JP7334548B2 - Charging device and charging method - Google Patents

Description

The present invention relates to a charging device and charging method.

2. Description of the Related Art There is known a charging device that charges a secondary battery with remaining power other than power supplied to a load, which is supplied by a power supply having a limited power supply. In addition, based on the difference between the maximum allowable current for the power supply and the detected current consumption of the load, the secondary battery is charged with the maximum charge current allowed for the power supply, shortening the time it takes to reach full charge. A technique for doing so is disclosed.

Incidentally, an image forming apparatus or the like is provided with both a first DC power supply that supplies power to a control system and a second DC power supply that has a higher voltage than the first DC power supply and supplies power to a drive system. For example, in an image forming apparatus that includes a secondary battery and a charging device and in which the second DC power supply is turned off during sleep mode, the secondary battery cannot be charged using the second DC power supply during sleep mode.

Therefore, in this type of image forming apparatus, the first DC power supply, which is always supplied with power regardless of the operation mode, is used for charging the secondary battery, and the second DC power supply is not used for charging the secondary battery. In this case, since the second DC power supply, which has a higher output voltage than the first DC power supply, cannot be used to charge the secondary battery, charging cannot be performed by making the most of the power supply capacity, and charging time is lengthened. be.

The present invention has been made in view of the above problems, and an object of the present invention is to improve the charging efficiency of a secondary battery and shorten the charging time.

In order to solve the above technical problem, a charging device according to one aspect of the present invention includes a booster circuit that boosts a first DC voltage generated by a first DC power supply to generate a boosted voltage; A first charging part that supplies a first charging current to the secondary battery, and a second charging current that is input from a second DC power supply that generates a second DC voltage higher than the first DC voltage to the secondary battery. 2 charging units ;
a switching unit that connects the output of the first DC power supply or the output of the booster circuit to the input of the first charging unit; When the charging efficiency of the secondary battery is lower than the charging efficiency of the secondary battery by only the first DC current of the first DC power supply, the switching unit is controlled to connect the output of the first DC power supply to the input of the first charging unit, 2 a switching control unit for stopping charging of the secondary battery by the charging unit , wherein the boosted voltage generated by the booster circuit is equal to the second DC voltage.

It is possible to shorten the charging time by improving the charging efficiency of the secondary battery.

1 is a block diagram showing an example of an image forming apparatus equipped with a charging device according to a first embodiment of the invention; FIG. FIG. 2 is a block diagram showing an example of elements related to power supply of the image forming apparatus of FIG. 1; 3 is a block diagram showing an example of the charging device of FIG. 2; FIG. 4 is a timing chart showing an example of charging control of a secondary battery by the charging device of FIG. 3; FIG. 2 is an explanatory diagram showing an example of a state for each operation mode of the image forming apparatus of FIG. 1; FIG. 4 is a flow diagram showing an example of the operation of the charging device of FIG. 3; FIG. FIG. 5 is a block diagram showing an example of a charging device according to a second embodiment of the invention; FIG. 8 is an explanatory diagram showing an example of a state for each operation mode of the charging device of FIG. 7; FIG. 8 is a flow chart showing an example of the operation of the charging device of FIG. 7; FIG. 11 is a block diagram showing an example of a charging device according to a third embodiment of the invention; FIG. 11 is a flow chart showing an example of the operation of the charging device of FIG. 10; FIG. 11 is a block diagram showing an example of a charging device according to a fourth embodiment of the invention; FIG. 13 is a flow chart showing an example of the operation of the charging device of FIG. 12;

Hereinafter, embodiments will be described with reference to the drawings. In addition, in each drawing, the same code|symbol may be attached|subjected to the same component part, and the overlapping description may be abbreviate|omitted. "Voltage" is also used to indicate a voltage value, and "power" is also used to indicate a power value.

(First embodiment)
FIG. 1 is a block diagram showing an example of an image forming apparatus equipped with a charging device according to the first embodiment of the invention. An image forming apparatus 100 shown in FIG. 1 is a multifunction machine called an MFP (MultiFunction Printer). That is, the image forming apparatus 100 has a copy function, a facsimile function, a print function, a scanner function, and a function of storing and distributing an image input by the scanner function and the facsimile function.

The image forming apparatus 100 can also communicate with an external device such as a PC (Personal Computer), and can perform operations according to instructions received from the external device. The “image” processed by the image forming apparatus 100 is not limited to image data, and may include text data that does not include image data. FIG. 1 shows a part of the image forming apparatus 100 as seen through.

