1. Field of the Invention
The present invention relates to a battery charger and more particularly, to a battery charger that is adapted to charge different size battery cells, such as AA and AAA battery cells, in which the battery charger can automatically distinguish between different size battery cells in order to provide the battery cell with the proper charging characteristic.
2. Description of the Prior Art
Various portable devices and appliances are known to use multiple rechargeable battery cells, such as AA and AAA battery cells. In order to facilitate charging of the battery cells for such multiple cell appliances, multiple cell battery chargers have been developed. Many known battery chargers are configured to receive battery cells having different sizes, such as AA and AAA battery cells. Because the charging characteristics of different size battery cells are different, various mechanical configurations have been developed to sense the size of the battery cell inserted into the charging terminals of the battery charger and properly configure the battery charger for the correct battery cell.
For example, U.S. Pat. Nos. 5,606,238; 6,384,575; and 6,610,941 disclose battery chargers with different mechanical configurations for detecting the size of a battery cell. For example, Rayovac U.S. Pat. No. 5,606,238 discloses a mechanical configuration for sensing the size of a battery cell inserted into the battery charger for charging. A front wall of the battery compartment is formed with a number of apertures sized to coincide with the diameter of various battery cell cathodes. The apertures are located so that when a battery cell is fully inserted within the battery compartment, the cathodes of the cell are received in one of the apertures. The cathode contacts are disposed behind the apertures. The anode in the battery compartment is formed from a leaf spring and is used to bias the battery cell toward the cathode. There are several problems with such a configuration. For example, the mechanical sensing configuration is dependent upon the diameter of the cathode which varies from manufacturer to manufacturer. In addition, the leaf spring may eventually lose its spring tension due to metal fatigue.
U.S. Pat. No. 6,384,575, assigned to Delta Electronics, Inc. of Taiwan, discloses a different type of battery cell mechanical sensing arrangement for a battery charger. This battery charger includes a anode contact and a rotatable cathode contact. When the rotatable cathode contact is in a first position, it is adapted to receive a battery cell of a first longer length. In a second position, the pivotal cathode contact is adapted to receive battery cells of a shorter length. The mechanical sensing arrangement disclosed in the '575 patent requires the user to rotate the rotatable contact before inserting the battery cell in the battery compartment in order to select the appropriate configuration for the battery cell to be charged. Such an operation is cumbersome for the user.
U.S. Pat. No. 6,610,941 discloses another configuration for mechanically sensing the size of the battery cell. This arrangement uses a slide device and a two-prong fork. The configuration disclosed in the '941 patent is used to sense AAA, AA, C, and D-type batteries. The two-prong fork is pivotally mounted. The prongs of the fork are spaced apart at a distance less than the diameter of a type-C battery. The two-prong fork is also rotatably mounted so that when a type-C or D battery is inserted into the battery compartment, a two-prong fork is pushed downwardly. The actuation of the two-prong fork operates a switch which provides an electrical representation of whether type C/D or type AA/AAA batteries have been installed in the battery compartment. The anode is connected to a slider assembly, which, in turn, actuates a switch depending on the length of the battery cell inserted into the battery compartment. Thus, the combination of the two switches can be used to identify the type of battery that has been inserted into the battery compartment.
Such mechanical systems for sensing the size of a battery cell are relatively cumbersome and are subject to wear and are relatively expensive. As such, systems have been developed for electronically determining the size of a battery cell. For example, commonly owned U.S. Pat. Nos. 5,764,030 and 5,998,966 disclose a system for electrically-sensing the battery size and type of smart batteries. Such smart batteries normally include an internal microprocessor that is adapted to communicate with a microprocessor in the battery charger and thus provide data to the battery charger relating to the size of battery cells in the smart battery pack. Unfortunately, the techniques disclosed in the '030 and '966 patents are not suitable for batteries other than smart battery packs.
Fujitsu, U.S. Pat. No. 5,861,729, discloses a battery charger which can electrically distinguish between NiH and NiCd battery based on [FILL IN DETAILS]. Thus there is a need for a battery charger which can effectively and inexpensively distinguish between different size battery cells which are not part of a smart battery pack.
