Source: https://patents.google.com/patent/JP2015154600A/en
Timestamp: 2020-01-21 12:05:33
Document Index: 734310355

Matched Legal Cases: ['art 15', 'art 11', 'art 15', 'art 15', 'art 4', 'art 13', 'art 15']

JP2015154600A - Battery pack charger for electric power tool - Google Patents
Battery pack charger for electric power tool Download PDF
JP2015154600A
JP2015154600A JP2014026568A JP2014026568A JP2015154600A JP 2015154600 A JP2015154600 A JP 2015154600A JP 2014026568 A JP2014026568 A JP 2014026568A JP 2014026568 A JP2014026568 A JP 2014026568A JP 2015154600 A JP2015154600 A JP 2015154600A
JP2014026568A
2014-02-14 Application filed by 株式会社マキタ, Makita Corp filed Critical 株式会社マキタ
2014-02-14 Priority to JP2014026568A priority Critical patent/JP2015154600A/en
2015-08-24 Publication of JP2015154600A publication Critical patent/JP2015154600A/en
PROBLEM TO BE SOLVED: To provide a charger for an electric power tool having a fuel cell as a power source, in which a plurality of secondary batteries (a battery pack) can be efficiently charged.SOLUTION: Charging power to one or a plurality of battery packs 1 attached to an attachment part 15 is controlled based on battery information. This allows for appropriate charging of each secondary battery 2 with an effective use of maximum output power of a fuel cell 5, and allows for efficient charging of a plurality of secondary batteries 2 as a result.
The present invention relates to a battery pack charging device for electric tools.
For example, Patent Document 1 describes a charging device for an electric tool that includes a fuel cell as a power source. The charging device can charge a plurality of secondary batteries.
WO2011 / 162357
An object of the present invention is to provide a charging device for a power tool that includes a fuel cell as a power source, and that can efficiently charge a plurality of secondary batteries (battery packs).
In order to achieve the above object, the present invention provides an electric tool in which a chargeable / dischargeable secondary battery (2) and an information output unit (3) capable of outputting information on the secondary battery (2) are integrated. In the battery pack (1) charging device, the mounting portion (15) having a plurality of charging ports (15A, 15B) to which the battery pack (1) can be detachably mounted, and an oxidation reaction between the fuel and the oxidant An information acquisition unit (11) that acquires information on the fuel cell (5) that generates electric power and the battery pack (1) attached to the attachment unit (15) from the information output unit (3), and an information acquisition unit A control unit (11) for controlling charging power to one or a plurality of battery packs (1) mounted on the mounting unit (15) based on the information acquired in (11). To do.
Thereby, in this invention, based on the information of each secondary battery (2) acquired by the information acquisition part (11), to one or several battery pack (1) with which the mounting part (15) was mounted | worn. Therefore, it is possible to charge each secondary battery (2) appropriately. Therefore, it can be possible to efficiently charge a plurality of secondary batteries (2).
Incidentally, the reference numerals in parentheses for each of the above means are examples showing the correspondence with the specific means described in the embodiments described later, and the present invention is indicated by the reference numerals in the parentheses of the above respective means. It is not limited to a specific hand or the like.
1 is a block diagram of a power supply device 1 according to a first embodiment of the present invention. 1 is an external view of a power supply device 1 according to a first embodiment of the present invention. It is a flowchart which shows the power supply control of the power supply device 1 which concerns on 1st Embodiment of this invention. It is a flowchart which shows the power supply control of the power supply device 1 which concerns on 2nd Embodiment of this invention. It is an external view of the power supply device 1 which concerns on 3rd Embodiment of this invention. It is a block diagram of the power supply device 1 which concerns on 4th Embodiment of this invention. It is a flowchart which shows determination of the charging power using identification information. It is a flowchart which shows determination of the charging power using status information. It is a flowchart which shows the power supply control of the power supply device 1 which concerns on 5th Embodiment of this invention.
At least one member or part described with at least a reference numeral is provided, except where “plurality”, “two or more”, and the like are omitted. Hereinafter, the charging device for electric tools which concerns on embodiment of this invention is demonstrated with drawing.
In addition, the use of an electric tool is not ask | required. That is, it may be a power tool for metal processing, wood processing, stone processing, or gardening. Specifically, electric drill, electric driver, electric wrench, electric grinder, electric marnoco, electric reciprocating saw, electric jigsaw, electric hammer, electric cutter, electric chainsaw, electric canna, electric nailer (including a hammer) An electric tool such as an electric hedge trimmer, an electric lawn clipper, an electric lawn mower, an electric brush cutter, an electric blower, or an electric cleaner.
1. 1. Configuration of Charging Device 1.1 Overview Charging device 10 shown in FIG. 1 charges battery pack 1 for an electric tool. The battery pack 1 includes a secondary battery 2 that can be charged and discharged, an information output unit 3 and the like, and the secondary battery 2 and the information output unit 3 and the like are integrated as one package. Note that the secondary battery 2 according to the present embodiment is a lithium ion battery.
The information output unit 3 can output information on the secondary battery 2. The information output unit 3 according to the present embodiment is configured as a part of a battery control unit (not shown). The battery control unit including the information output unit 3 is configured by a microcomputer having a CPU, a ROM, a RAM, and the like.
The battery controller includes a state of the secondary battery 2 such as a voltage sensor (not shown) for detecting the voltage of the secondary battery 2 and a temperature sensor (not shown) for detecting the temperature of the secondary battery 2. An output signal is input from a sensor for detecting
The battery control unit monitors the monitoring items such as whether or not the voltage, temperature, remaining capacity, deterioration state, and overcharge state of the secondary battery 2, and the monitoring result of the monitoring items is output to the information output unit. 3 to the charging device 10.
The battery control unit determines the deterioration state of the secondary battery 2 based on the cumulative number of charges, the type of the secondary battery 2, and the like. The battery control unit determines whether the remaining capacity and the overcharged state are based on the voltage of the secondary battery 2. Information such as the program for executing the above determination and the type of the secondary battery 2 is stored in advance in a nonvolatile storage unit such as a ROM.
