KR100940482B1 - Discharge state display device for rechargeable battery of remote control unit - Google Patents

Abstract

The present invention relates to a battery discharge state display device for a remote control unit that visually displays the discharge state of the battery mounted on the remote control unit, which is connected to the charging terminal of the battery mounted on the remote control unit such as a remote control vehicle and a helicopter. Connector; A controller connected to the connector and configured to extract and calculate a voltage per cell of the battery through the connector and generate an output signal corresponding to the voltage level of at least one cell; And display means connected to an output terminal of the controller and configured to visually display the voltage level of the one cell in response to an output signal output from the controller, wherein each cell of the battery is over-discharged or fully discharged. It has the effect of managing the battery more efficiently.

Remote control unit, battery, lithium polymer, controller, display means, over discharge, full discharge

Description

Discharge state display device for rechargeable battery of remote control unit

The present invention relates to a battery discharge state display device for a remote control unit, and more particularly, by visually displaying the cell voltage of the lithium polymer battery mounted on the remote control unit, it is possible to prevent over-discharge and full discharge of each cell. The present invention relates to a battery discharge status display device for a remote control unit.

In general, a remote control model car, a helicopter, and the like are units that operate by wirelessly receiving an RF (Radio Frequency) signal emitted from a remote transmitter. The remote control unit has a wide base as a hobby, and is also used as a simulation of a real car or a helicopter.

Such remote control units are equipped with a rechargeable battery as the power source. The battery mounted on the remote control unit is typically a lithium polymer battery. Lithium polymer batteries are lighter than conventional nickel-metal hydride batteries, have higher capacities in the same volume, and have the advantage of being easy to discharge, so they can be mounted in remote control units that need to reduce their weight as much as possible and require higher output. Very suitable.

However, the lithium polymer battery has a problem that it is difficult to manage overcharge and overdischarge. In general, to prevent overcharge and overdischarge of a lithium polymer battery, a protection circuit such as a PCM (Protect Circuit Module) is installed. However, since the remote control unit is usually equipped with a transmission, and instantaneous high discharge is required for the acceleration of the remote control unit, the above-described PCM cannot be mounted on the lithium polymer battery mounted in the remote control unit. Therefore, the lithium polymer battery mounted in the remote control unit requires careful management of overcharge and overdischarge.

Typically, the lithium polymer battery for the remote control unit has a structure in which two to eight cells are connected in series according to the output of the remote control unit. The rating per cell is approximately 3.7V, with four cells rated at 14.8V. A charger for a lithium polymer battery for a remote control unit, commonly referred to as a "balancer", balances the charging voltage per cell to prevent overcharging of each cell of the lithium polymer battery. For example, the balancer stops charging one of the four cells when it reaches 4.2V and charges only the remaining cells. That is, using a lithium polymer battery charger for the remote control unit is very useful as a solution to prevent overcharging of the battery mounted in the remote control unit.

However, there is no means for visually confirming the discharge state of the lithium polymer battery for the conventional remote control unit. Typically, the user arbitrarily determines the timing of recharging the lithium polymer according to the operation time of the remote control unit. As such, judging the discharge state of the lithium polymer battery by the user's sense often causes overcharging or complete discharge of the lithium polymer battery. If one cell of the lithium polymer battery is over discharged, the life of the cell is drastically reduced, which reduces the life of the entire battery pack even if the other cells are in a normal state. If one cell is in a fully discharged state, the cell becomes incapable of charging and may cause an unusable state of the battery pack even when other cells are in a normal state.

On the other hand, the product has been disclosed to prevent the over-discharge and full discharge of the lithium polymer battery by designing a function to cut-off the power when the battery is over-discharged to the electronic transmission mounted to the remote control unit. However, the cutoff function of the electronic transmission is for the output voltage of the battery pack as a whole, and it is impossible to check individual voltages for each cell. For example, even if the voltage of one cell drops below 2.8V, the cutoff function will not work if the voltages of the remaining cells remain at a high level. That is, judging whether the battery is over-discharged by the cut-off function in the electronic transmission may result in excessive use of the lithium polymer battery, and as a result, any cell of the lithium polymer battery may be easily over discharged or completely discharged. The risk is high.

The present invention has been proposed to solve the above problems, and is connected to the charging terminal of the battery mounted in the remote control unit to visually display the cell voltage of the battery, thereby preventing over-discharge or full discharge of each cell It is an object of the present invention to provide a battery discharge status display device for a remote control unit that can extend the service life of the battery and manage the battery more efficiently.