Briefly, the present invention relates to a battery charger that is configured to charge different size battery cells which can automatically determine the size of the battery cell to be charged. The battery charger includes at least one charging circuit and a microprocessor. The charging circuit, in turn, includes a serially connected switching device and a current sensing resistor and a first and second pair of battery terminals that are configured to receive different size battery cells. The first pair of battery terminals is serially connected to a size detection resistor. The serial combination of the first pair of battery terminals and the size detection resistor is connected in parallel with a second pair of battery terminals. The parallel combination is connected in series with the charging circuit. At a nominal charging current, the voltage at the battery terminals will vary by the voltage drop across the size detection resistor. Accordingly, by measuring the voltage at the battery terminals, the system can determine which pair of battery terminals is connected to a battery cell. By configuring the first pair of battery terminals to receive a first battery cell size, for example, size AAA, and serially coupling the first pair of battery terminals to the size detection resistor, and configuring the second pair of battery terminals to receive a second size of battery cell, for example, size AA, the battery cell size can easily be detected electronically by measuring the voltage at the battery terminals.
These and other advantages of the present invention will be readily understood with reference to the following specification and attached drawing wherein:
The present invention relates to a multiple cell battery charger configured to charge different size battery cells In accordance with an important aspect of the invention the battery charger is provided with multiple pockets for receiving battery cells having different sizes and can automatically determine the size of the battery cell populated in one of the pockets.
In general, the battery charger 20 includes at least one charging circuit, such as the charging circuit 21 and a microprocessor 26. The charging circuit 21, in turn, includes a switching device Q12, Q13, Q14 and Q15; a serially connected current sensing resistor R37, R45, R53 and R60 and one or more pairs of first and second pair of battery terminals T1,T2 and T3,T4; T5,T6 and T7,T8; T9,TI0 and TI1,T12; T13,T14 and T15,T16, respectively, that are configured to receive different size battery cells, for example size M and AA. Each pair of battery terminals T1,T2 T3,T4; T5,T6; T7,T8; T9,T10; T11,T12; T13,T14; T15,T16, defines a pocket. Each of the first pairs of battery terminals T3,T4; T7,T8; T11,T12; T15,T16, is serially connected to a size detection resistor R1, R2, R3 and R4. The serial combination of the first pair of battery terminals T3,T4; T7,T8; T11,T12; T15,T16 and the size detection resistor R1, R2, R3 and R4 is connected in parallel with the second pair of battery terminals T1,T2; T5,T6; T9,T10; and T13,T14. The parallel combination is connected in series with the charging circuit 21.
At a nominal charging current, for example 750 milliamps, the voltage at the battery terminals will vary by an amount approximately equivalent to the voltage drop across the size detection resistor R1, R2, R3 and R4. Accordingly, by individually measuring the voltage at the nodes N1, N2, N3, and N4, defined by the battery terminals T1,T3; T5,T7; T9,T11; and T13,T15, the system can determine which pair of battery terminals is connected to a battery cell. For example, the first pair of battery terminals may be configured to receive a first battery cell size, for example, size AAA, and configuring the second pair of battery terminals to receive a second size of battery cell, for example, size AA, the nominal voltage of such battery cells is in the range of 1.2–1.5 volts DC. By sizing the size detection resistors R1, R2, R3 and R4 so that at the nominal charging current of, for example, 750 milliamps, the voltage drop across the size detection resistors R1, R2, R3 and R4 is about 0.5 volts DC, measurement of the voltage at the nodes will either be the nominal battery cell voltage of 1.2–1.5 volts if, for example, a AA battery cell is populated in one of the pockets P1, P2, P3 and P4 defined by the second pair of battery terminals T1,T2; T5,T6; T9,T10; and T13,T14. Alternatively, if a, for example, AAA battery cell is populated in one of the pockets P5, P6, P7 and P8 defined by first pair of battery terminals T3,T4; T7,T8; TI1,T12; T15,T16 that are serially connected to one of the size detection resistors R1, R2, R3 and R4, the voltage at the nodes N1, N2, N3, and N4 at a nominal charging current of 750 milliamps will be in the range of 1.7–2.0 volts DC. Thus, the microprocessor 26 can periodically sense the voltage at the nodes N1, N2, N3 and N4 at its port Vsen or alternatively at its port Is1.
An exemplary battery charger with a parallel topology is described and illustrated below which can automatically sense the size of the battery cell to be charged. However, the principles of the present invention are applicable to various types of battery chargers, for example, battery chargers having either a parallel or serial topology.