When the battery pack 1 is attached to the charging device 10, information indicating the monitoring result of each monitoring item is transmitted and received between the charging device 10 and the battery control unit (information output unit 3). The basic functions of the charging device 10 are the following two.
That is, (a) When the charging device 10 receives information indicating that the secondary battery 2 is less than full charge, the charging device 10 starts charging by supplying power to the secondary battery 2 of the battery pack 1. (B) When receiving information indicating that the secondary battery 2 is overcharged, the charging device 10 stops supplying power to the secondary battery 2 of the battery pack 1.
1.2 Configuration of Charging Device As shown in FIG. 1, the charging device 10 includes a fuel cartridge 4, a fuel cell 5, a charging circuit 7, a secondary battery 9, a control unit 11, a mounting unit 15, and the like. Components such as the fuel cartridge 4 are accommodated in the casing 13 shown in FIG. The fuel cartridge 4 is filled with fuel supplied to the fuel cell 5.
The fuel cartridge 4 is detachably mounted on the casing 13. When the fuel filled in the fuel cartridge 4 is exhausted, it is necessary to replace the fuel cartridge 4 with a new fuel cartridge 4 instead of refilling the fuel.
The casing 13 is provided with an intake port 13A for taking in air. The air taken in from the intake port 13A is supplied to the fuel cell 5 as an oxidant and is blown to the fuel cell 5 and the secondary battery 9 as cooling air. And the air etc. which finished cooling of the fuel cell 5 etc. are discharged | emitted by the fan 13B outside.
The mounting portion 15 is a part to which the battery pack 1 is connected, and as shown in FIG. 1, has a plurality of charging ports 15A, 15B and the like to which the battery pack 1 is detachably mounted. The charging ports 15A and 15B are provided with signal ports 15C and 15D for transmitting and receiving information to and from the information output unit 3, respectively.
The first charging circuit 17A supplies charging power to the charging port 15A (hereinafter referred to as the first charging port 15A). The second charging circuit 17B supplies charging power to the charging port 15B (hereinafter referred to as the second charging port 15B).
The first charging circuit 17A and the second charging circuit 17B output the electric power generated in the fuel cell 5 via the secondary battery 9 to the first charging port 15A and the second charging port 15B. The fuel cell 5 generates electric power by oxidizing the fuel and the oxidant.
The fuel cell 5 according to this embodiment is a direct methanol fuel cell (DMFC) that directly supplies liquid fuel (methanol) stored in the fuel cartridge 4 instead of the reformed fuel (hydrogen). In the present embodiment, a pump or the like for sending fuel to the fuel cell 5 is not provided, and the fuel is supplied using the pressure difference between the pressure in the fuel cartridge 4 and the pressure in the fuel cell 5. .
The secondary battery 9 is a chemical battery that can be charged and discharged. In the present embodiment, a lithium ion battery is employed as the secondary battery 9. The charging circuit 7 is a circuit for controlling input power input from the fuel cell 5 to the secondary battery 9. The electromagnetic valve 4 </ b> A is a valve that adjusts the amount of fuel supplied from the fuel cartridge 4 to the fuel cell 5.
The control unit 11 controls the operation of the electromagnetic valve 4A, the charging circuit 7, the first charging circuit 17A, and the second charging circuit 17B. That is, the control unit 11 controls the output power output from the fuel cell 5 by controlling the operation of the electromagnetic valve 4 </ b> A and the charging circuit 7.
The control unit 11 controls the first charging circuit 17A using information related to the secondary battery 2 acquired via the signal port 15C. Similarly, the control part 11 controls the 2nd charging circuit 17B using the information regarding the secondary battery 2 acquired via signal port 15D. That is, the control unit 11 functions as an information acquisition unit that acquires information about the battery pack 1 (hereinafter referred to as battery information) from the information output unit 3 in cooperation with the signal ports 15C and 15D.
The control unit 11 is configured by a microcomputer having a CPU, a ROM, a CPU, and the like. A program for controlling the operation of the first charging circuit 17A, the second charging circuit 17B, and the like is stored in advance in a nonvolatile storage unit such as a ROM. And CPU reads the program etc. which were memorize | stored in ROM etc. and performs control of 1st charging circuit 17A etc. FIG.
2. Charging Control 2.1 Overview of Charging Control The control unit 11 controls charging power to one or a plurality of battery packs 1 mounted on the mounting unit 15 based on battery information.
That is, the control unit 11 according to the present embodiment acquires, as battery information, information related to power when charging the secondary battery 2 (hereinafter referred to as allowable charging power), and the acquired allowable charging power, and Based on the power that can be output by the fuel cell 5 (hereinafter referred to as the maximum output power), the charging power to one or a plurality of battery packs 1 attached to the attachment unit 15 is controlled.
Specifically, when there is one battery pack 1 attached to the attachment unit 15, the control unit 11 performs the first charge using the allowable charging power acquired from the information output unit 3 of the battery pack 1 as the charging power. The first charging mode to be output from the circuit 17A or the second charging circuit 17B is executed.
When the allowable charging power is larger than the maximum output power, the control unit 11 executes the first charging mode with the maximum output power as the charging power. The permissible charging power is power required when charging the secondary battery 2 and is power having a value determined to be necessary by the battery control unit.
For this reason, the value of the allowable charging power (hereinafter also referred to as necessary charging power) is not a fixed value, but is information indicating the state of the secondary battery 2 such as the deterioration state (number of times of charging, etc.) and temperature of the secondary battery 2. (Hereinafter also referred to as state information). That is, the battery control unit changes the required charging power (allowable charging power) to a small value when the deterioration of the secondary battery 2 progresses or when the temperature of the secondary battery 2 rises.