Battery discharge state display device for a remote control unit of the present invention for achieving the above object, the connector is connected to the charging terminal of the battery mounted in the remote control unit, such as remote control cars and helicopters; A controller connected to the connector and configured to extract and calculate a voltage per cell of the battery through the connector and generate an output signal corresponding to the voltage level of at least one cell; And display means connected to an output terminal of the controller and configured to visually display the voltage level of the one cell in response to an output signal output from the controller.

Preferably, the controller extracts the voltage of each cell of the battery and generates an output signal corresponding to the voltage level of the cell having the lowest voltage.

More preferably, the controller comprises a first monitoring mode for generating an output signal corresponding to the current voltage level of the cell, and a controller for monitoring the voltage fluctuation range of the cell to generate an output signal corresponding to the lowest voltage level. It has 2 monitoring modes.

In the present invention, the display means is a plurality of LEDs, it is preferable to display the cell voltage of the battery by selectively lighting or blinking at least one of the plurality of LEDs.

In the present invention, the battery mounted on the remote control unit may be a secondary battery of various methods, preferably a lithium polymer battery.

According to the battery discharge state display device for a remote control unit of the present invention, by displaying the cell voltage of the battery by the display means such as LED, the user can easily check the discharge state of the battery with the naked eye, and each cell of the battery is over It can be expected to extend the life of the battery by preventing it from being discharged or completely discharged, and it is effective to manage the battery more efficiently.

In addition, according to the present invention, by monitoring the cell with the lowest voltage level among the cells of the battery to display the cell voltage, there is an effect that can have a monitoring effect for all the cells.

In addition, according to the present invention, since the cell voltage of the battery tends to be momentarily reduced or increased due to a nonlinear load due to the characteristics of the remote control unit, the cell has a first monitoring mode in which the cell voltage of the battery is displayed as it is. By selectively driving the second monitoring mode that continuously monitors the voltage variation and continuously displays the lowest voltage level, there is an effect that the overdischarge of the battery can be more stably prevented.

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

1 is a perspective view showing a battery discharge state display device for a remote control unit of the present invention, Figure 2 is a circuit diagram showing a circuit configuration of the present invention, Figure 3 is a view showing an example of the display means lighting of the present invention.

First, referring to FIG. 1, an appearance configuration of a battery discharge state display device for a remote control unit according to the present invention will be described.

First, in the present invention, the "remote control unit" includes a model car and a helicopter that are remotely controlled. Such a remote control unit is typically equipped with a rechargeable battery 10 as shown in FIG. As shown in FIG. 1, the battery 10 is provided in a pack form, and a charging terminal 12 and an output terminal 14 are drawn out to one side. The charging terminal 12 is a terminal for charging the battery 10 and is connected to a "balancer" and the like which is a dedicated charging device for the battery for the remote control unit. The balancer is a device for equally charging each cell in the battery 10. The output terminal 14 is connected to a power mechanism in the remote control unit. For example, the output terminal 14 is connected to a power input terminal of an electronic transmission normally provided in the remote control unit. As shown in FIG. 1, an attachment means 16 such as Velcro is installed on the top surface of the battery 10. This attachment means 16 allows the battery 10 to be firmly positioned so that it does not flow in the remote control unit.

Battery discharge state display device for a remote control unit of the present invention is connected to the charging terminal 12 to display the discharge state of the battery (10). As shown in FIG. 1, the present invention includes a connector 20 connected to the charging terminal 12 at one end thereof, and a body 26 at the other end connected to the connector 20 via a cable 24. ) Is provided.

In this embodiment, the battery 10 is four cells connected in series, each cell is rated approximately 3.7V. More specifically, the battery 10 is a lithium polymer battery. Of course, the battery 10 may be composed of a secondary battery other than the lithium polymer battery. The charging terminal 12 of the battery 10 is composed of four pins, and the connector 20 has four connection pins 22 correspondingly. In addition, the upper surface of the body 26 is mounted so that the display means 28 for visually displaying the cell voltage of the battery 10 is exposed. In the present embodiment, the display means 28 is configured such that a plurality of, preferably six LEDs are arranged in a line. The LED has a very low power consumption, which is suitable for displaying the discharge state of the battery 10 while minimizing the power consumption of the battery 10. However, the LED is an embodiment of the display means 28, and of course, it can be replaced by another display device.