Referring to
The regulator 24 may be an integrated circuit (IC) or formed from discrete components. The regulator 24 may be, for example, a switching type regulator which generates a pulse width modulated (PWM) signal at its output. The regulator 24 may be a synchronous buck regulator 24, for example, a Linear Technology Model No. LTC 1736, a Fairchild Semiconductor Model No. RC5057; a Fairchild Semiconductor Model No. FAN5234; or a Linear Technology Model No. LTC1709–85 or others.
The output of the regulator 24 may optionally be controlled by way of a feedback loop. In particular, a total charging current sensing device, such as a sensing resistor R11, may be serially coupled to the output of the regulator 24. The sensing resistor R11 may be used to measure the total charging current supplied by the regulator 24. The value of the total charging current may be dropped across the sensing resistor R11 and sensed by a microprocessor 26. The microprocessor 26 may be programmed to control the regulator 24, as will be discussed in more detail below, to control the regulator 24 based on the state of charge of the battery cells being charged.
As shown in
The charging current supplied to each of the battery pockets P1,P5; P2,P6; P3,P7; and P4,P8 can vary due to the differences in charge, as well as the internal resistance of the circuit and the various battery cells populated within the pockets P1,P5; P2,P6; P3,P7; and P4,P8. This charging current as well as the cell voltage and optionally the cell temperature may be sensed by the microprocessor 26. In accordance with an important aspect of the present invention, the multiple cell battery charger 20 may be configured to optionally sense the charging current and cell voltage of each of the battery cells 28, 30, 32 and 34, separately. This may be done by control of the serially connected FETS Q12, Q13, Q14 and Q15. For example, in order to measure the cell voltage of an individual cell, such as the cell 28, the FET Q12 is turned on while the FETs Q13, Q14 and Q15 are turned off. When the FET 12 is turned on, the anode of the cell 28 is connected to system ground. The cathode of the cell is connected to the Vsen terminal of the microprocessor 26. The cell voltage is thus sensed at the terminal Vsen.
As discussed above, the regulator 24 may be controlled by the microprocessor 26. In particular, the magnitude of the total charging current supplied to the battery cells within the pockets P1,P5; P2,P6; P3,P7; and P4,P8 may be used to determine the pulse width of the switched regulator circuit 24. More particularly, as mentioned above, the sensing resistor R11 may be used to sense the total charging current from the regulator 24. In particular, the charging current is dropped across the sensing resistor R11 to generate a voltage that is read by the microprocessor 26. This charging current may be used to control the regulator 24 and specifically the pulse width of the output pulse of the pulse width modulated signal forming a closed feedback loop. In another embodiment of the invention, the amount of charging current applied to the individual cells Q12, Q13, Q14 and Q15 may be sensed by way of the respective sensing resistors R37, R45, R53 and R60 and used for control of the regulator 24 either by itself or in combination with the total output current from the regulator 24. In other embodiments of the invention, the charging current to one or more of the battery cells within the pockets P1,P5; P2,P6; P3,P7; and P4,P8 may be used for control.
In operation, during a charging mode, the pulse width of the regulator 24 is set to an initial value. Due to the differences in internal resistance and state of charge of each of the battery cells within the pockets P1,P5; P2,P6; P3,P7; and P4,P8 at any given time, any individual cells which reach their fully charged state, as indicated by its respective cell voltage, as measured by the microprocessor 26. More particularly, when the microprocessor 26 senses that any of the battery cells within any of the pockets P1,P5; P2,P6; P3,P7; and P4,P8 are fully charged, the microprocessor 26 drives the respective FETs Q12, Q13, Q14, or Q15 open in order to disconnect the respective battery cell from the circuit. Since the battery cells are actually disconnected from the circuit, no additional active devices are required to protect the cells from discharge.
As mentioned above, the charging current to each of the battery cells within the pockets P1,P5; P2,P6; P3,P7; and P4,P8 is dropped across a sensing resistor R37, R45, R53 and R60. This voltage may be scaled by way of a voltage divider circuit, which may include a plurality of resistors R30, R31, R33 and R34, R35, R38, R39, R41, R43, R44, R46, R48, R49, R51, R52, R54, R57, R58, R59, R61, as well as a plurality of operational amplifiers U4A, U4B, U4C and U4D. For brevity, only the amplifier circuit for the first channel 28 is described. The other amplifier circuits operate in a similar manner. In particular, for the battery cell populated in channel 28, the charging current through the battery cell is dropped across the resistor R37. That voltage drop is applied across a non-inverting input and inverting input of the operational amplifier U4D.
