KR100493186B1 - Battery type identifying apparatus and digital camera therewith - Google Patents

Abstract

The battery type identification device according to the present invention includes a battery of a first type having a recognition terminal, a battery of a second type having two or more connected in series by a connection terminal, and any one of the recognition terminal and the connection terminal. A battery type identification device for identifying which type of battery is installed in a battery chamber among a third type of battery which is not provided, the first type recognition part, the second recognition part, the reference voltage supply part, And a recognition signal converter, an analog / digital converter, and a controller. The first recognition unit is electrically connected to the recognition terminal, and recognizes the first type of battery to generate a recognition signal. The second recognition unit is electrically connected to the connection terminal to recognize the second type of battery to generate a recognition signal. The reference voltage supply unit generates a reference voltage for converting the recognition signal. The recognition signal converter generates a conversion recognition signal by converting a recognition signal input from one of the first recognition unit and the second recognition unit by the reference voltage. The analog / digital converter receives the conversion recognition signal and generates a digital recognition signal. The controller receives the digital recognition signal to identify the type of battery. In the digital camera using various types of batteries, the controller accurately identifies the type of battery.

Description

Battery type identification apparatus and digital camera having the same {Battery type identifying apparatus and digital camera therewith}

The present invention relates to a battery type identification device and a digital camera having the same, and more particularly, in a portable electronic device such as a digital camera using several types of batteries, it is possible to accurately identify the type of battery by a hardware method. It relates to a battery type identification device and a digital camera having the same.

These days, batteries are becoming more and more diverse from year to year. More large, small and eco-friendly batteries have been developed and used. The packages are also diversified to meet the small and light trend of portable devices such as digital cameras.

In particular, four types of digital cameras on the market are mainly used, such as dedicated batteries (lithium ion batteries), nickel-hydrogen batteries, lithium batteries, and alkaline batteries. Among them, many cameras use exclusive batteries (lithium ion batteries) and nickel-hydrogen batteries. However, the alkaline battery can almost match the end voltage of the nickel-metal hydride battery and the battery, so that a camera using the nickel-metal hydride battery can be mixed with the alkaline battery. However, these four types of batteries are not easy to control because the range of voltage that can be used is different and the terminal voltage is different.

1 is a graph schematically showing a discharge curve of a battery according to a battery type.

Referring to the drawings, the battery has different types of compounds and different compounding ratios, so that the discharge curves are different even if they are discharged with the same current. As shown in the figure, the discharge characteristic of a battery generally drops rapidly during a brief instant during initial discharge and then draws a gentle curve from a certain point. Then at the end of its life, the voltage drops sharply. At this time, the capacity notation in the drawing shows an example, there may be a difference from the actual.

Therefore, portable electronic devices such as digital cameras, battery chargers, and the like mostly use certain types of batteries. That is, one of various types of batteries, such as a lithium ion battery, an alkaline battery, a nickel-metal hydride battery, or a lithium battery, which is a dedicated battery, is selected and used. This is because it is not easy to control various kinds of batteries in one way because the rated voltage and discharge characteristics are different for each battery. In addition, when the power supply control device is designed for any one type of battery, the use of another type of battery may lead to an error of determining that the battery is a low battery without using all of its lifespan.

In addition, as the battery is used, its characteristics such as voltage level vary. If the battery continues to use when the voltage drops, the voltage drops sharply until it can no longer handle the load. In addition, if the digital camera runs out of battery life during operation, the device may be destroyed due to malfunction. To prevent this, the camera must be protected by continuous battery checks. Especially, digital cameras consume high current, and the voltage drop rapidly varies from battery to battery. Therefore, it is necessary to accurately identify the type of battery used to ensure normal operation of the camera over the life of the battery.

For this purpose, Japanese Laid-Open Patent Publication No. 2000-010159 discloses a power supply control apparatus for a camera that can use a battery having various characteristics and can extend the life of the battery. The content described in the specification of the published patent is to be included in the specification of the present invention, a detailed description thereof will be omitted.

In the battery identification method using the power control apparatus of the patent application, the accumulated data is secured by using the difference in discharge characteristics of the lithium battery and the alkaline battery, and the difference between the no-load voltage and the load voltage, that is, the voltage drop amount, is obtained using the data. Each battery type is determined by software.

However, this method puts a heavy burden on the control device in software and requires a memory space where the accumulated data will reside. In addition, the dummy current is applied several times for accurate identification, which increases unnecessary current consumption and causes a time delay.

In addition, in order to use all four types of batteries, such as a lithium ion battery, an alkaline battery, a nickel-metal hydride battery, or a lithium battery, which are frequently used as a power source for a digital camera as in the present invention, There is a problem that it is necessary to accumulate more data, and even if a significant amount of data is secured, it is difficult to secure reliability, and it is difficult to secure a memory capable of storing data.

Therefore, there is a need for a simpler method of identifying all four types of batteries, such as lithium ion batteries, alkaline batteries, nickel-hydrogen batteries, or lithium batteries, which are frequently used as power sources for digital cameras.

The present invention is to solve the above problems, in a portable electronic device such as a digital camera using a plurality of batteries, a battery type identification device that can accurately identify the type of battery by a hardware method and having the same It is an object to provide a digital camera.

In order to achieve the above object, a battery type identification device according to the present invention includes a first type of battery having a recognition terminal, a second type of battery in which at least two or more are connected in series by a connection terminal, and A battery type identification device for identifying which type of battery is a battery mounted inside a battery chamber among a third type of battery in which neither the recognition terminal nor the connection terminal is provided, the first recognition unit and the second recognition unit; And a recognition unit, a reference voltage supply unit, a recognition signal converter, an analog / digital converter, and a controller.