Then, when there are a plurality of battery packs 1 attached to the attachment unit 15 (two in this embodiment), the control unit 11 sets the maximum output power to the number of battery packs 1 attached to the attachment unit 15 (this number). In the embodiment, the second charging mode in which each battery pack 1 is charged by the value divided in 2) is executed.
2.2 Details of Charging Control FIG. 3 is a flowchart showing the charging control according to the present embodiment, where the maximum output power of the fuel cell 5 is 200 W and the required charging power of the battery pack 1 is 200 W or less. This is illustrated in the example.
The control shown in FIG. 3 (hereinafter referred to as charge control) is stored in advance in the non-volatile storage unit and is read into the CPU when a start switch (not shown) of the charging apparatus 10 is turned on. Start up. When the start switch is cut off, the charging control is stopped at that time.
When the charging control is activated, it is determined based on the battery information whether or not the battery pack 1 that needs to be charged is connected to either the first charging port 15A or the second charging port 15B (S1). Note that the battery pack 1 that needs to be charged includes an uncharged battery pack 1, that is, a new battery pack 1.
If it is determined that the battery pack 1 that requires charging is not connected to either the first charging port 15A or the second charging port 15B (S1: NO), the first charging circuit 17A and the second charging circuit In any one of the charging circuits 17B, it is determined whether or not the state where the charging power is not output continues for a predetermined time (for example, 1 minute) or longer (S3).
When it is determined that the state where the charging power is not output continues for a predetermined time or more (S3: YES), the charging circuit which is determined that the state where the charging power is not output continues for a predetermined time or more After the stop state is set (S5), S1 is executed. When it is determined that the state where the charging power is not output has not continued for a predetermined time or longer (S3: NO), S1 is executed without stopping the charging circuit.
When it is determined that the battery pack 1 that requires charging is connected to either the first charging port 15A or the second charging port 15B (S1: YES), two battery packs 1 that require charging are present. Is determined (S7).
If it is determined that there are two battery packs 1 that need to be charged (S7: YES), the number of battery packs 1 to which the maximum output power (200 W) of the fuel cell 5 is attached (2 in this embodiment). The second charging mode for charging each battery pack 1 is executed using the value (100 W) divided by) as charging power (S9).
When it is determined that there are not two battery packs 1 that need charging, that is, one battery pack 1 that needs to be charged (S7: NO), the charging power of each charging port 15A, 15B is 100 W or less. (Second charging mode) is released (S11).
The charging device 10 according to the present embodiment operates in the charging mode in either the first charging mode or the second charging mode. Therefore, when the second charging mode is canceled, the charging mode is automatically set to the first charging mode. Switch to charging mode. Similarly, when the first charging mode is canceled, the charging mode automatically shifts to the second charging mode.
When the second charging mode is released (S11), it is determined whether or not there are two battery packs 1 that need to be charged (S13). When it is determined that two battery packs 1 need to be charged (S13: YES), the second charging mode is executed (S9).
If it is determined that there are not two battery packs 1 that require charging (S13: NO), it is determined whether there is one battery pack 1 that requires charging (S15). When it is determined that there is one battery pack 1 that needs to be charged (S15: YES), S11 is executed, and the charging mode becomes the first charging mode.
When it is determined that there is not one battery pack 1 that needs to be charged (S15: NO), since the battery pack 1 is not attached to the attachment unit 15, the process returns to S1 again.
3. Characteristics of Charging Device According to this Embodiment In this embodiment, since the charging power to one or a plurality of battery packs 1 mounted on the mounting unit 15 is controlled based on the battery information, the maximum output power of the fuel cell 5 Charging suitable for each secondary battery 2 becomes possible while effectively using. Therefore, it may be possible to charge a plurality of secondary batteries 2 efficiently.
1. Outline of Charging Device According to this Embodiment In this embodiment, the charging device is installed based on the permissible charging power for each battery pack 1 acquired via each signal port 15C, 15D, that is, the required charging power for each battery pack 1. The charging power to each battery pack 1 attached to the unit 15 is controlled. Specifically, the control unit 11 increases the charging power for the battery pack 1 having a large required charging power as compared with the charging power for the battery pack 1 having a small required charging power.
2. Details of Charging Control FIG. 4 is a flowchart showing charging control according to the present embodiment, and illustrates an example in which the maximum output power of the fuel cell 5 is 200 W and the required charging power of the battery pack 1 is 200 W or less. Is.
The charge control shown in FIG. 4 is stored in advance in the non-volatile storage unit, and is read and activated by the CPU when the activation switch of the charging apparatus 10 is turned on. When the start switch is cut off, the charging control is stopped at that time.
When the charging control is activated, it is determined based on the battery information whether or not the battery pack 1 that needs to be charged is connected to either the first charging port 15A or the second charging port 15B (S21). Note that the battery pack 1 that needs to be charged includes an uncharged battery pack 1, that is, a new battery pack 1.
When it is determined that the battery pack 1 that requires charging is not connected to either the first charging port 15A or the second charging port 15B (S21: NO), the first charging circuit 17A and the second charging circuit In any one of the charging circuits of 17B, it is determined whether or not the state where the charging power is not output continues for a predetermined time (for example, 1 minute) or longer (S23).
When it is determined that the state where the charging power is not output continues for a predetermined time or more (S23: YES), the charging circuit which is determined that the state where the charging power is not output continues for a predetermined time or more After entering the stop state (S25), S21 is executed. If it is determined that the state where the charging power is not output has not continued for a predetermined time or longer (S23: NO), S21 is executed without stopping the charging circuit.
When it is determined that the battery pack 1 that requires charging is connected to either the first charging port 15A or the second charging port 15B (S21: YES), two battery packs 1 that require charging are present. Is determined (S27).
If it is determined that there are two battery packs 1 that need to be charged (S27: YES), one of the two battery packs 1 attached to the attachment unit 15 has a predetermined first charge power. It is determined whether or not the power is equal to or lower than power (S29).