The resistors R31, R33, R34, and R35 and the operational amplifier U4D form a current amplifier. In order to eliminate the off-set voltage, the value of the resistors R33 and R31 value are selected to be the same and the values of the resistors R34 and R35 value are also selected to be the same. The output voltage of the operational amplifier U4D=voltage drop across the resistor R37 multiplied by the quotient of the resistor value R31 resistance value divided by the resistor value R34. The amplified signal at the output of the operational amplifier U4D is applied to the microprocessor 26 by way of the resistor R30. The amplifier circuits for the other battery cells 30, 32, and 34 operate in a similar manner.
The principles of the present invention are applicable to battery chargers with various charge termination techniques, such as temperature, pressure, negative delta, and peak cut-out techniques. These techniques can be implemented relatively easily by program control and are best understood with reference to
In addition to the charge termination techniques mentioned above, various other charge termination techniques the principles of the invention are applicable to other charge termination techniques as well. For example, a peak cut-out charge termination technique, for example, as described and illustrated in U.S. Pat. No. 5,519,302, hereby incorporated by reference, can also be implemented. Other charge termination techniques are also suitable.
As discussed above, other known charge termination techniques are based on pressure and temperature. These charge termination techniques rely upon physical characteristics of the battery cell during charging. These charge termination techniques are best understood with respect to
Temperature can also be used as a charge termination technique. As illustrated by the characteristic curve 44, the temperature increases rather gradually. After a predetermined time period, the slope of the temperature curve becomes relatively steep. This slope, dT/dt may be used as a method for terminating battery charge.
The battery charge in accordance with the present invention can also utilize other known charge termination techniques. For example, in U.S. Pat. No. 5,519,302 discloses a peak cut-out charge termination technique in which the battery voltage and temperature is sensed. With this technique, a load is attached to the battery during charging. The battery charging is terminated when the peak voltage is reached and reactivated as a function of the temperature.
Referring to the main program, as illustrated in
A more detailed flow-chart is illustrated in
One or more temperature based charge termination techniques may be implemented. If so, a thermistor may be provided to measure the external temperature of the battery cell. One such technique is based on dT/dt. Another technique relates to temperature cut off (TCO). If one or more of the temperature based techniques are implemented, the temperature is measured in step 74. If a dT/dt charge termination technique is utilized, the temperature is taken along various points along the curve 44 (
As mentioned above, the system may optionally be provided with negative delta V charge termination. Thus, in step 78, the system may constantly monitor the cell voltage by turning off all but one of the switching devices Q12, Q13, Q14, and Q15 and measuring the cell voltage along the curve 40 (
As mentioned above, a temperature cut-off (TCO) charge termination technique may be implemented. This charge termination technique requires that the temperature of the cells 28, 30, 32 and 34 to be periodically monitored. Should the temperature of any the cells 28, 30, 32 and 34 exceed a predetermined value, the FET for that cell is turned off in step 80. In step 82, the charging time of the cells 28, 30, 32, and 34 is individually monitored. When the charging time exceeds a predetermined value, the FET for that cell is turned off in step 82. A LED indication may be provided in step 84 indicating that the battery is being charged.
The pocket on-off subroutine is illustrated in
As discussed above, the channels 28, 30, 32 and 34 refer to the individual charging circuits 21 which include the switching devices Q12, Q13, Q14, and Q15. The channels 28, 30, 32 and 34 are controlled by way of the switching devices Q12, Q13, Q14 or Q14 being turned on or off by the microprocessor 26.
Obviously, many modifications and variations of the present invention are possible in light of the above teachings. Thus, it is to be understood that, within the scope of the appended claims, the invention may be practiced otherwise than as specifically described above.
This application is a continuation-in-part of commonly owned copending U.S. patent application Ser. No. 10/863,920, filed on Jun. 9, 2004, entitled “Multiple Cell Battery Charger Configured with a Parallel Topology”.
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Number | Date | Country | |
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20050275369 A1 | Dec 2005 | US |
Number | Date | Country | |
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Parent | 10863920 | Jun 2004 | US |
Child | 10896654 | US |