The image forming apparatus 100 adheres toner to an electrostatic latent image written by selectively exposing the surface of a charged photoreceptor, and transfers the adhered toner to a recording medium such as paper. This is an electrophotographic image forming apparatus. The image forming apparatus 100 has an operation panel 1, a start switch 2, a controller 3, a reading section 4, an engine control section 5, a printer unit 6, paper feed cassettes 7A and 7B, and a transport unit 8. .

The operation panel 1 accepts various inputs according to user's operations, and also displays various kinds of information (for example, information indicating the accepted operation, information indicating the operation status of the image forming apparatus 100, and setting status of the image forming apparatus 100). , etc.). The operation panel 1 is composed of, for example, a liquid crystal display (LCD: Liquid Crystal Display) equipped with a touch panel function, but is not limited to this. For example, an organic EL (Electro-Luminescence) display device equipped with a touch panel function may be used. Furthermore, the image forming apparatus 100 may have an operation unit such as hardware keys and a display unit such as an LED (Light Emitting Diode).

Start switch 2 starts image forming apparatus 100 when pressed by a user while image forming apparatus 100 is powered off. When the user presses the button while the image forming apparatus 100 is activated, that is, when the power is on, the image forming apparatus 100 is turned off.

The controller 3 controls the entire image forming apparatus 100 . For example, the controller 3 causes the image forming apparatus 100 to perform operations according to operations received by the operation panel 1 . Further, the controller 3 causes the image forming apparatus 100 to execute an instruction received by the image forming apparatus 100 from an external device such as a PC. For example, the controller 3 is implemented by a CPU (Central Processing Unit) mounted on a control board together with ROM (Read Only Memory) and RAM (Random Access Memory).

The reading unit 4 has an ADF (Auto Document Feeder) 41 and a scanner unit 42 . The ADF 41 sequentially conveys and optically reads the originals placed on the ADF 41 to generate image data. The scanner unit 42 fixes a document on a transparent document platen and optically reads the fixed document to generate image data. The engine control section 5 generates control signals for controlling the printer unit 6 and the transport unit 8 based on the image data generated by the reading section 4 .

The printer unit 6 functions as an image forming section that forms an image on a recording medium such as paper. The printer unit 6 has a photoreceptor drum 61 as a photoreceptor and a charging member 62 that charges the outer surface of the photoreceptor drum 61 . The printer unit 6 also includes a writing unit 63 that exposes the charged photoreceptor drum 61 based on the image data read by the reading unit 4 and writes an electrostatic latent image on the photoreceptor. and a developer member 64 for developing the latent image with toner. Further, the printer unit 6 has a conveying belt 65 that conveys a recording medium on which a toner image is formed, and a fixing unit 66 that fixes the toner on the recording medium to the recording medium, thereby forming a toner image on the recording medium. .

Paper feed cassettes 7A and 7B accommodate recording media before image formation. In FIG. 1, two paper feed cassettes are provided as an example, and recording media of different sizes are accommodated in each, but image forming apparatus 100 may have only one paper feed cassette, or three You may have the above paper feed cassettes. The transport unit 8 has various rollers, and transports the recording media contained in the paper feed cassettes 7A and 7B to the printer unit 6. As shown in FIG.

Here, the flow of image formation in the image forming apparatus 100 will be described using the copy mode as an example. First, by operating a function switching key or the like on the operation panel 1, the user can sequentially switch and select the copy function, the printer function, and the facsimile function of the image forming apparatus 100, and operate each function. When the copy function is selected, the mode is the copy mode, when the printer function is selected, the printer mode is selected, and when the facsimile function is selected, the facsimile mode is selected. In the copy mode, the image information of each document to be copied is read by the reading section 4 and image data is generated.

The outer peripheral surface of the photoreceptor drum 61 is uniformly charged by the charging member 62 and then exposed to light emitted from the writing unit 63 (indicated by the dotted arrow A in FIG. 1). An electrostatic latent image is formed on the outer peripheral surface of 61 . The developing member 64 visualizes this electrostatic latent image with toner. Thereby, a toner image is formed on the photosensitive drum 61 . The toner image formed on the photosensitive drum 61 is transferred onto the recording medium on the conveying belt 65 . The fixing unit 66 heats and melts the toner of the toner image on the recording medium with heat from a heater or the like, fixes the toner image on the recording medium, and ejects the recording medium from the image forming apparatus 100 .

Although the case where the printer unit 6 forms an image by a monochrome electrophotographic method has been described, a color electrophotographic method, an inkjet method, or the like may be used, and the image forming method is not limited to these.

FIG. 2 is a block diagram illustrating an example of power supply components of the image forming apparatus of FIG. FIG. 2 shows a state in which the image forming apparatus 100 is connected to a commercial power supply AC (Alternating Current). Image forming apparatus 100 includes AC control unit 9 , DC power supply unit 10 , charging device 200 , and secondary battery 104 in addition to the elements shown in FIG. 1 .