The first power is a value obtained by dividing the maximum output power of the fuel cell 5 by the number of battery packs 1 attached to the attachment portion 15. Therefore, the predetermined power according to the present embodiment is a value obtained by dividing 200 W by 2, that is, 100 W.
If any of the plurality (two) of battery packs 1 attached to the attachment unit 15 is not equal to or less than the first power, that is, if the required charge power of any of the battery packs 1 is greater than the first power. If it is determined (S29: NO), the second charging mode for charging each battery pack 1 in a state where the charging power is limited to the first power (100W) is executed (S31).
If it is determined that one of the two battery packs 1 attached to the attachment unit 15 has a required charging power equal to or lower than the first power (S29: YES), the battery attached to the first charging port 15A Whether the required charging power of pack 1 (hereinafter referred to as battery pack A) is greater than the required charging power of battery pack 1 (hereinafter referred to as battery pack B) attached to second charging port 15B. Determination is made (S33).
When it is determined that the required charging power of the battery pack A is larger than the required charging power of the battery pack B (S33: YES), (a) charging output from the second charging circuit 17B (second charging port 15B) (B) The charging power output from the first charging circuit 17A (first charging port 15A) is defined as “charging output from the maximum output power to the second charging circuit 17B”. The third charging mode is set to “a value obtained by reducing power” (S35).
When it is determined that the required charging power of the battery pack A is not larger than the required charging power of the battery pack B, that is, the required charging power of the battery pack A is less than or equal to the required charging power of the battery pack B (S33: NO), (c) the charging power output from the first charging circuit 17A (first charging port 15A) is the required charging power of the battery pack A, and (d) the second charging circuit 17B (second charging port 15B) The fourth charging mode is executed in which the charging power output from (1) is “a value obtained by subtracting the charging power output from the first charging circuit 17A from the maximum output power” (S37).
When it is determined that there are not two battery packs 1 that need charging, that is, one battery pack 1 that needs to be charged (S27: NO), the charging power of each charging port 15A, 15B is set to the above The second charging mode limited to 1 power or less is canceled and the first charging mode is set (S39).
When the second charging mode is released (S39), it is determined whether or not there are two battery packs 1 that need to be charged (S41). When it is determined that two battery packs 1 need to be charged (S41: YES), the second charging mode is executed (S31).
When it is determined that there are not two battery packs 1 that need charging (S41: NO), it is determined whether there is one battery pack 1 that needs charging (S43). If it is determined that there is one battery pack 1 that needs to be charged (S43: YES), S39 is executed, and the charging mode becomes the first charging mode.
When it is determined that there is not one battery pack 1 that needs to be charged (S43: NO), since the battery pack 1 is not attached to the attachment unit 15, the process returns to S21 again.
3. Characteristics of Charging Device According to this Embodiment In this embodiment, the charging power to one or a plurality of battery packs 1 attached to the attachment unit 15 is controlled based on the required charging power for each battery pack 1. Charging suitable for each secondary battery 2 is possible while effectively utilizing the maximum output power of the fuel cell 5. Therefore, it may be possible to charge a plurality of secondary batteries 2 efficiently.
1. Overview of Charging Device According to the Present Embodiment In the present embodiment, the battery pack 1 to be charged is selected based on the battery information from among the plurality of battery packs 1 mounted on the mounting unit 15 and is charged to the mounting unit 15. Among the plurality of battery packs 1 that are mounted, charging is performed in order from the battery pack 1 that is mounted to the mounting unit 15 first.
2. Details of Charging Control FIG. 5 is a flowchart showing charging control according to the present embodiment, and illustrates the case where the maximum output power of the fuel cell 5 is 200 W and the required charging power of the battery pack 1 is 200 W or less. Is.
The charge control shown in FIG. 5 is stored in advance in the non-volatile storage unit, and is read and activated by the CPU when the activation switch of the charging apparatus 10 is turned on. When the start switch is cut off, the charging control is stopped at that time.
When the charging control is activated, it is determined based on the battery information whether or not the battery pack 1 that requires charging is connected to either the first charging port 15A or the second charging port 15B (S51). . Note that the battery pack 1 that needs to be charged includes an uncharged battery pack 1, that is, a new battery pack 1.
When it is determined that the battery pack 1 that requires charging is not connected to either the first charging port 15A or the second charging port 15B (S51: NO), the first charging circuit 17A and the second charging circuit In any one of the charging circuits 17B, it is determined whether or not the state where the charging power is not output continues for a predetermined time (for example, 1 minute) or longer (S53).
When it is determined that the state where the charging power is not output continues for a predetermined time or more (S53: YES), the charging circuit which is determined that the state where the charging power is not output continues for a predetermined time or more After entering the stop state (S55), S51 is executed. If it is determined that the state where the charging power is not output has not continued for a predetermined time or longer (S53: NO), S51 is executed without stopping the charging circuit.
When it is determined that the battery pack 1 that needs to be charged is connected to either the first charging port 15A or the second charging port 15B (S51: YES), the charging port setting is executed (S57). .
That is, in S57, the charging port to which the battery pack 1 is first attached is set as the charging port A among the charging ports, and the other charging port is set as the charging port B. Hereinafter, the charging circuit corresponding to the charging port A in the first charging circuit 17A and the second charging circuit 17B is referred to as a charging circuit A, and the charging circuit corresponding to the charging port B is referred to as a charging circuit B.
When S57 is executed, it is determined whether or not the required charging power acquired from the battery pack 1 attached to the charging port A (hereinafter referred to as battery pack A) is greater than or equal to the maximum output power (200 W) ( S59). The battery pack 1 attached to the charging port B is hereinafter referred to as a battery pack B.
When it is determined that the required charging power of the battery pack A is greater than or equal to the maximum output power (200 W) (S59: YES), the control unit 11 limits the output of the charging circuit B to 0 and The battery pack A is charged with the output as the maximum output power (200 W) (S61).
If it is determined that the required charging power of the battery pack A is not equal to or greater than the maximum output power (200 W) (S59: NO), whether or not the charging circuit A is outputting, that is, charging the battery pack A is executed. It is determined whether it has been performed (S63).