The first recognition unit is electrically connected to the recognition terminal, and recognizes the first type of battery to generate a recognition signal. The second recognition unit is electrically connected to the connection terminal to recognize the second type of battery to generate a recognition signal. The reference voltage supply unit generates a reference voltage for converting the recognition signal. The recognition signal converter generates a conversion recognition signal by converting a recognition signal input from one of the first recognition unit and the second recognition unit by the reference voltage. The analog / digital converter receives the conversion recognition signal and generates a digital recognition signal. The controller receives the digital recognition signal and identifies a type of battery.

The battery type identification device according to the present invention can accurately identify the type of battery in a portable electronic device such as a digital camera using various types of batteries.

In this case, the analog / digital converter is preferably embedded in the controller.

Preferably, the first recognition portion and the second recognition portion are electrically insulated from the third type of battery.

A battery voltage detector for detecting a battery voltage and a second analog / digital converter for generating a digital battery voltage and inputting the battery voltage from the battery voltage detector to the controller; It is preferable to check whether a stop voltage is reached to stop the operation of the battery by receiving the input, and identify the type of the battery by receiving the digital recognition signal.

In this case, the second analog / digital converter is preferably embedded in the controller.

According to another aspect of the present invention, there is provided a battery type identification device comprising: a first type of battery having a recognition terminal; a second type of battery in which at least two are connected in series by a connection terminal; A battery type identification device for identifying which type of battery is a battery mounted in a battery chamber among a third type of battery in which none of the connection terminals is provided, the first recognition unit, the second recognition unit, and the reference And a voltage supply unit, a recognition signal conversion unit, and a control unit.

The first recognition unit is electrically connected to the recognition terminal to recognize the first type of battery to generate a first recognition signal. The second recognizing unit is electrically connected to the connection terminal to recognize the second type of battery to generate a second recognition signal. The reference voltage supply unit generates a reference voltage for converting the first recognition signal. The recognition signal converter generates a conversion recognition signal by converting the first recognition signal input from the first recognition unit by the reference voltage. The controller identifies the type of battery by receiving the conversion recognition signal and the second recognition signal through input terminals, respectively.

The apparatus further includes a battery voltage detector configured to detect a battery voltage, wherein the controller receives the conversion recognition signal and the second recognition signal through an input terminal, respectively, identify a type of battery, and convert the digital battery voltage into an analog / digital conversion terminal. It is preferable to check whether the stop voltage is reached to stop the operation of the battery received through the input.

A digital camera according to another aspect of the present invention is characterized by including a main body, a battery chamber, an opening and closing means, and a battery type identification device.

The battery chamber is formed inside the main body, and from the outside of one side of the main body, a first type of battery having a recognition terminal, a second type of battery having at least two connected in series, and the recognition One battery of a third type of battery which is not provided with a terminal is housed therein, and a first type of battery recognition means electrically connected to the recognition terminal is provided therein. The opening and closing means opens and closes the battery chamber, and a conductive connection terminal is formed at a portion in contact with the second type of battery. The battery type identification device, when the battery of the first type is mounted in the battery chamber, is electrically connected with the battery recognition means of the first type to identify the battery of the first type, and the battery of the second type is When mounted, the connector is electrically connected to identify the second type of battery, and when the third type of battery is mounted, the first type of battery recognition means and the connection terminal are not electrically connected. To identify the third type of battery.

The battery type identification device includes a first recognition unit, a second recognition unit, a reference voltage supply unit, a recognition signal converter, an analog / digital converter, and a controller.

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

2A to 2C are diagrams illustrating batteries to which a battery type identification device according to the present invention is applied, and are perspective views schematically showing lithium ion batteries, CR-V3 type lithium batteries, and alkaline / nickel hydrogen batteries, respectively.

Referring to the drawings, four types of batteries, such as lithium ion batteries (dedicated batteries), nickel-hydrogen batteries, lithium batteries, and alkaline batteries, which are used in currently available digital cameras, are illustrated. However, alkaline batteries and nickel-metal hydride batteries are almost the same in shape and size, and thus are not shown separately. In addition, the alkaline battery and the nickel-hydrogen battery can make the final voltage of the battery almost the same, so that they can be mixed with each other without any particular problem.

The batteries are respectively inserted into the battery chamber of the digital camera. Typically, one square lithium ion battery 21 that is a dedicated battery is used, one CR-V3 type lithium battery (hereinafter, lithium battery, 22) is used, or two AA type alkaline batteries or nickel Hydrogen cells (hereinafter, alkaline / nickel-metal hydride batteries) 23 are used in series.

Therefore, in the digital camera using the four kinds of batteries, the battery identification device according to the present invention identifies each battery type among three kinds of lithium ion batteries, lithium batteries, and alkaline / nickel hydrogen batteries.

FIG. 2A illustrates a lithium ion battery 21 used as a dedicated battery that can be recharged in a conventional digital camera, and includes a positive electrode terminal (+), a negative electrode terminal (−), and a recognition terminal 211. A recognition unit capable of recognizing the recognition terminal 211 is provided in a battery chamber inside the digital camera accommodating the power supply, and identifies whether the mounted battery is a lithium ion battery 11 which is a dedicated battery. In addition, a groove is formed in one side of the lithium ion battery 11 in the longitudinal direction in which the battery is inserted, thereby preventing the polarity from being inserted.

FIG. 2B shows a lithium battery 22 of the CR-V3 type, which has a positive terminal (+) and a negative terminal (−). However, the lithium battery 22 does not have a separate recognition terminal.

2C shows an alkaline / nickel-metal hydride battery 23. As an example used in the battery identification apparatus according to the present invention, two cylindrical batteries each having a positive terminal (+) and a negative terminal (−) are shown. It is inserted into a battery chamber (not shown) inside a digital camera which will be described later in directions having different polarities. At this time, the two batteries are connected in series by the connection terminal 231, the connection terminal 231 is preferably formed in the contact with the battery of the opening and closing means for opening and closing the battery chamber is inserted into the battery. .