The AC control unit 9 supplies the AC voltage input from the commercial power supply AC to the fixing unit 66, for example. The fixing unit 66 is controlled by the engine control unit 5 and performs control such as ON/OFF of a fixing heater supplied with an AC voltage.

The DC power supply unit 10 has a first DC power supply 101 that converts an AC voltage input from a commercial power supply AC into a first DC voltage, and a second DC power supply 102 that converts the AC voltage into a second DC voltage.

The first DC power supply 101 generates a first DC voltage regardless of whether the start switch 2 shown in FIG. 1 is on or off when the commercial power supply AC is input. The output of first DC power supply 101 is connected via charging device 200 to secondary battery 104 and controller 3, which is an example of a first DC load. The first DC power supply 101 is a power supply system that supplies power to the controller 3, and generates a first DC voltage of 5V, for example.

Second DC power supply 102 generates a second DC voltage when activation switch 2 of image forming apparatus 100 is turned on, and does not generate the second DC voltage while image forming apparatus 100 is set to the sleep mode. Stop. The output of the second DC power supply 102 is connected via the charging device 200 to the secondary battery 104 and the engine control section 5 as an example of the second DC load. A second DC power supply 102 supplies a second power supply voltage to the reading section 4 , the printer unit 6 and the transport unit 8 via the engine control section 5 . The second DC load (reading unit 4, printer unit 6, and transport unit 8) includes a drive system such as a motor that rotates transport rollers and the like. The second DC power supply 102 is a power supply system that supplies power to the engine control unit 5, and generates a second DC voltage of 24V, for example.

The charging device 200 controls power supply to the controller 3 by the first DC power supply 101 and charging of the secondary battery 104 by the first DC power supply 101 . Further, the charging device 200 controls power supply to the engine control unit 5 by the second DC power supply 102 and charging of the secondary battery 104 by the second DC power supply 102 .

As described above, when power is supplied to the image forming apparatus 100 from an external power supply such as a commercial power supply AC, power from the first DC power supply 101 is constantly supplied to the controller 3 . Here, since the power used varies depending on the operation content of the controller 3, the secondary battery 104 can be charged by supplying the remaining power, which is power that is not used, to the secondary battery 104 as an auxiliary power supply. .

Further, when power is supplied to the image forming apparatus 100 from an external power supply such as a commercial power supply AC, and the operation mode of the image forming apparatus 100 is other than the sleep mode, the power from the second DC power supply 102 is It is supplied to the engine control unit 5 . Here, since the power used varies depending on the operation contents of the reading unit 4, the printer unit 6, and the transport unit 8 controlled by the engine control unit 5, the remaining power, which is unused power, is supplied to the secondary battery 104. Thus, the secondary battery 104 can be charged. Note that charging of the secondary battery 104 using the first DC power supply 101 and the second DC power supply 102 will be described with reference to FIG. 3 and subsequent figures.

When the power supply to the image forming apparatus 100 is stopped due to a power outage due to a disaster or the like, power is supplied from the secondary battery 104 to the first DC load such as the controller 3 . Here, by providing the controller 3 with a control function of the operation panel 1 and a facsimile control function, the controller 3 can be operated even in the event of a power failure to receive facsimile data and store it in a hard disk drive (not shown) of the image forming apparatus 100 . ), etc. When the power supply is started by a UPS (Uninterruptible Power Supply) capable of supplying AC power, or when the power failure is restored, the facsimile data stored in the HDD or the like can be printed.

FIG. 3 is a block diagram illustrating an example of charging device 200 of FIG. Charging device 200 includes voltage/current detection units 211 and 212, output voltage control unit 220, voltage adjustment/booster circuit 230, charging current control unit 240, chargers 251 and 252, diodes 261 and 262, and charge capacity detection unit 270. have. In FIG. 3, thick lines indicate power supply lines, and thin lines indicate signal lines.

Voltage/current detector 211 is an example of a power detector that detects the power consumption of first DC load 105 . Voltage/current detector 212 is an example of a power detector that detects the power consumption of second DC load 106 . Charger 251 is an example of a first charging section, and charger 252 is an example of a second charging section.

Voltage/current detection unit 211 detects a first DC voltage and a first DC current output by first DC power supply 101, and transmits information indicating values of the detected first DC voltage and first DC current to a charging current control unit. 240 output. Here, the first DC current is the sum of the first load current supplied to the first DC load and the first charging current used to charge the secondary battery 104 .