When it is determined that the charging circuit A is outputting (S63: YES), the output of the charging circuit B is “a value obtained by subtracting the necessary charging power required by the battery pack A from the maximum output power (200 W) (hereinafter referred to as“ charging power ”). , “Set output B”) ”(S65). When the required charging power required by the battery pack B is smaller than the set output B, the output of the charging circuit B becomes the required charging power required by the battery pack B.
When it is determined that the charging circuit A is not outputting, that is, when the charging to the battery pack A is completed (S63: NO), the restriction to set the output of the charging circuit B to 0 is released, and the battery pack B Charging is started (S67).
At this time, the output of the charging circuit B becomes the necessary charging power required by the battery pack B. As a result, among the plurality of battery packs 1 mounted on the mounting unit 15, the battery packs 1 that are mounted on the mounting unit 15 earliest are charged in order.
3. Characteristics of Charging Device According to the Present Embodiment In the present embodiment, the battery pack 1 to be charged is selected based on the battery information from among the plurality of battery packs 1 mounted on the mounting unit 15 and charged to the mounting unit 15. Among the plurality of battery packs 1 that are mounted, the battery packs 1 are charged in order from the battery pack 1 that is mounted first to the mounting unit 15, so that the maximum output power of the fuel cell 5 is effectively used while the plurality of secondary batteries 2 are It may be possible to charge efficiently.
1. Outline of Charging Device According to this Embodiment In the above-described embodiment, the required charging power is determined by the battery control unit of the battery pack 1, and the charging device 10 acquires the determined required charging power as battery information. .
In contrast, the charging device 10 according to the present embodiment acquires (a) state information of the secondary battery 2 and (b) identification information indicating the type of the battery pack 1 (secondary battery 2) as battery information. At the same time, the charging power for each battery pack 1 is determined using the acquired battery information.
That is, in the above-described embodiment, the charging device 10 according to the present embodiment has battery information such as state information, although the charging mode in which charging is performed using the necessary charging power acquired from the battery pack 1 as charging power. The charging device 10 itself has a charging mode in which the power corresponding to the required charging power is determined and charging is performed using the determined power as the charging power.
2.1 Details of Charging Control FIG. 6 is a flowchart showing charging control according to the present embodiment. The maximum output power of the fuel cell 5 is 200 W, and the maximum charging power when charging the battery pack 1 is 200 W or less. A case is illustrated by way of example.
The charge control shown in FIG. 6 is stored in advance in the non-volatile storage unit, and is read and activated by the CPU when the activation switch of the charging apparatus 10 is turned on. When the start switch is cut off, the charging control is stopped at that time.
When the charging control is activated, it is determined based on the battery information whether or not the battery pack 1 that needs to be charged is connected to either the first charging port 15A or the second charging port 15B (S71). Note that the battery pack 1 that needs to be charged includes an uncharged battery pack 1, that is, a new battery pack 1.
When it is determined that the battery pack 1 that requires charging is not connected to either the first charging port 15A or the second charging port 15B (S71: NO), the first charging circuit 17A and the second charging circuit In any one of the charging circuits 17B, it is determined whether or not the state where the charging power is not output continues for a predetermined time (for example, 1 minute) or longer (S73).
When it is determined that the state where the charging power is not output continues for a predetermined time or longer (S73: YES), the charging circuit which is determined that the state where the charging power is not output continues for a predetermined time or longer is determined. After entering the stop state (S75), S71 is executed. If it is determined that the state where the charging power is not output has not continued for a predetermined time or longer (S73: NO), S71 is executed without stopping the charging circuit.
When it is determined that the battery pack 1 that requires charging is connected to either the first charging port 15A or the second charging port 15B (S71: YES), two battery packs 1 that require charging are present. It is determined whether or not (S77).
When it is determined that there are two battery packs 1 that need to be charged (S77: YES), after the identification information and status information regarding each battery pack 1 are acquired via each information output unit 3 (S79). The charging power for each battery pack 1 is determined by the control unit 11 based on the acquired battery information (S81).
The details of “determination method of charging power using acquired battery information” executed by the control unit 11, that is, the details of S81 will be described later.
Next, it is determined whether or not the charging power of any of the two battery packs 1 mounted on the mounting unit 15 is equal to or lower than the first power described above (S83). When it is determined that any one of the plurality (two) of battery packs 1 mounted on the mounting unit 15 is not less than or equal to the first power (S83: NO), the charging power is set to the first power (100W). ), The second charging mode for charging each battery pack 1 is executed (S85).
When it is determined that any one of the two battery packs 1 attached to the attachment unit 15 has the first power or less (S83: YES), the battery pack attached to the first charging port 15A. It is determined whether the charging power of 1 (hereinafter referred to as battery pack A) is greater than the charging power of the battery pack 1 (hereinafter referred to as battery pack B) attached to the second charging port 15B. (S87).
When it is determined that the charging power of the battery pack A is larger than the charging power of the battery pack B (S87: YES), (a) the output of the second charging circuit 17B (second charging port 15B) is supplied to the battery pack B. The fifth charging mode is executed in which the charging power is set and (b) the output of the first charging circuit 17A (first charging port 15A) is “a value obtained by subtracting the output of the second charging circuit 17B from the maximum output power”. (S89).
When it is determined that the charging power of the battery pack A is not greater than the charging power of the battery pack B (S87: NO), (c) the output of the first charging circuit 17A (first charging port 15A) is used as the battery pack. A charging power of A, and (d) a sixth charging mode in which the output of the second charging circuit 17B (second charging port 15B) is “a value obtained by subtracting the output of the first charging circuit 17A from the maximum output power”. It is executed (S91).
When it is determined that there are not two battery packs 1 that need charging, that is, one battery pack 1 that needs to be charged (S77: NO), the charging power of each charging port 15A, 15B is set to the above The second charging mode limited to 1 power or less is canceled and the first charging mode is set (S93).