In addition, each of the lithium ion battery 21, the lithium battery 22, and the alkaline / nickel-metal hydride battery 23 is inserted into and mounted in one battery chamber, and electrode terminals of each of the positive and negative electrodes are disposed in the battery chamber. It is desirable to be in contact with the same connection terminals formed.

If the type of battery mounted in the battery compartment can be accurately identified, the power control device can control the power level for each battery, and thus can extend the life of devices such as a battery and a camera. More stable operation. Therefore, since various batteries can be used in one electronic device, the battery can be freely selected, and the user's convenience can be further increased.

In the battery type identification device according to the present invention, one battery of one type of battery, two types of AA type batteries connected in series, and one type of battery of one type CR-V3 Is preferably mounted inside the battery chamber.

In particular, in the embodiments described below, the following batteries are used. That is, the first type of battery is a lithium ion battery, the second type of battery is an AA type alkaline battery or a nickel hydride battery (hereinafter, an alkaline / nickel hydrogen battery), and the third type of battery is a CR-V3 type lithium battery. It is a battery.

In addition, hereinafter, the battery type identification device used in the digital camera and a digital camera having the same will be described.

Therefore, in the battery chamber of the digital camera, one lithium ion battery 21, two AA type alkaline / nickel hydrogen batteries 23 connected in series, and one CR-V3 type lithium battery ( One of the batteries 22 is mounted.

In the battery type identification device according to the present invention, when the lithium ion battery 21 is mounted, the recognition terminal is electrically connected to identify a lithium ion battery, and when the alkaline / nickel hydrogen battery 23 is mounted, the connection is performed. The lithium battery 22 is electrically connected to a terminal to identify the alkaline / nickel-metal hydride battery. When the lithium battery 22 is mounted, the lithium battery is not electrically connected to both the recognition terminal and the connection terminal.

3 is a block diagram schematically illustrating a battery type identification device of the batteries of FIGS. 2A to 2C according to an exemplary embodiment of the present invention, and FIG. 4 further includes a battery voltage detection unit in the battery type identification device of FIG. 3. It is a block diagram schematically showing a battery type identification device.

Referring to the drawings, the battery type identification device 3 includes a lithium ion battery 21 having a recognition terminal 211 inside a battery compartment and an alkaline line in which at least two or more are connected in series by the connection terminal 231. A battery type identification device for mounting one of the nickel-metal hydride batteries 23 and the lithium batteries 22 and identifying the type of batteries to be mounted in the battery chamber, comprising: a first recognition unit 31, It is preferable to include the two recognition unit 32, the reference voltage supply unit 33, the recognition signal conversion unit 34, the analog / digital conversion unit 35, and the control unit 36.

The first recognition unit 31 is electrically connected to the recognition terminal 211 and recognizes the lithium ion battery 21 to generate a recognition signal. The second recognition unit 32 is electrically connected to the connection terminal 231 to recognize the alkaline / nickel-metal hydride battery 23 to generate a recognition signal. The reference voltage supply unit 33 generates a reference voltage for converting the recognition signal. The recognition signal converter 34 converts a recognition signal input from one of the first recognition unit 31 and the second recognition unit 32 by the reference voltage to generate a conversion recognition signal. The analog / digital converter 35 receives the conversion recognition signal and generates a digital recognition signal. The controller 36 receives the digital recognition signal and identifies a type of battery.

In this case, the analog / digital conversion unit 35 is preferably embedded in the control unit 36, and the first recognition unit 31 and the second recognition unit 32 are electrically connected to the lithium battery 22. It is preferred to be insulated.

According to the battery identification device according to the present invention as described above, since the type of battery used is accurately identified, the power control device performs power control at a level suitable for each battery, and thus the life of devices such as batteries and digital cameras. Can be extended, and the device can operate more stable. In addition, since various batteries can be used in one electronic device, the battery can be freely selected, thereby facilitating user convenience.

In this case, it is preferable that the analog / digital converter 35 is embedded in the controller 36. In this case, the controller 36 is provided with an analog / digital conversion terminal for receiving an analog signal and converting the signal into a digital signal internally, and the conversion recognition signal generated by the recognition signal conversion unit 34 is analog / Instead of going through the digital converter, the controller 36 is directly input through the analog-to-digital converter.

Therefore, since the device having the same function can be implemented without the need for a separate analog / digital converter, the battery type identification device will be simpler.

As shown in FIG. 2A, the lithium ion battery 21 is provided with a recognition terminal 211, and the first recognition unit 31 is electrically connected to the recognition terminal 211 so that the lithium terminal is connected to the lithium terminal from the recognition terminal 211. A recognition signal for recognizing an ion battery is generated.

As illustrated in FIG. 2C, the alkaline battery or the nickel-hydrogen battery 23 is connected in series by at least two or more batteries 23 by a connection terminal 231. The second recognition unit 32 is electrically connected to the connection terminal 231 to recognize the alkaline battery and the nickel metal hydride battery from the connection terminal 231 to generate a recognition signal.

In addition, the second recognizing unit 32 is electrically insulated from the lithium battery 22 so that the second recognizing unit 32 does not recognize the electrical signal from the connection terminal 231.

Therefore, when the lithium ion battery 21 is mounted, the first recognition unit 31 detects an electrical signal from the recognition terminal 211 of the lithium ion battery 21 and transmits the signal through the recognition signal conversion unit 34. By inputting the converted recognition signal to the control unit 36 by conversion, it is possible to identify that the mounted battery is the lithium ion battery 21.