Voltage/current detection unit 212 detects a second DC voltage and a second DC current output from second DC power supply 102, and transmits information indicating the values of the detected second DC voltage and second DC current to a charging current control unit. 240 output. Voltage/current detection section 212 also outputs information indicating the detected value of the second DC voltage to output voltage control section 220 . Here, the second DC current is the sum of the second load current supplied to the second DC load and the second charging current used to charge the secondary battery 104 .

The output voltage control unit 220 adjusts the boost voltage value to the second DC voltage value based on the value of the second DC voltage detected by the voltage/current detection unit 212 and the value of the boost voltage generated by the voltage adjustment/boost circuit 230. The voltage regulator/boost circuit 230 is controlled so that The voltage adjusting/boosting circuit 230 boosts the first DC voltage from the first DC power supply 101 under the control of the output voltage control unit 220 to generate a boosted voltage having the same value as the second DC voltage. The boosted voltage is output to charger 251 .

When charging current control unit 240 detects that second DC power supply 102 is on based on the voltage/current information output from voltage/current detecting unit 212, charging current control unit 240 operates charger 252 to supply the second charging current. It is supplied to the secondary battery 104 . Charging current control unit 240 stops the operation of charger 252 when it detects that second DC power supply 102 is off based on the voltage/current information output from voltage/current detection unit 212 .

Charging current control section 240 calculates the power used by first DC load 105 based on the voltage/current information output from voltage/current detecting section 211 . Charging current control unit 240 calculates residual power (RP1 in FIG. 4) by subtracting the power used by first DC load 105 from the allowable maximum power of first DC power supply 101 . Then, the charging current control unit 240 outputs a charging control signal to the charger 251 to cause the charger 251 to output a charging current corresponding to the remaining power so as not to exceed the allowable maximum power of the first DC power supply 101. . Since the first DC power supply 101 always generates the first DC voltage, the charging current control unit 240 always controls the charger 251 .

Similarly, charging current control unit 240 calculates the power used by second DC load 106 based on the voltage/current information output from voltage/current detection unit 212 . Charging current control unit 240 calculates residual power (RP2 in FIG. 4) by subtracting the power used by second DC load 106 from the allowable maximum power of second DC power supply 102 . Then, charging current control unit 240 outputs to charger 252 a charging control signal for causing charger 252 to output a charging current corresponding to the remaining power so as not to exceed the allowable maximum power of second DC power supply 102. .

The charging current control unit 240 controls charging of the secondary battery 104 using only the charger 251 during the sleep mode in which the first DC power supply 101 is kept on and the second DC power supply 102 is turned off. . In addition, charging current control unit 240 charges secondary battery 104 using both chargers 251 and 252 during copy mode and standby mode in which both first DC power supply 101 and second DC power supply 102 are turned on. Control charging. Sleep mode, copy mode, and standby mode will be described with reference to FIG.

Note that when charging current control unit 240 receives notification of a fully charged state from charge capacity detection unit 270, charging current control unit 240 charges chargers 251 and 252 regardless of the voltage/current information output from voltage/current detection units 211 and 212. to stop the operation of This prevents overcharging of the secondary battery 104 .

Charger 251 generates charging current using the boosted voltage based on the charging control signal from charging current control section 240 and supplies the generated charging current to secondary battery 104 via diode 261 . Charger 252 generates a charging current using the second power supply voltage based on a charging control signal from charging current control section 240 and supplies the generated charging current to secondary battery 104 via diode 262 . do.

The anode of the diode 261 is connected to the output of the charger 251 and the cathode of the diode 261 is connected to the common power line connected to the terminal of the secondary battery 104 . The anode of diode 262 is connected to the output of charger 252 and the cathode of diode 262 is connected to the common power line connected to the terminal of secondary battery 104 .

This can prevent the charging current from flowing from one of the chargers 251 and 252 to the other, and can prevent the charging current from being consumed for purposes other than charging the secondary battery 104 . For example, even when the second DC power supply 102 is turned off and the charger 252 stops operating, it is possible to prevent the charging current output from the charger 251 from leaking to the charger 252 . As a result, it is possible to prevent the charging efficiency of the secondary battery 104 from decreasing.

In addition, since the charger 251 generates the charging current using the boosted voltage of the same value as the second DC voltage, when both the chargers 251 and 252 are used simultaneously to charge the secondary battery 104, A charging current from the charger 251 can be supplied to the secondary battery 104 . On the other hand, when the charger 251 generates a charging current using the first DC voltage (5 V), the anode voltage of the diode 261 becomes lower than the cathode voltage of the diode 261, so that the secondary battery is discharged from the charger 251. 104 cannot be supplied with charging current. In other words, the charger 251 generates the charging current using the boosted voltage of the same value as the second DC voltage, so that the charging current can be simultaneously supplied to the secondary battery 104 from the chargers 251 and 252. .