When the second charging mode is released (S93), it is determined whether or not there are two battery packs 1 that need to be charged (S95). When it is determined that there are two battery packs 1 that need to be charged (S95: YES), S79 is executed.
If it is determined that the number of battery packs 1 that require charging is not 2 (S95: NO), it is determined whether or not the number of battery packs 1 that require charging is one (S97). When it is determined that there is one battery pack 1 that needs to be charged (S97: YES), S93 is executed, and the charging mode becomes the first charging mode.
If it is determined that there is not one battery pack 1 that needs to be charged (S97: NO), since the battery pack 1 is not attached to the attachment unit 15, the process returns to S71 again.
2.2 Determination Method of Charging Power Using Acquired Battery Information <Determination of Charging Power Using Identification Information (see FIG. 7)>
The secondary battery 2 of the battery pack 1 according to the present embodiment is configured by connecting a plurality of battery cells (hereinafter also referred to as unit batteries) in series and in parallel.
Therefore, the identification information, that is, the type of the secondary battery 2 depends on the number of unit batteries connected in series (hereinafter referred to as a series unit), the number of series units connected in parallel, and the output power of the unit battery. Identified. Note that the charging device 10 according to the present embodiment can cope with the battery pack 1 with an output power of 5 W and the battery pack 1 with an output power of 10 W.
In the determination control of the charging power using the identification information, as shown in FIG. 7, as the identification information, the number of unit cells connected in series, the number of series units connected in parallel, and the unit battery After the output power is acquired (S100), it is determined whether the output power is 10 W (S102).
When it is determined that the output power is 10 W (S102: YES), 10 is input to the variable indicating the rated power (S104). If it is determined that the output power is not 10 W (S102: NO), 5 is input to the variable indicating the rated power (S106).
Then, the value obtained by multiplying the number of unit cells connected in series, the number of series units connected in parallel, and the rated output is set as the charging power (S108).
<Determination of charging power using status information (see FIG. 8)>
As the status information, after the temperature of the secondary battery 2, the voltage of the secondary battery 2, and the total number of times of charging are acquired (S110), the temperature of the secondary battery 2 is equal to or higher than a first predetermined temperature (for example, 10 ° C.). It is determined whether or not there is (S112).
When it is determined that the temperature of the secondary battery 2 is equal to or higher than the first predetermined temperature (for example, 10 ° C.) (S112: YES), the charging current is set to the first current value (for example, 3A) ( S114). When it is determined that the temperature of the secondary battery 2 is lower than the first predetermined temperature (S112: NO), the charging current is set to a second current value (for example, 1A) smaller than the first current value ( S116).
Next, it is determined whether or not the total number of times of charging is a predetermined number (for example, 300 times) or more (S118). If it is determined that the total number of times of charging is equal to or greater than the predetermined number of times (S118: YES), the charging current is set to a third current value (for example, 1A) smaller than the first current value (S120). .
When it is determined that the total number of times of charging is less than the predetermined number (S118: NO), the charging current set in S114 or S116 is held. Then, the value obtained by multiplying the voltage of the secondary battery 2 by the charging current is used as the charging power (S122).
3. Characteristics of Charging Device According to this Embodiment In this embodiment, the charging power to one or a plurality of battery packs 1 attached to the attachment unit 15 is controlled based on the state information and identification information for each battery pack 1. Therefore, it is possible to charge each secondary battery 2 while effectively using the maximum output power of the fuel cell 5. Therefore, it may be possible to charge a plurality of secondary batteries 2 efficiently.
1. Outline of Charging Device According to this Embodiment This embodiment is a modification of the fourth embodiment. In other words, the charging device 10 according to the present embodiment uses the battery information such as the state information to determine the power corresponding to the required charging power by the charging device 10 itself, and based on the determined power based on the charging power. The battery pack 1 to be charged is selected and the charging mode is executed for charging.
2. Details of Charging Control FIG. 9 is a flowchart showing charging control according to the present embodiment, in which the maximum output power of the fuel cell 5 is 200 W and the maximum charging power when charging the battery pack 1 is 200 W or less. This is illustrated in the example.
The charging control shown in FIG. 9 is stored in advance in the non-volatile storage unit, and is read and activated by the CPU when the activation switch of the charging apparatus 10 is turned on. When the start switch is cut off, the charging control is stopped at that time.
When the charging control is activated, it is determined based on the battery information whether or not the battery pack 1 that requires charging is connected to either the first charging port 15A or the second charging port 15B (S131). . Note that the battery pack 1 that needs to be charged includes an uncharged battery pack 1, that is, a new battery pack 1.
When it is determined that the battery pack 1 that requires charging is not connected to either the first charging port 15A or the second charging port 15B (S131: NO), the first charging circuit 17A and the second charging circuit In any one of the charging circuits 17B, it is determined whether or not the state where the charging power is not output continues for a predetermined time (for example, 1 minute) or longer (S133).
When it is determined that the state where the charging power is not output continues for a predetermined time or longer (S133: YES), the charging circuit that is determined that the state where the charging power is not output continues for a predetermined time or longer is determined. After entering the stop state (S135), S131 is executed. If it is determined that the state where the charging power is not output has not continued for a predetermined time or longer (S133: NO), S131 is executed without stopping the charging circuit.
When it is determined that the battery pack 1 that requires charging is connected to either the first charging port 15A or the second charging port 15B (S131: YES), two battery packs 1 that require charging are present. It is determined whether or not (S137).
When it is determined that there are two battery packs 1 that need to be charged (S137: YES), after the identification information and status information regarding each battery pack 1 are acquired via each information output unit 3 (S139) ), Charging power for each battery pack 1 is determined based on the acquired battery information (S141).
The “determination method of charging power using acquired battery information” executed by the control unit 11 is the same as that in the fourth embodiment.