In addition, when the alkaline battery or the nickel-metal hydride battery 23 is mounted, the second recognition unit 32 detects an electrical signal from the connection terminal 231 and converts the signal through the recognition signal conversion unit 34 to control the control unit ( By inputting the recognition signal converted into 36, it is possible to identify that the mounted battery is an alkaline battery or a nickel metal hydride battery 23.

In addition, when the lithium battery 22 is mounted, the electric signal cannot be detected from each of the first recognizing unit 31 and the second recognizing unit 32, and the recognition signal converting unit 34 detects a signal for which no electric signal is detected. By converting the signal through the input signal input to the control unit 36, it is possible to identify that the mounted battery is the lithium battery 22.

As shown in FIG. 4, the battery type identification device 4 preferably further includes a battery voltage detector 37 and a second analog / digital converter 38.

The battery voltage detector 37 detects a battery voltage. The second analog-to-digital converter 38 receives a battery voltage from the battery voltage detector and generates a digital battery voltage and inputs it to the controller.

In this case, the control unit 36 receives the digital battery voltage and checks whether the stop voltage for stopping the operation of the battery is reached, and receives the digital recognition signal to identify the type of battery.

In addition, it is possible to protect the device such as a digital camera by detecting the battery voltage and checking whether the stop voltage is reached and stopping the operation of the battery in advance before reaching the final voltage. In other words, if the digital camera reaches the end voltage of the battery during operation and reaches the end of battery life, the device may be destroyed due to malfunction.By considering the safety factor, the stop voltage is set slightly higher than the end voltage, Once reached, the battery can be shut down to protect the device.

In this case, the analog / digital converter 35 and the second analog / digital converter 38 are preferably embedded in the controller 36. In this case, the controller 36 is provided with an analog / digital conversion terminal for receiving an analog signal and converting the signal into a digital signal internally, and the conversion recognition signal generated by the recognition signal conversion unit 34 is analog / Instead of going through the digital converter, the controller 36 is directly input through the analog-to-digital converter. This is because, in general, a microcomputer used as a control unit has a built-in analog / digital conversion terminal (A / D). Therefore, using this, there is no need to use a separate analog / digital converter.

Therefore, since the device having the same function can be implemented without the need for a separate analog / digital converter, the battery type identification device will be simpler.

FIG. 5 is a circuit diagram schematically illustrating a battery identification device when four batteries are mounted, as a specific embodiment of the battery type identification device of FIG. 3.

Referring to the drawings, the same components as those of the battery type identifiers 3 and 4 shown in FIGS. 3 and 4 of the battery type identifier 5 according to the present embodiment use the same reference numerals as they have the same function. The detailed description thereof will be omitted.

The battery type identification device 5 according to the present invention includes a first recognition unit 31, a second recognition unit 32, a reference voltage supply unit 33, a recognition signal conversion unit 34, and a battery voltage detection unit. It is preferable to include 37 and the control unit 36.

In this case, the controller 36 is provided with an analog / digital conversion terminal (A / D) for each of the recognition signal for detecting the battery voltage and the battery type, and the battery type identification device shown in FIGS. The analog / digital converting unit 35 and the second analog / digital converting unit 38 of 3 and 4 are omitted.

Accordingly, the detected battery voltage and the converted recognition signal of the recognition signal detected by the first recognition unit 31 and the second recognition unit 32 are directly input to the controller 36 without passing through the analog / digital conversion unit.

While receiving the battery voltage and the conversion recognition signal from the analog / digital conversion terminal (A / D) of the control unit 36, the analog signal is converted into a digital signal from the digital signals converted in the control unit 36, The battery operation may be determined according to the battery voltage, and the battery type may be identified according to the conversion recognition signal.

The battery type identification device 5 according to the present embodiment is a battery type identification device for identifying each of the lithium ion battery 21, the lithium battery 22, and the alkaline / nickel hydrogen battery 23. For example, a recognition signal detected by the first recognition unit 31 and the second recognition unit 32 varies according to the type of battery inserted into the digital camera battery room and mounted from the recognition signal. Identify the type of battery.

The lithium ion battery 21 is provided with a recognition terminal 211, and identifies the lithium ion battery 21 from the first recognition unit 31 electrically connected to the recognition terminal 211.

The alkaline / nickel-metal hydride battery 23 is provided with a connection terminal 231, and identifies the alkaline / nickel-metal hydride battery 23 from the second recognition unit 32 electrically connected to the connection terminal 231.

In the lithium battery 22, neither the recognition terminal 211 nor the connection terminal 231 is provided, so that the first recognition unit 31 and the second recognition unit 32 are electrically insulated and electrically insulated. The recognized signal is input, and the lithium battery 22 is identified.

When the lithium ion battery 21 is mounted, the first recognition unit 31 is electrically connected to the recognition terminal 211 and receives a recognition signal through the lithium ion battery test line LI_CHK. 32 is electrically connected to the connection terminal 231 when the alkaline / nickel hydrogen battery 23 is mounted, and receives a recognition signal through the alkaline / nickel hydrogen battery test line ALK_CHK.

In the drawing, a first switch SW1 for selecting an input from the positive terminal (+) of each battery and a second switch SW2 for selecting an input from the first recognition unit 31 and the second recognition unit 32. ) Is shown. However, the switches SW1 and SW2 are not actual switches to be arbitrarily selected, but are intended to show that each input line to be connected varies according to the type of battery to be mounted. In addition, the cathodes of the cells are each electrically connected to ground.

In the present embodiment, the reference voltage supply unit 33 supplies 3.3V as a reference voltage, and the recognition signal converter 34 connects a pull-up resistor R _P from the reference voltage according to an input signal. The voltage level input to the controller 36 may be detected differently.