Based on the signal indicating the charge capacity from the secondary battery 104, the charge capacity detection unit 270 determines whether or not the charge capacity is in the fully charged state. Notify status. It should be noted that the charge capacity detection unit 270 may have a function of determining whether or not the battery is in an empty state with almost no charge capacity. The power line connecting the secondary battery 104 and the first DC load 105 is connected to the secondary battery 104 to the first DC load when the supply of the first DC voltage to the image forming apparatus 100 is stopped due to a power failure or the like. 105 schematically shows the path of the DC voltage supplied to 105. FIG.

FIG. 4 is a timing chart showing an example of charging control of the secondary battery 104 by the charging device 200 of FIG. Image forming apparatus 100 shown in FIG. 1 has sleep mode, copy mode, and standby mode as operation modes. Note that FIG. 4 shows the operation when the secondary battery 104 is not fully charged.

The sleep mode is shifted from the standby mode, for example, when a predetermined period of time elapses while the operation panel 1 is not operated in the standby mode. In sleep mode, the second DC power supply 102 is turned off, and only the first DC power supply 101 remains on.

The copy mode is a so-called operation mode, and is set when copying or printing an image or transmitting/receiving a facsimile. In the copy mode, since the second DC load 106 operates, both the first DC power supply 101 and the second DC power supply 102 are turned on.

The standby mode is set during a period before and after the operation mode in which no copy operation or print operation is performed. Since the standby mode is a state of waiting for the operation of the second DC load 106, both the first DC power supply 101 and the second DC power supply 102 are turned on.

In this embodiment, charger 251 operates in all of sleep mode, copy mode and standby mode. Then, charger 251 supplies charging current corresponding to residual power RP1, which is the difference between the maximum allowable power of first DC power supply 101 and the power used by first DC load 105, to secondary battery 104. do. Charger 252 operates in the copy mode and the standby mode, and charges current corresponding to residual power RP2, which is the difference between the maximum allowable power of second DC power supply 102 and the power used by second DC load 106. is supplied to the secondary battery 104 .

Thus, in the copy mode and the standby mode, both the charging current from the first DC power supply 101 and the charging current from the second DC power supply 102 can be used to charge the secondary battery 104 . Therefore, compared with the case where the secondary battery 104 is charged using only the charging current from the first DC power supply 101, the charging amount of the secondary battery 104 per hour can be increased. That is, the charging efficiency of the secondary battery 104 can be improved, and the charging time can be shortened.

In order to improve energy-saving efficiency, the voltage of the first DC power supply 101 is set to 5.1 V during copy mode and standby mode, and is set to 5 V during sleep mode, for example. Therefore, the allowable maximum power of first DC power supply 101 during copy mode and standby mode is set to be greater than the allowable maximum power of first DC power supply 101 during sleep mode.

Further, although not shown in FIGS. 1 and 2, image forming apparatus 100 has a fan for adjusting the temperature inside image forming apparatus 100 . The reading section 4, the printer unit 6, the transport unit 8, etc. (a part of the second DC load) shown in FIG. 2 operate by receiving the second DC power supply 102 during the copy mode. During the copy mode, the fan operates (rotates) to discharge heat generated within the image forming apparatus 100 to the outside. On the other hand, since the reading section 4, the printer unit 6, the transport unit 8, and the like stop operating during the standby mode, the amount of heat generated in the image forming apparatus 100 is small, and the fan stops operating.

Therefore, the allowable maximum power of the second DC power supply 102 during the copy mode in which heat can be discharged to the outside by operating the fan is the allowable maximum power of the second DC power supply 102 in the standby mode in which heat cannot be discharged to the outside by stopping the fan. It is set larger than the maximum power.

FIG. 5 is an explanatory diagram showing an example of a state for each operation mode of the image forming apparatus 100 of FIG. Note that FIG. 5 shows a state in which the secondary battery 104 is not fully charged. When image forming apparatus 100 is in sleep mode, first DC power supply 101 is turned on (ON), second DC power supply 102 is turned off (OFF), charger 251 operates (ON), and charger 252 operates. Stop (OFF).

When image forming apparatus 100 is in standby mode, first DC power supply 101 and second DC power supply 102 are turned on, and chargers 251 and 252 operate. When image forming apparatus 100 is in copy mode, first DC power supply 101 and second DC power supply 102 are turned on, and chargers 251 and 252 operate.

FIG. 6 is a flow diagram showing an example of the operation of charging device 200 of FIG. That is, FIG. 6 shows an example of a charging method of the secondary battery 104 by the charging device 200. As shown in FIG. The operation flow shown in FIG. 6 is performed at a predetermined cycle.