It is determined whether or not the charging power of any of the two battery packs 1 mounted on the mounting unit 15 is equal to or greater than the maximum output power (200 W) (S143). When it is determined that the charging power of any battery pack 1 is less than the maximum output power (S143: NO), the charging power of either of the two battery packs 1 mounted on the mounting unit 15 is as described above. It is determined whether or not the power is equal to or lower than the first power (S145).
When it is determined that any one of the plurality (two) of battery packs 1 mounted on the mounting unit 15 is not less than or equal to the first power (S145: NO), the charging power is set to the first power (100 W). ), The second charging mode for charging each battery pack 1 is executed (S147).
When it is determined that one of the two battery packs 1 attached to the attachment unit 15 has a charging power equal to or lower than the first power (S145: YES), the battery pack attached to the first charging port 15A. It is determined whether the charging power of 1 (hereinafter referred to as battery pack A) is greater than the charging power of the battery pack 1 (hereinafter referred to as battery pack B) attached to the second charging port 15B. (S149).
When it is determined that the charging power of the battery pack A is larger than the charging power of the battery pack B (S149: YES), (a) the output of the second charging circuit 17B (second charging port 15B) is supplied to the battery pack B. The fifth charging mode is executed in which the charging power is set and (b) the output of the first charging circuit 17A (first charging port 15A) is “a value obtained by subtracting the output of the second charging circuit 17B from the maximum output power”. (S151).
When it is determined that the charging power of the battery pack A is not greater than the charging power of the battery pack B (S149: NO), (c) the output of the first charging circuit 17A (first charging port 15A) is used as the battery pack. A charging power of A, and (d) a sixth charging mode in which the output of the second charging circuit 17B (second charging port 15B) is “a value obtained by subtracting the output of the first charging circuit 17A from the maximum output power”. This is executed (S153).
When it is determined in S143 that one of the two battery packs 1 attached to the attachment unit 15 has a maximum output power (200W) or more (S143: YES), the charging power is 200W. The output of the charging circuit (the first charging circuit 17A or the second charging circuit 17B) to which the battery pack 1 determined to be less than is connected is stopped (S155).
That is, in S155, the battery pack 1 whose charging power is determined to be 200 W or more is selected, and the selected battery pack 1 is charged with the maximum output power. If any of the battery packs 1 has a charging power equal to or greater than the maximum output power (200 W), the battery pack 1 that is mounted earliest to the mounting unit 15 is selected and S155 is executed.
When it is determined that there are not two battery packs 1 that require charging, that is, one battery pack 1 that requires charging (S137: NO), the charging power of each charging port 15A, 15B is set to The second charging mode limited to 1 power or less, or the output stop of the charging circuit (S155) is canceled and the first charging mode is set (S157).
When the second charging mode is released (S157), it is determined whether or not there are two battery packs 1 that need to be charged (S159). If it is determined that there are two battery packs 1 that require charging (S159: YES), S139 is executed.
If it is determined that there are not two battery packs 1 that need charging (S159: NO), it is determined whether there is one battery pack 1 that needs charging (S161). When it is determined that there is one battery pack 1 that needs to be charged (S161: YES), S157 is executed and the charging mode becomes the first charging mode. As a result, charging of the battery pack 1 connected to the charging circuit whose output is stopped in S155 is started.
If it is determined that there is not one battery pack 1 that needs to be charged (S161: NO), since the battery pack 1 is not attached to the attachment unit 15, the process returns to S131 again.
3. Characteristics of Charging Device According to this Embodiment In this embodiment, the charging device 10 according to this embodiment determines the power corresponding to the necessary charging power by using the battery information such as the state information. At the same time, since the battery pack 1 that charges the determined power based on the charging power is selected and charged, the battery pack 1 is suitable for each secondary battery 2 while effectively using the maximum output power of the fuel cell 5. Can be recharged. Therefore, it may be possible to charge a plurality of secondary batteries 2 efficiently.
In the above-described embodiment, the detachable fuel cartridge 4 is filled with fuel. However, the present invention is not limited to this. For example, the present invention is also applicable to a stationary power supply device that supplies fuel by piping. it can.
Although the fuel cell 5 according to the above-described embodiment is a direct methanol fuel cell, the present invention is not limited to this, and may be a fuel cell of another type.
Although the secondary battery 9 according to the above-described embodiment is a lithium ion battery, the present invention is not limited to this, and may be another secondary battery or a capacitor.
In the third embodiment, among the plurality of battery packs 1 attached to the attachment part 15, the battery pack 1 attached to the attachment part 15 is selected and charged earliest, but the present invention is limited to this. is not.
For example, among the plurality of battery packs 1 attached to the attachment unit 15, the battery pack having the largest required charging power may be selected and charged, and the battery packs may be charged in order from the selected battery pack. That is, which battery pack should be charged first may be selected based on the battery information, and the battery packs may be charged in order from the selected battery pack.
The present invention is not limited to the above-described embodiment as long as it matches the gist of the invention described in the claims. Therefore, you may combine with at least 2 embodiment among several embodiment mentioned above.
DESCRIPTION OF SYMBOLS 1 ... Battery pack 2 ... Secondary battery 3 ... Information output part 4 ... Fuel cartridge 4A ... Solenoid valve 5 ... Fuel cell 7 ... Charging circuit 9 ... Secondary battery 10 ... Charging apparatus 11 ... Control part 13 ... Casing 13A ... Intake port 13B ... Fan 15 ... Mounting part 15A, 15B ... Charging port 15C, 15D ... Signal port
In a charging device for a battery pack for an electric tool in which a chargeable / dischargeable secondary battery and an information output unit capable of outputting information on the secondary battery are integrated,
A mounting portion having a plurality of charging ports to which the battery pack can be detachably mounted;
A fuel cell that generates electric power by oxidizing a fuel and an oxidant; and
An information acquisition unit for acquiring information on the battery pack mounted on the mounting unit from the information output unit;
A battery pack for an electric tool, comprising: a control unit that controls charging power to one or a plurality of battery packs mounted on the mounting unit based on information acquired by the information acquisition unit. Charging device.