In this case, the lithium ion battery may be connected to the negative electrode terminal (−) by the internal resistance r from the recognition terminal 211 of the lithium ion battery, and the internal resistance r may be 1/10 of the pull-up resistance R _P. It is preferable to set. In this case, in the present embodiment, the pull-up resistor R _P is 47 kΩ, and the internal resistance r is 4.7 kΩ.

In addition, the battery voltage detector 37 is electrically connected to the positive terminal of the battery on which the battery voltage detection unit 37 is mounted to detect the battery voltage from the positive electrode terminal to check whether the battery reaches a stop voltage set slightly higher than the final voltage.

FIG. 6 is a circuit diagram schematically illustrating a battery type identification device of FIG. 5, in which a lithium ion battery is mounted, and FIG. 7 is a battery type identification device of FIG. 5, and equipped with an alkaline / nickel hydrogen battery. Fig. 8 is a circuit diagram schematically showing a battery identification device, and Fig. 8 is a circuit diagram schematically showing a battery identification device when a lithium battery of the CR-V3 type is mounted as the battery type identification device of Fig. 5.

Referring to the drawings, the same components as those of the battery type identification device 5 shown in FIG. 5 of the battery type identification device 5 according to the present embodiment use the same reference numerals, and have the same reference numerals. Detailed description will be omitted.

6 identifies the lithium ion battery 21 by the battery type identification device 5 according to an embodiment of the present invention. The first recognition unit 31 is electrically connected to the recognition terminal 211 to detect the recognition signal. The recognition signal is input through the lithium ion battery test line LI_CHK, is input to the recognition signal converter 34, and the voltage level is adjusted to be input to the controller 36.

When the lithium ion battery 21 is mounted, a pull-up resistor R _P having a resistance value of 47 kV and an internal resistor r having a resistance value of 4.7 kV are connected in series between a reference voltage of 3.3 V and ground. The voltage value input to the controller is a value in which the reference voltage is divided by the pull-up resistor R _P and the internal resistor r.

Accordingly, a ratio corresponding to the internal resistance r of the sum of the pull-up resistor R _P and the internal resistance r of the reference voltage is input to the controller 36, and the pull-up resistor R _P is the internal resistance. Since it is 10 times (r), a voltage value of 0.3 V, which is 1/11 of the reference voltage 3.3 V, is input to the controller 36.

That is, when the voltage value input to the control unit 36 is 0.3V by the above calculation, it can be seen that the battery to be mounted is a lithium ion battery.

7 identifies an alkaline / nickel-metal hydride battery 23 by a battery type identification device 5 according to one embodiment of the invention. The second recognition unit 32 is electrically connected to the connection terminal 231 connecting two batteries in series to detect the recognition signal. The recognition signal is input through the alkaline / nickel-metal hydride battery test line ALK_CHK, and is input to the recognition signal converter 34 to adjust the voltage level and input the controller 36.

When the alkaline battery or the nickel-metal hydride battery 23 is mounted, the second recognition unit 32 is electrically connected to the connection terminal 231 formed at the contact portion of the battery chamber opening and closing unit with the battery, and grounded regardless of the reference voltage. And a voltage of one cell interposed between the connection terminal 231 is detected as a recognition signal. Accordingly, the recognition signal is inputted to the analog / digital conversion terminal (A / D) of the control unit 36 without changing its voltage level by the recognition signal conversion unit 34, thereby identifying the battery type. In this case, 0.6 to 1.5 V, which is a voltage value of one battery cell, is input to the control unit 36.

That is, when the voltage value input to the control unit 36 is 0.6 to 1.5V by the above calculation, it can be seen that the battery to be mounted is an alkaline battery or a nickel-hydrogen battery.

8 identifies the lithium battery 22 by the battery type identification device 5 according to an embodiment of the present invention. Since there is no recognition terminal 211 in the lithium battery 22, the lithium battery 22 is opened to the first recognition unit 31 and electrically insulated. In addition, since the electrode terminal is not connected to the contact portion of the lithium battery 22 with the connection terminal 231, the second recognition part 32 is electrically insulated from the battery.

Since the recognition signal input from the first recognition unit 31 and the second recognition unit 32 is not electrically connected, the recognition signal is input from the first recognition unit 31 and the second recognition unit 32. Not. The recognition signal converted from the reference voltage in the state in which the input terminal is opened by the recognition signal converter 34 to the voltage value applied to the pull-up resistor R _P is input to the controller 36. Accordingly, 3.3 V is applied to the control unit 36 by the input terminal being electrically opened and applied to the pull-up resistor R _P by the reference voltage.

That is, when the voltage value input to the control unit 36 by the above calculation is 3.3V, it can be seen that the battery to be mounted is a lithium battery.

9 is a block diagram schematically showing a battery type identification device of the batteries of FIGS. 2A to 2C as another preferred embodiment of the present invention, and FIG. 10 is a specific embodiment of the battery type identification device of FIG. It is a circuit diagram schematically showing a battery identification device when the branch cells are mounted, respectively.

Referring to the drawings, the same components as those of the battery type identification device 3 shown in FIG. 3 of the battery type identification devices 6 and 7 according to the present embodiment use the same reference numerals, and use the same reference numerals. Detailed descriptions thereof will be omitted.

Battery type identification device (6, 7) according to the present invention is a lithium ion battery 21 having a recognition terminal 211 in the battery chamber and at least two or more are connected in series by the connection terminal 231 A battery type identification device for mounting one of an alkaline / nickel-metal hydride battery 23 and a lithium battery 22 and identifying the type of battery mounted in the battery chamber, comprising: a first recognition unit 61, Preferably, the second recognition unit 62, the reference voltage supply unit 63, the recognition signal conversion unit 64, and the control unit 36 are provided.