First, in step S10, the charging device 200 determines whether the charging capacity of the secondary battery 104 is fully charged by the charging capacity detection unit 270. If the charging capacity is fully charged, the process proceeds to step S60. If it is not in the charging state, step S20 is carried out. Note that the fully charged state charge capacity used for determination may be a value close to 100%, such as 98%, instead of 100%.

In step S<b>20 , the charging device 200 controls the charger 251 using the charging current control unit 240 to charge the secondary battery 104 using the charging current (boosted voltage) of the first DC power supply 101 . Next, in step S30, charging device 200 uses voltage/current detection unit 212 to determine whether or not second DC power supply 102 is in the ON state. , the process returns to step S10.

In step S<b>40 , the charging device 200 controls the charger 252 with the charging current control unit 240 to charge the secondary battery 104 using the charging current of the second DC power supply 102 . That is, charging device 200 uses both chargers 251 and 252 at the same time to charge secondary battery 104 .

Next, in step S50, the charging device 200 determines whether or not the charging capacity of the secondary battery 104 is fully charged by the charging capacity detection unit 270, and if it is fully charged, executes step S60, If the battery is not fully charged, the process returns to step S30.

In step S60, the charging device 200 causes the charging current control unit 240 to stop the operation of the operating charger (both of the chargers 51 and 52 or only the 51) and stop supplying the charging current to the secondary battery 104. Then, the operation shown in FIG. 6 ends.

As described above, in the first embodiment, in the copy mode and the standby mode in which the first DC load 105 and the second DC load 106 operate, both the charging current by the first DC power supply 101 and the charging current by the second DC power supply 102 are can be used to charge the secondary battery 104 . Therefore, compared with the case where the secondary battery 104 is charged using only the charging current from the first DC power supply 101, the charging amount of the secondary battery 104 per hour can be increased. Thereby, the charging efficiency of the secondary battery 104 can be improved, and the charging time can be shortened.

In addition, since the charger 251 generates the charging current using the boosted voltage having the same value as the second DC voltage, the charging current can be simultaneously supplied to the secondary battery 104 from the chargers 251 and 252 .

(Second embodiment)
FIG. 7 is a block diagram showing an example of a charging device according to the second embodiment of the invention. Elements similar to those in FIG. 3 are denoted by the same reference numerals, and detailed description thereof is omitted. A charging device 200A shown in FIG. 7 is mounted in the image forming apparatus 100 instead of the charging device 200 shown in FIG. The image forming apparatus 100 is the same as that in FIG. 1 except that the mounted charging device is different, so the description of the image forming apparatus 100 is omitted.

Charging device 200A has a configuration in which charging efficiency comparing section 280 and switching section 290 are added to charging device 200 shown in FIG. Charging efficiency comparison section 280 is an example of a switching control section that controls switching of switching section 290 . In addition, the charging device 200A has a path (5V path) for directly supplying the first charging current from the voltage/current detection unit 211 to the charger 251 and a path (24V path) for supplying the first charging current via the voltage adjusting/boosting circuit 230. and

Charging efficiency comparison section 280 charges the output of voltage/current detection section 211 when it detects the OFF state of second DC power supply 102 (sleep mode) based on the voltage/current information from voltage/current detection section 211. A switching signal for connecting to the input of the device 251 is output to the switching section 290 .

In addition, when the charging efficiency comparison unit 280 detects that the second DC power supply 102 is turned on (copy mode or standby mode), the charging efficiency comparison unit 280 operates both the chargers 251 and 252 and operates only the charger 251. The charging efficiency of the secondary battery 104 is compared with time.

When charging efficiency comparing section 280 determines that the charging efficiency is high when both chargers 251 and 252 are operated, charging efficiency comparing section 280 connects the output of voltage/current detecting section 211 to the input of voltage adjusting/boosting circuit 230. A switching signal is output to the switching unit 290 (simultaneous charging mode). Further, charging efficiency comparing section 280 outputs an instruction to operate charger 252 to charging current control section 240 .

On the other hand, when charging efficiency comparison section 280 determines that the charging efficiency is high when charger 251 is operated alone, it switches the switching signal that connects the output of voltage/current detection section 211 to the input of charger 251 . output to unit 290 (single charge mode). Further, charging efficiency comparing section 280 outputs to charging current control section 240 an instruction to stop the operation of charger 252 and to operate only charger 251 .

For example, charging efficiency comparing section 280 uses equation (1) based on remaining power RP1 of first DC power supply 101 and remaining power RP2 of second DC power supply 102 shown in FIG. It is determined which of the charging mode and the charging mode has higher charging efficiency.