2 is a circuit diagram showing the circuit configuration of the battery discharge state display device for a remote control unit according to the present invention. Referring to this, a printed circuit board (PCB) (not shown) is embedded in the body 26, and a circuit configuration as shown in FIG. 2 is printed on the PCB. As shown, the cable drawn out from the connector 20 is five wires, one wire is grounded, and four wires are used to detect four cell voltages built in the battery 10.

As shown in FIG. 2, the display means 28, the constant voltage unit 30, the signal input unit 32, the controller 34, the setting unit 36, and the reset unit 38 are printed on the PCB.

The constant voltage unit 30 is for applying driving power to each component, and receives the power of the battery 10 from any one of terminals drawn from the connector 20. The constant voltage unit 30 converts power of the battery 10 into DC 5V and supplies power to the controller 34 and the display means 28, and includes a constant voltage regulator U1 and a smoothing capacitor C10. It is composed.

The signal input unit 32 is for detecting the voltage level of each cell in the battery 10 from the charge terminal 4 pin of the battery 10. The controller 34 distributes the voltage of each cell by a plurality of resistors. The signal is transmitted to the input terminal of the predetermined signal.

The controller 34 is a means for extracting and calculating the voltage signal of each cell input through the signal input unit 32, and generating an output signal corresponding to the voltage level of the lowest cell. Preferably, the controller 34 is a microprocessor having its own analog to digital converter (ADC). Therefore, the analog signal input from the signal input unit 32 is input to the PC0-PC3 terminal, which is an input terminal of the controller 34, is converted into a digital signal in the controller 34 and processed.

More preferably, the controller 34 has two monitoring modes. The monitoring mode of the controller 34 is set by the setting unit 36. For example, when the connector 20 of the present invention is connected to the charging terminal 12 of the battery 10, the LEDs of the first and second rows constituting the display means 34 are alternately lit. When the connection of the connector 20 is released when the LEDs of the first row are turned on, the input power of the setting unit 36 is cut off and the controller 34 is set to the first monitoring mode. Similarly, if the connector 20 is released when the LEDs in the second row are turned on, the controller 34 is set to the second monitoring mode.

On the other hand, the reset unit 38 resets the last display value when the display device of the present invention is separated from the battery 10. Even if the display value is reset by the reset unit 38, the setter 36 Setting value is maintained.

First, in the first monitoring mode, the controller 34 outputs an output signal corresponding to the current voltage level of the cell having the lowest voltage among the cells of the battery 10 as it is. At this time, the display means 28 displays the voltage of the corresponding cell in stages. The cell voltage display method of the display means 28 will be described later.

In the second monitoring mode, the controller 34 monitors the voltage fluctuation range of the cell and generates an output signal corresponding to the lowest voltage level. For example, if the cell voltage drops momentarily to 3.0V and then returns to about 3.4V, the first monitoring mode displays 3.4V which is the current voltage, while the second monitoring mode displays the lowest voltage level of 3.0V. .

Normally, the remote control unit uses an electronic transmission to achieve instantaneous acceleration and deceleration, so the load is nonlinear. Therefore, the voltage of each cell is increased or decreased instantaneously. For example, when the cell voltage is low, such instantaneous acceleration may sharply lower the cell voltage and cause over discharge. Therefore, in the second monitoring mode, the instantaneous cell voltage decrease is detected and the lower limit value is stored and displayed, thereby preventing overdischarging of the battery due to instantaneous acceleration and deceleration.

3 shows an example of lighting of the display means of the present invention. As shown, the display means 28 has various display modes. The display means 28 displays the voltage level of the cell in each of the display modes in a number of identifiable steps. The display method of the display means 28 is divided into a plurality of ways for the user to select a display method of a more convenient method. Preferably, the display means 28 has six display modes.

Also, in the present embodiment, the display means 28 has six LEDs arranged in a row, for the purpose of mutual identification, the LEDs of the fourth row in the first row are green LEDs, the LEDs of the fifth row are yellow LEDs, The LED is a red LED. The green LEDs in the first column and the fourth column are used to indicate that the cell voltage is normal, and the yellow LEDs in the fifth column and the red LEDs in the sixth column are mainly used to display when the cell voltage is close to overdischarge. Used.