The first recognition unit 61 is electrically connected to the recognition terminal 211 and recognizes the lithium ion battery 21 to generate a first recognition signal. The second recognition unit 62 is electrically connected to the connection terminal 231 to recognize the alkaline / nickel-metal hydride battery 23 to generate a second recognition signal. The reference voltage supply unit 63 generates a reference voltage for converting the first recognition signal. The recognition signal converter 64 converts the first recognition signal input from the first recognition unit 61 by the reference voltage to generate a conversion recognition signal. The controller 66 receives the converted recognition signal and the second recognition signal through input terminals IN1 and IN2, respectively, and identifies the type of battery.

It is preferable that the battery type identification devices 6 and 7 according to the present invention further comprise a battery voltage detector 67. The battery voltage detector 67 detects a battery voltage, and the controller 66 receives the conversion recognition signal and the second recognition signal through input terminals IN1 and IN2, respectively, and identifies the type of battery. It is preferable to check whether the stop voltage is reached to stop the operation of the battery by receiving the digital battery voltage through the analog / digital conversion terminal (A / D).

In this embodiment, the first recognition signal is generated from the first recognition unit 61 that recognizes the lithium ion battery 21. The second recognition signal from the second recognition unit 62 that recognizes the alkaline / nickel-metal hydride battery 23 does not go through a separate analog / digital converter. In addition, the input to the control unit 66 is not input via the analog / digital conversion terminal A / D of the control unit, but through the normal input / output terminals IN1 and IN2 provided in the control unit.

In this case, the first recognition signal recognized by the first recognition unit 61 is converted into a conversion recognition signal by the recognition signal conversion unit 64 to the control unit 66 through the first input terminal IN1 of the control unit 66. Is entered. In addition, the second recognition signal recognized by the second recognition unit 62 is input to the control unit 66 through the second input terminal IN2 of the control unit 66.

However, a predetermined logic circuit part is provided in the controller, and signals input through the first input terminal IN1 and the second input terminal IN2 are converted into high and low signals by the logic circuit part. The type of the battery is determined by a combination of high and low of the signals.

As such, signals input through the first input terminal IN1 and the second input terminal IN2 input signals through normal input / output terminals IN1 and IN2 instead of analog / digital conversion terminals A / D. This is because the number of analog / digital conversion terminals A / D is much smaller than that of the normal input / output terminals IN1 and IN2 in the microcomputer generally used as the control unit.

Therefore, in the battery type identification device 3 shown in Fig. 3, in the case where the microcomputer used as the controller does not have an extra analog / digital conversion terminal (A / D), if it is configured as in the present embodiment, a new analog / The digital conversion terminal A / D can be configured without the addition of an analog / digital conversion unit, which is simple in circuit construction and advantageous in terms of cost.

In the battery type identification device 7 shown in FIG. 10, a third switch SW3 is shown which selects an input from the positive terminal + of each battery. However, the third switch SW3 is not an actual switch to be arbitrarily selected, but is intended to show that each input line to be connected varies according to the type of battery to be mounted. In addition, the cathodes of the cells are each electrically connected to ground.

In addition, as in the embodiment illustrated in FIG. 5, the reference voltage supplied from the reference voltage supply unit 63 is set to 3.3 V, and the internal resistance r is set to be 1/10 of the pull-up resistor R _P. It is desirable to. In this case, in the present embodiment, the pull-up resistor R _P is set to 47 kV, and the internal resistance r is set to 4.7 kV.

In the battery identification method according to the present embodiment, the first input signal input from the first recognition unit 61 through the first input terminal IN1 and the second input terminal IN2 from the second recognition unit 62. The second input signals inputted through are determined through predetermined logic circuits in the control unit as follows. That is, basically, when the battery is not mounted inside the battery chamber, both the first input signal and the second input signal have a low value.

When the lithium ion battery 21 is mounted, the connection terminal 231 is not electrically connected to the electrode terminals of the lithium ion battery 21. Accordingly, no electricity is supplied to the connection terminal 231, and no electrical signal is detected by the second recognition unit 62 that recognizes the signal from the connection terminal 231, so that the second input signal has a low value. Have

In addition, the first recognition unit 61 is electrically connected to the recognition terminal 211 provided in the lithium ion battery 21. Therefore, a pull-up resistor R _P having a resistance value of 47 kV and an internal resistor r having a resistance value of 4.7 kV are connected in series between a reference voltage of 3.3 V and ground, and a voltage input to the controller. The value is a value at which the reference voltage is voltage-divided by the pull-up resistor R _P and the internal resistor r.

That is, a ratio corresponding to the internal resistance r of the sum of the pull-up resistor R _P and the internal resistance r of the reference voltage is input to the controller 36, and the pull-up resistor R _P is the internal resistance. Since it is 10 times (r), a voltage value of 0.3 V, which is 1/11 of the reference voltage 3.3 V, is input to the controller 36. Thus, the first input signal has a low value.

When the alkaline / nickel-metal hydride battery 23 is mounted, the first recognition unit 61 is not electrically connected to the recognition terminal 211 provided in the lithium ion battery 21 and is in an open state. The recognition signal converted from the reference voltage in the state in which the input terminal is opened by the recognition signal converter 64 to the voltage value applied to the pull-up resistor R _P is input to the controller 36. 3.3V applied to the pull-up resistor R _P by the reference voltage is input to the controller 36. Thus, the first input signal has a high value.

The second recognition unit 62 is electrically connected to the connection terminal 231, and the voltage of one cell of the battery interposed between the ground to which the negative electrode is connected and the connection terminal 231 is detected as a recognition signal. That is, 0.6-1.5V which is the voltage value of one battery cell is input to the said control part 36. Therefore, the second input signal has a high value.