The left side of equation (1) represents the power that can be charged to the secondary battery 104 in the single charge mode, and the right side of the equation (1) represents the power that can be charged to the secondary battery 104 in the simultaneous charge mode. A larger value indicates higher charging efficiency. Charging efficiency comparison unit 280 determines that the charging efficiency in the single charging mode is high when formula (1) is satisfied. Charging efficiency comparing section 280 determines that the charging efficiency in the simultaneous charging mode is high when formula (1) is not satisfied.

Residual power RP1>Residual power RP1×Conversion efficiency+Residual power RP2 (1)
In equation (1), the conversion efficiency is the efficiency when the voltage regulator/boost circuit 230 converts the first DC voltage (5 V) into the boosted voltage (24 V), and is measured or calculated in advance.

Charging efficiency comparison section 280 calculates the power consumption used by first DC load 105 based on the voltage/current information output from voltage/current detection section 211, and transmits the calculated power consumption to the first DC power supply. The remaining power RP1 is calculated by subtracting from the allowable maximum power of 101. Similarly, charging efficiency comparison section 280 calculates the power consumption used by second DC load 106 based on the voltage/current information output from voltage/current detection section 212, and sets the calculated power consumption to 2 Subtract from the allowable maximum power of DC power supply 102 to calculate residual power RP2. It should be noted that charging efficiency comparison section 280 may determine the charging efficiency using remaining power RP1 and RP2 calculated by charging current control section 240 .

For example, when the residual power RP1 is 50 W, the residual power RP2 is 14 W, and the conversion efficiency is 70%, the left side of Equation (1) is 50 W, and the right side of Equation (1) is 49 W. In this case, the charging efficiency comparison unit 280 determines that the charging efficiency in the single charging mode is high, does not operate the charger 252, operates the charger 251 without using the boosted voltage, and operates the 5 V single secondary power supply. Battery 104 is charged.

Also, for example, when the residual power RP1 is 50 W, the residual power RP2 is 40 W, and the conversion efficiency is 70%, the left side of (1) is 50 W, and the right side of Equation (1) is 75 W. In this case, the charging efficiency comparison unit 280 determines that the charging efficiency in the simultaneous charging mode is high, supplies the boosted voltage to the charger 251, operates the chargers 251 and 252 simultaneously, and charges the secondary battery 104 at 24V. do.

In this manner, the charging efficiency of the secondary battery 104 is further improved by charging the secondary battery 104 in either the single charging mode or the simultaneous charging mode based on the charging efficiency determination result by the charging efficiency comparison unit 280. can be used, and the charging time can be further shortened.

In addition to the function described with reference to FIG. 3 , charging current control section 240 has a function of stopping the operation of charger 252 when receiving an instruction to stop the operation of charger 252 from charging efficiency comparing section 280 . Switching section 290 connects the output of voltage/current detecting section 211 to the input of charger 251 or the input of voltage adjusting/boosting circuit 230 in response to the switching signal from charging efficiency comparing section 280 .

FIG. 8 is a flow chart showing an example of states for each operation mode of charging device 200A of FIG. A detailed description of the state similar to that of FIG. 5 is omitted. FIG. 8 shows the state when the secondary battery 104 is not fully charged.

When the image forming apparatus 100 is in sleep mode, the switching unit 290 directly connects the output of the voltage/current detection unit 211 to the input of the charger 251 to supply 5V to the charger 251 . Other states in sleep mode are the same as in FIG.

When the image forming apparatus 100 is in the standby mode or the copy mode, the switching unit 290 switches the output of the voltage/current detection unit 211 to the input of the charger 251 or adjusts the voltage based on the charging efficiency determination result by the charging efficiency comparison unit 280 . / Connect to the input of the booster circuit 230 .

FIG. 9 is a flow diagram showing an example of the operation of charging device 200A of FIG. That is, FIG. 9 shows an example of a charging method of the secondary battery 104 by the charging device 200A. The same reference numerals are assigned to the same operations as in FIG. 6, and detailed description thereof will be omitted. In FIG. 9, steps S32, S36, and S40 are inserted between steps S30 and S50 instead of step S40 of FIG.

If the second DC power supply 102 is on in step S30, step S32 is performed. In step S32, the charging device 200A uses the charging efficiency comparison unit 280 to determine whether charging the secondary battery 104 in the single charging mode (5V) has higher charging efficiency than in the simultaneous charging mode. 200 A of charging devices implement step S36, when the charge efficiency of single charge mode is high, and implements step S40, when the charge efficiency of simultaneous charge mode is high.

In step S36, charging device 200A charges secondary battery 104 in the single charging mode, and the operation proceeds to step S50. In step S40, the same operation as step S40 in FIG. 6 is performed, and the operation proceeds to step S50. The operations of steps S50 and S60 are the same as steps S50 and S60 of FIG. 6, respectively.