In this embodiment, the display mode setting is made as follows. After the display device of the present invention is connected to the battery 10 as described above, the LEDs of the first row and the LEDs of the second row cross lit for a predetermined time (approximately 1.5 seconds), and then the step of setting the monitoring mode is over. The display mode setting step is started in which the LEDs in the sixth column are sequentially turned on from the LEDs in the first column. The display mode setting is set in such a manner that the connector 20 is disconnected from the battery 10 when the LEDs of each column are turned on, as in the monitoring mode setting step. If the display mode setting step is simply passed, it will be set to the first display mode. If both the monitoring mode setting step and the display mode setting step are just passed, the display device of the present invention is normally operated to switch to the step of displaying the discharge state of the battery 10.

Referring to Fig. 3, three display modes are shown. First, in the first display mode, the discharge state of the battery 10 is displayed in seven steps. When the cell voltage of the battery 10 is 4.0 V or more, the green LED of the first row and the red LED of the sixth row are lit together. As illustrated, when the cell voltage of the battery 10 is 3.8V to 3.9V, the green LED of the second column and the red LED of the sixth column are turned on together, and when the cell voltage is 3.6V to 3.7V, the third The green LED of the row and the red LED of the sixth row are lit together. When the cell voltage is 3.4V to 3.5V, the green LED of the fourth row and the red LED of the sixth row are lit together. When the cell voltage drops to 3.2V to 3.3V, the yellow LED of the fifth column and the red LED of the sixth column are lit together. Then, when the cell voltage drops to 3.0V to 3.1V, only the red LED of the sixth column is lit. If the cell voltage of the battery 10 falls below 3.0 V, although not shown, the yellow LEDs of the fifth row and the red LEDs of the sixth row cross lit to warn of the risk of overdischarge. As such, when the cell voltage drops below 3.0V, it means that the battery 10 must be recharged immediately. If the cell voltage falls below 2.8V, the cell may be fully discharged and may not be recharged.

As shown in FIG. 3, in the second display mode, the cell voltages are displayed in such a manner that the LEDs of the first to sixth columns are turned off step by step, and in the third display mode, the LEDs of two adjacent columns are sequentially turned on. Display the cell voltage in such a way that In both display modes, when the cell voltage drops from 3.0V to 3.1V, only the red LED of the sixth row is lit.When the cell voltage drops below 3.0V, the yellow LED of the fifth column and the red LED of the sixth column are lit. Warns of the risk of overdischarge.

Although not shown, the fourth to sixth display modes display the cell voltage in multiple stages in such a manner that LEDs in the same column as the first and third display modes periodically blink.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the technical field of the present invention without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

1 is a perspective view showing a battery discharge state display device for a remote control unit of the present invention;

2 is a circuit diagram showing a circuit configuration of the present invention.

3 is a view showing an example of lighting the display means of the present invention;

<Explanation of symbols for the main parts of the drawings>

10: battery 12: charging terminal

14: output terminal 16: attachment means

20: connector 22: connection pin

24: cable 26: body

28: display means 30: constant voltage portion

32: signal input unit 34: controller

36: setting unit 38: reset unit

Claims (5)

A connector 20 connected to a charging terminal 12 of a battery 10 mounted in a remote control unit such as a remote control vehicle and a helicopter; A controller (34) connected to the connector (20) for extracting and calculating the voltage per cell of the battery (10) through the connector (20) and generating an output signal corresponding to the voltage level of at least one cell; And And display means (28) connected to an output terminal of the controller (34) to visually display the voltage level of any one cell in response to an output signal output from the controller (34). 34) The battery discharge status display device for a remote control unit, characterized in that for extracting the voltage of each cell of the battery (10) to generate an output signal corresponding to the voltage level of the lowest cell. delete The method of claim 1, The controller 34 includes a first monitoring mode for generating an output signal corresponding to the current voltage level of the cell, and a second monitoring mode for monitoring the voltage fluctuation range of the cell and generating an output signal corresponding to the lowest voltage level. Battery discharge status display device for a remote control unit, characterized in that it has a mode. The method of claim 1, The display means 28 is a plurality of LEDs, the battery discharge status display for the remote control unit, characterized in that to display the cell voltage of the battery 10 by selectively lighting or blinking at least one of the plurality of LEDs Device. The method according to any one of claims 1, 3 or 4, The battery 10 is a battery discharge state display device for a remote control unit, characterized in that the lithium polymer battery.

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