When the lithium battery 22 is mounted, the recognition terminal 211 is not provided in the lithium battery 22 as in the lithium ion battery 21, so that the first recognition unit 61 is not electrically connected and is open. do. Thus, as in the case of the alkaline / nickel hydrogen battery 23, the first input signal has a high value.

In addition, as in the case of the lithium ion battery 21, the connection terminal 231 is not electrically connected to the electrode terminals of the lithium ion battery 21. Thus, the second input signal has a low value.

Therefore, both the first input signal and the second input signal have a low value when the lithium ion battery is mounted, and both the first input signal and the second input signal are high when the alkaline / nickel-metal hydride battery is mounted. When the lithium battery is mounted, the first input signal has a high value and the second input signal has a low value.

FIG. 11 is a perspective view schematically showing a digital camera having a battery identification device according to another embodiment of the present invention, and FIG. 12 is a schematic view showing a battery stop surface inside a battery chamber of the digital camera of FIG. It is a figure shown.

Referring to the drawings, the digital camera 8 according to a preferred embodiment of the present invention includes a main body 81, a battery chamber 82, an opening and closing means 83, and a battery type identification device 84. desirable.

As the battery type identification device 84, the battery type identification devices 3, 4, 5, 6, and 7 illustrated in FIGS. 3 to 10 may be used. Therefore, the digital camera 8 according to the present invention has the same actions and effects as those caused by them, and detailed description thereof will be omitted. At this time, the batteries identified by the battery type identification device 84 are the batteries shown in Figs. 2A to 2C.

The battery chamber 82 is formed inside the main body 81, and the lithium ion battery 21 having the recognition terminal 211 from the outside of one side of the main body 81, and at least two or more An alkaline / nickel-metal hydride battery 23 connected in series and one of the lithium batteries 22 are housed therein, and a lithium ion battery recognition means 8213 is electrically provided inside the recognition terminal 211. .

The opening and closing means 83 opens and closes the battery chamber 82, and a conductive connection terminal 831 is formed at a portion in contact with the alkaline / nickel hydrogen battery 23.

When the lithium ion battery 21 is mounted in the battery chamber 82, the battery type identification device 84 is electrically connected to the lithium ion battery recognition means 8213 to identify the lithium ion battery 21. When the alkaline / nickel hydrogen battery 23 is mounted, the connection terminal 831 is electrically connected to identify the alkaline / nickel hydrogen battery 23, and when the lithium battery 22 is mounted, The lithium battery 22 is identified by being not electrically connected to both the lithium ion battery recognition means 8213 and the connection terminal 831.

The main body 81 may be composed of various components required for operation of a conventional digital camera such as a lens unit, a flash unit, a display unit, a selection unit, and a shutter.

In the battery chamber 82 of this embodiment, one lithium ion battery, two AA-type alkaline / nickel-metal hydride batteries connected in series, and one CR-V3 type lithium battery are mounted. Preferably, all of the batteries have a shape that can be accommodated.

The battery stop surface 821 is formed in the battery chamber 82 to contact the inner surface of the battery chamber 82 when the batteries to be inserted are inserted to the end. The battery stop surface 821 is preferably provided with a positive electrode portion 8211 and a negative electrode portion 8212 which are electrically connected to the positive terminal (+) and the negative terminal (-) of the respective batteries.

The positive electrode portion 8211 and the negative electrode portion 8212 are preferably formed to be connected even when the positive terminal (+) and the negative terminal (−) of the batteries are concave. It may be in the form of, or may be formed of a spiral spring that is thinner than the leaf spring or the end.

In addition, the battery stop surface 821 is a lithium ion battery recognition means (8213) to recognize the lithium ion battery 21 is provided with a recognition terminal for identifying a lithium ion battery, the recognition terminal 211 It is preferable to be installed so as to be electrically connected with. The lithium ion battery recognizing means 8231 is formed so that the lithium ion battery is inserted into the battery chamber so as to protrude at a position where the recognition terminal 211 is located, and may be pressed into the lithium ion battery in contact with the recognition terminal 211. It is preferably formed so that.

The opening and closing means 83 may include a conductive connection terminal formed at a portion in contact with the batteries so that the second recognition unit is electrically connected to the connection terminal.

The battery type identification device 84 may include a first recognition unit, a second recognition unit, a reference voltage supply unit, a recognition signal conversion unit, and a controller.

In this case, it is preferable that the first recognition unit is electrically connected to the lithium ion battery recognition unit 8213 provided in the battery chamber 82. In addition, the second recognition unit is preferably electrically connected to the connection terminal 831 formed in the opening and closing means (83).

Battery type identification device according to the present invention and a digital camera having the same, in a portable electronic device such as a digital camera using a plurality of batteries, by accurately identifying the type of the battery, by performing a power supply control for the battery The battery life can be maximized.

In addition, since the separation of the various types of batteries in a hardware method, it is possible to reduce the software burden of the electronic device in which the different types of batteries are used.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Could be. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

1 is a graph schematically showing a discharge curve of a battery according to a battery type;

2A to 2C are views illustrating batteries to which a battery type identification device according to the present invention is applied, and are perspective views schematically showing lithium ion batteries, CR-V3 type lithium batteries, and alkaline / nickel hydrogen batteries, respectively.

3 is a block diagram schematically showing a battery type identification device of the batteries of FIGS. 2A to 2C as one preferred embodiment of the present invention;

4 is a block diagram schematically illustrating a battery type identification device further including a battery voltage detection unit in the battery type identification device of FIG. 3;

FIG. 5 is a detailed embodiment of the battery type identification device of FIG. 4, and is a circuit diagram schematically illustrating the battery identification device when four batteries are mounted.

FIG. 6 is a circuit diagram of a battery type identifying device of FIG. 5 and schematically illustrating a battery identifying device when a lithium ion battery is mounted.