Charging of a battery pack for an electric tool in which a chargeable / dischargeable secondary battery and an information output unit capable of outputting information related to power when charging the secondary battery (hereinafter referred to as allowable charging power) are integrated In the device
An information acquisition unit that acquires the allowable charging power of the battery pack mounted on the mounting unit from the information output unit;
A control unit that controls charging power to one or a plurality of battery packs mounted on the mounting unit based on the allowable charging power acquired by the information acquisition unit and the power that can be output by the fuel cell; A battery pack charging device for an electric tool, comprising:
The said control part has charge mode which charges each battery pack by the value which remove | divided the electric power which can be output with the said fuel cell by the number of the said battery packs with which the said mounting part was mounted | worn. The battery pack charging device for an electric tool as described.
A control unit that controls charging power to each battery pack mounted on the mounting unit based on an allowable charging power for each battery pack acquired by the information acquisition unit. Battery pack charger.
5. The battery pack for an electric tool according to claim 4, wherein the control unit increases the charging power for the battery pack having a large allowable charging power as compared with the charging power for the battery pack having a small allowable charging power. Charging device.
In a battery pack charging device for a power tool in which a chargeable / dischargeable secondary battery and an information output unit capable of outputting information for identifying the type of the secondary battery (hereinafter referred to as identification information) are integrated,
An information acquisition unit for acquiring identification information of the battery pack mounted on the mounting unit from the information output unit;
A power tool battery comprising: a control unit that controls charging power to each battery pack mounted on the mounting unit based on identification information for each battery pack acquired by the information acquisition unit. Pack charging device.
In a charging device for a battery pack for an electric tool, in which a chargeable / dischargeable secondary battery and an information output unit capable of outputting information indicating the state of the secondary battery (hereinafter referred to as state information) are integrated,
An information acquisition unit for acquiring state information of the battery pack attached to the attachment unit from the information output unit;
A battery for a power tool, comprising: a control unit that controls charging power to each battery pack mounted on the mounting unit based on state information for each battery pack acquired by the information acquisition unit. Pack charging device.
The electric information according to claim 7, wherein the state information is information including at least one of information indicating the temperature of the secondary battery and information indicating the number of times of charging the secondary battery. Battery charger for tools.
A battery for an electric tool, comprising: a control unit that selects and charges a battery pack to be charged from among a plurality of battery packs mounted on the mounting unit based on information acquired by the information acquisition unit. Pack charging device.
The charging of the battery pack for an electric tool according to claim 9, wherein the control unit has a charging mode in which charging is performed in order from the battery pack that is first installed in the mounting unit among the plurality of selected battery packs. apparatus.
In a battery pack charging device for a power tool having a rechargeable secondary battery,
A charging device for a battery pack for an electric tool, comprising: a control unit that sequentially charges the battery packs that are mounted on the mounting unit first from the battery packs mounted on the mounting unit.
A control unit that selects and charges a battery pack to be charged from among a plurality of battery packs mounted on the mounting unit based on identification information for each battery pack acquired by the information acquisition unit. A battery pack charging device for an electric tool.
A control unit that selects and charges a battery pack to be charged from among a plurality of battery packs mounted on the mounting unit based on state information for each battery pack acquired by the information acquisition unit. A battery pack charging device for an electric tool.
JP2014026568A 2014-02-14 2014-02-14 Battery pack charger for electric power tool Pending JP2015154600A (en)
JP2014026568A JP2015154600A (en) 2014-02-14 2014-02-14 Battery pack charger for electric power tool
US14/614,870 US20150236532A1 (en) 2014-02-14 2015-02-05 Charging device for battery pack for power tool
DE102015001867.1A DE102015001867A1 (en) 2014-02-14 2015-02-12 Charger for a battery pack for a motor vehicle
JP2015154600A true JP2015154600A (en) 2015-08-24
ID=53758996
JP2014026568A Pending JP2015154600A (en) 2014-02-14 2014-02-14 Battery pack charger for electric power tool
US (1) US20150236532A1 (en)
JP (1) JP2015154600A (en)
DE (1) DE102015001867A1 (en)
JP2002238178A (en) * 2001-02-14 2002-08-23 Sony Corp Power supply and method, program storage medium and program
JP2006128088A (en) * 2004-09-30 2006-05-18 Hitachi Ltd Power supply apparatus using fuel cell and control method of the same
JP2007236041A (en) * 2006-02-28 2007-09-13 Hitachi Koki Co Ltd Charger
JP2011115031A (en) * 2009-11-30 2011-06-09 Toshiba Corp Power supply apparatus, system, and charge and discharge control method
JP2011155737A (en) * 2010-01-26 2011-08-11 Toyota Motor Corp Battery charging device
WO2011162357A1 (en) * 2010-06-23 2011-12-29 株式会社マキタ Power supply device for power tool
CA2617710C (en) * 2007-01-12 2015-01-06 Koehler-Bright Star, Inc. Battery pack for miner's cap lamp with charging and discharging control module
JPWO2011070746A1 (en) * 2009-12-10 2013-04-22 パナソニック株式会社 Fuel cell system and electronic device
2014-02-14 JP JP2014026568A patent/JP2015154600A/en active Pending
2015-02-05 US US14/614,870 patent/US20150236532A1/en not_active Abandoned
2015-02-12 DE DE102015001867.1A patent/DE102015001867A1/en active Pending
US20150236532A1 (en) 2015-08-20
DE102015001867A1 (en) 2015-08-20
CA2546788C (en) 2012-05-29 Portable self-contained electric power tool
JP2005354889A (en) 2005-12-22 Reduction of switches in cordless power tool
EP2207249B1 (en) 2015-07-22 Control method for an accumulator and a hand tool machine
CN201266841Y (en) 2009-07-01 Battery set
US8274261B2 (en) 2012-09-25 Cell monitoring and balancing
DE10223188A1 (en) 2003-01-09 Direct current or DC power source unit with a battery charging function