first energy storage device 24 and the second energy storage device 26 measured by the temperature measurement module 273 are both below the threshold temperature value It is determined that both the devices 24 and 26 are usable, and the second comparison module 2762 is driven, 2) the temperature of one of the first energy storage device 24 and the second energy storage device 26 is When the threshold temperature value is exceeded, it is determined that the energy storage device exceeding the threshold temperature value is unusable, and a use signal of the energy storage device less than the threshold temperature value is transmitted to the energy storage device determination module 2763 .

In addition, the first comparison module 2761 is configured to 3) use an energy storage device having a lower temperature when the temperatures of the first energy storage device 24 and the second energy storage device 26 both exceed the threshold temperature value. The use signal of the corresponding energy storage device is transmitted to the energy storage device determination module 2763 .

That is, when the temperatures of the first energy storage device 24 and the second energy storage device 26 are both below the threshold temperature value, the first comparison module 2761 determines that both energy storage devices can be used, and the second energy storage device 261 The comparison module 2762 is driven, but when one or more energy storage devices exceed the threshold temperature value, the energy storage device having a lower temperature is used by the energy storage device determination module 2763 .

The second comparison module 2762 compares the remaining energy amounts of the first energy storage device 24 and the second energy storage device 26 and, when the difference between the remaining energy amounts is less than or equal to a preset value, the energy storage device currently being used transmits the use signal of to the energy storage device determination module 2763, and when the difference in the remaining energy exceeds a preset value, the energy storage device with the larger remaining energy among the two energy storage devices 24 and 26 transmits the use signal of the energy storage device determination module 2763.

For example, when the remote controller 2 is using the first energy storage device 24 , the remaining energy of the first energy storage device 24 is 30% and the remaining energy of the second energy storage device 26 is 30%. When it is assumed that 35% and the preset value is 10%, the first energy storage device 24 is used because the difference in the remaining energy amount does not exceed 10% even if the energy remaining amount of the second energy storage device 26 is greater. do it Also, when the remaining amount of the first energy storage device 24 is reduced to 24%, the remote controller 2 uses the second energy storage device 26 by the energy storage device selection module 276 .

That is, the second comparison module 2762 uses an energy storage device with a larger amount of residual energy to periodically switch the charging/discharging of the two energy storage devices, but energy storage used only when the amount of residual energy differs by more than a certain value. By allowing the device to be switched, the energy storage used is prevented from constantly changing in a short period of time.

The energy storage device determination module 2763 is configured such that the energy storage device outputting the use signal from the first comparison module 2761 and the second comparison module 2762 among the two energy storage devices 24 and 26 is used. do.

The remote controller 2 of the second embodiment configured as described above uses the two energy storage devices 24 and 26 alternately to increase the lifespan compared to when one energy storage device is used, as well as to use one energy storage device. When the energy storage device is overheated, another energy storage device can be used, so that performance degradation due to overheating can be prevented.

1: Remote controller of the first embodiment 2: Remote controller of the second embodiment
11: input unit 12: output unit
13: receiving coil 14: first energy storage device
15: temperature sensor 16: control unit
200: charging device 201: transmitting coil

Claims (6)

delete delete delete an input means operated by a user to receive information;
output means for outputting a signal to the equipment based on the information input by the input means;
a first energy storage device;
a second energy storage device installed to be spaced apart from the first energy storage device;
a temperature sensor for sensing temperatures of the first energy storage device and the second energy storage device;
and a controller for stopping charging of the first energy storage device or the second energy storage device when the temperature sensed by the temperature sensor exceeds a preset threshold temperature value,
the control unit
a temperature measurement module for measuring temperatures of the first energy storage device and the second energy storage device;
a residual energy detection module configured to detect residual energy amounts of the first energy storage device and the second energy storage device;
a charging control module configured to control charging of the first energy storage device and the second energy storage device based on information input from the temperature measurement module and the residual energy detection module;
and an energy storage device selection module for selecting and using one of the first energy storage device and the second energy storage device,
The charging control module is
a first determination module for outputting a charging stop signal of the corresponding energy storage device when the remaining energy of the first energy storage device or the second energy storage device exceeds a preset threshold energy value;
a second determination module for outputting a charging stop signal of the corresponding energy storage device when the temperature of the first energy storage device or the second energy storage device exceeds a preset threshold temperature value;
and a final determination module for limiting charging of the corresponding energy storage device when a charging stop signal is output from the first determination module or the second determination module;
The energy storage device selection module is
1) When the temperatures of the first energy storage device and the second energy storage device measured by the temperature measurement module are both below a threshold temperature value, both the first energy storage device and the second energy storage device can be used 2) When the temperature of any one of the first energy storage device and the second energy storage device exceeds the threshold temperature value, but the other temperature is below the threshold temperature value, the temperature below the threshold temperature value It is determined that an energy storage device having an energy storage device can be used, and a use signal of the corresponding energy storage device is outputted. 3) When the temperatures of the first energy storage device and the second energy storage device both exceed the threshold temperature value, the temperature is a first comparison module that determines that a lower energy storage device can be used and outputs a use signal of the corresponding energy storage device;
In the first comparison module, it is determined that both the first energy storage device and the second energy storage device can be used because the temperatures of the first energy storage device and the second energy storage device are both below a threshold temperature value. After calculating the difference between the residual energy of the first energy storage device and the second energy storage device detected by the residual energy detection module, 1) when the difference between the calculated residual amount is less than or equal to a preset value, Outputs a use signal of the energy storage device currently being used, and 2) when the calculated difference exceeds a preset value, the energy storage device of the first energy storage device and the second energy storage device with a larger remaining energy a second comparison module for outputting a use signal;
and an energy storage device determination module for determining to use the energy storage device outputted from the use signal from the first comparison module or the second comparison module. delete delete

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