FIG. 7 is a circuit diagram schematically illustrating a battery type identifying device of FIG. 5, wherein the battery identifying device when an alkaline / nickel hydrogen battery is mounted;

FIG. 8 is a circuit diagram of a battery type identifying device of FIG. 5 and schematically illustrating a battery identifying device in a case where a CR-V3 type lithium battery is mounted.

9 is a block diagram schematically showing a battery type identification device of the batteries of FIGS. 2A to 2C as another preferred embodiment of the present invention;

FIG. 10 is a circuit diagram schematically illustrating a battery identification device when four batteries are mounted, as a specific embodiment of the battery type identification device of FIG.

11 is a perspective view schematically showing a digital camera having a battery identification device according to another embodiment of the present invention.

FIG. 12 is a view schematically illustrating a battery stop surface inside a battery chamber of the digital camera of FIG. 11.

<Description of Symbols for Major Parts of Drawings>

3, 4, 5, 6, 7: Battery type identifier

21: lithium ion battery 22: lithium battery

23: alkaline / nickel-metal hydride battery 211: recognition terminal

231: connection terminal 31, 61: first recognition unit

32, 62: second recognition unit 33, 63: reference voltage supply unit

34, 64: recognition signal conversion unit 36, 66: control unit

37, 67: battery voltage detector 81: main body

82: battery chamber 83: opening and closing means

Claims (11)

A first type of battery having a recognition terminal, a second type of battery in which at least two are connected in series by a connection terminal, and a third type of battery in which none of the recognition terminal and the connection terminal are provided In the battery type identification device for identifying which type of battery is the battery mounted inside the battery chamber, A first recognition unit electrically connected to the recognition terminal to generate a recognition signal by recognizing the first type of battery; A second recognition unit electrically connected to the connection terminal to recognize the second type of battery and generate a recognition signal; A reference voltage supply unit configured to generate a reference voltage for converting the recognition signal; A recognition signal converter for converting a recognition signal input from one of the first recognition unit and the second recognition unit by the reference voltage to generate a conversion recognition signal; An analog / digital converter configured to receive the converted recognition signal and generate a digital recognition signal; And And a controller for receiving the digital recognition signal and identifying a type of battery. The method of claim 1, One battery of one first type, two AA types of batteries connected in series, and one battery of a third type of CR-V3 type are mounted inside the battery chamber. Battery type identification device. The method of claim 1, A battery type identification device, wherein the first type of battery is a lithium ion battery, the second type of battery is an AA type alkaline battery or a nickel-hydrogen battery, and the third type of battery is a CR-V3 type lithium battery. The method of claim 1, And the analog / digital converting unit is built in the control unit. The method of claim 1, And the first recognition unit and the second recognition unit are electrically insulated from the third type of battery. The method of claim 1, A battery voltage detector for detecting a battery voltage and a second analog / digital converter for generating a digital battery voltage and inputting the battery voltage from the battery voltage detector to the controller; Battery type identification device, characterized in that for receiving a stop voltage for stopping the operation of the battery to receive the input, and receives the digital recognition signal to identify the type of battery. The method of claim 6, And the second analog / digital converting unit is built in the control unit. A first type of battery having a recognition terminal, a second type of battery in which at least two are connected in series by a connection terminal, and a third type of battery in which none of the recognition terminal and the connection terminal are provided In the battery type identification device for identifying which type of battery is the battery mounted inside the battery chamber, A first recognizing unit electrically connected to the recognizing terminal to recognize the first type of battery to generate a first recognizing signal; A second recognizer electrically connected to the connection terminal to recognize the second type of battery and to generate a second recognition signal; A reference voltage supply unit configured to generate a reference voltage for converting the first recognition signal; A recognition signal conversion unit converting the first recognition signal input from the first recognition unit by the reference voltage to generate a conversion recognition signal; And a controller configured to receive the converted recognition signal and the second recognition signal through input terminals, respectively, and identify a type of battery. The method of claim 8, The apparatus further includes a battery voltage detector configured to detect a battery voltage, wherein the controller receives the conversion recognition signal and the second recognition signal through an input terminal, respectively, identify a type of battery, and convert the digital battery voltage into an analog / digital conversion terminal. Battery type identification device, characterized in that for receiving the input via a test to determine whether the stop voltage for stopping the operation of the battery. A main body; Is formed inside the main body, from the outside of one side of the main body, having a first type of battery having a recognition terminal, a second type of battery at least two connected in series, and the recognition terminal A battery chamber in which one battery of a third type of battery which is not provided is accommodated, and having a first type of battery recognition means electrically connected to the recognition terminal; Opening and closing means for opening and closing the battery chamber, the opening and closing means having a conductive connection terminal formed at a portion in contact with the second type of battery; And When the battery of the first type is mounted in the battery chamber, the first terminal is electrically connected with the battery recognition means to identify the battery of the first type, and when the battery of the second type is mounted, the connection terminal Is electrically connected to identify the second type of battery, and when the third type of battery is mounted, the third type of battery is not electrically connected to both the first type of battery recognition means and the connection terminal. A digital camera having a battery type identification device for identifying a battery. The method of claim 10, The battery type identification device is electrically connected to the first type of battery recognition means, and is electrically connected to the first and second recognition units for recognizing the first type of battery and generating a recognition signal. A second recognizer that recognizes the second type of battery and generates a recognition signal, a reference voltage supply that generates a reference voltage for converting the recognition signal, and one of the first recognizer and the second recognizer A recognition signal converter for converting a recognition signal input from the reference voltage to generate a conversion recognition signal, an analog / digital converter for receiving the conversion recognition signal and generating a digital recognition signal, and the digital recognition signal. And a controller for receiving the input and identifying the type of battery.