As described above, in the second embodiment, as in the first embodiment, both the charging current by the first DC power supply 101 and the charging current by the second DC power supply 102 are used to charge the secondary battery 104. Efficiency can be improved and charging time can be shortened.

Furthermore, in the second embodiment, the secondary battery 104 can be charged in either the single charge mode or the simultaneous charge mode based on the charging efficiency comparison result by the charging efficiency comparison unit 280 . Thereby, the charging efficiency of the secondary battery 104 can be further improved, and the charging time can be further shortened.

(Third embodiment)
FIG. 10 is a block diagram showing an example of a charging device according to the third embodiment of the invention. Elements similar to those in FIGS. 3 and 7 are denoted by the same reference numerals, and detailed description thereof is omitted. A charging device 200B shown in FIG. 10 is mounted in the image forming apparatus 100 instead of the charging device 200 shown in FIG. The image forming apparatus 100 is the same as that in FIG. 1 except that the mounted charging device is different, so the description of the image forming apparatus 100 is omitted.

Charging device 200B has a configuration in which switching unit 290 is added to charging device 200 shown in FIG. The switching section 290 of this embodiment operates according to a switching signal from the charge capacity detection section 270 . As in the second embodiment, the switching unit 290 connects the output of the voltage/current detection unit 211 to the input of the charger 251 during the sleep mode regardless of the switching signal. 7, the charging device 200B supplies the first charging current from the voltage/current detection unit 211 directly to the charger 251 via a path (5V path) and the voltage adjustment/boosting circuit 230. (24V path).

In this embodiment, the charge capacity detection unit 270 determines whether the charge capacity is in a nearly fully charged state or an empty state with almost no charge capacity, based on a signal indicating the charge capacity from the secondary battery 104 . Determine if it is neither empty state. Although not particularly limited, for example, the charge capacity in the charged state is about 95% when the fully charged state is 100%, and the charge capacity in the empty state is 5% or less.

When charging capacity detection section 270 determines the charged state or the empty state, it outputs a switching signal to switching section 290 for connecting the output of voltage/current detection section 211 to the input of charger 251 (independent charging mode). In addition, charging capacity detection unit 270 outputs an instruction to stop the operation of charger 252 to charging current control unit 240 .

On the other hand, if the charge capacity detection unit 270 determines that the state is neither the charged state nor the empty state, the switching unit 290 switches the switching signal for connecting the output of the voltage/current detection unit 211 to the input of the voltage adjustment/boost circuit 230 . (simultaneous charging mode). In addition, charging capacity detection section 270 outputs an instruction to operate charger 252 to charging current control section 240 .

If a large charging current is supplied to the secondary battery 104 when the secondary battery 104 is nearly fully charged, the charging current control unit 240 may not be able to control the charging stop in time when the secondary battery 104 is fully charged. The secondary battery 104 may become overcharged. When the secondary battery 104 is in an overcharged state, an abnormal voltage may be output from the secondary battery 104, and an excessive current may flow. Moreover, depending on the type of the secondary battery 104, when the secondary battery 104 is in an overcharged state, memory effect, which is a phenomenon in which the charge capacity decreases, is likely to occur.

In the present embodiment, charging at 24V is stopped and the battery is switched to charging at 5V when the charging state is close to the fully charged state. It is possible to prevent the secondary battery 104 from being overcharged. As a result, it is possible to prevent the occurrence of abnormal voltage and current, and for example, it is possible to prevent the image forming apparatus 100 from malfunctioning due to the abnormal current flowing through the first DC load 105 . Furthermore, the occurrence of memory effects can be prevented.

In addition, when the secondary battery 104 is empty or nearly empty, if the secondary battery 104 is rapidly charged using 24 V, a large charging current flows through the secondary battery 104, and the secondary battery 104 may deteriorate. In the present embodiment, charging at 24 V is stopped and switched to charging at 5 V in the empty state, whereby the charging current can be reduced compared to charging at 24 V, and the secondary battery 104 deteriorates. can be suppressed. That is, when the secondary battery 104 is in a charged state or an empty state, the secondary battery 104 can be protected by stopping charging at 24V and switching to charging at 5V.

FIG. 11 is a flow chart showing an example of the operation of charging device 200B of FIG. That is, FIG. 11 shows an example of a charging method of the secondary battery 104 by the charging device 200B. The same reference numerals are assigned to the same operations as in FIGS. 6 and 9, and detailed descriptions thereof are omitted. In FIG. 11, step S34 is performed instead of step S32 of FIG.

In step S34, the charging device 200B uses the charging capacity detection unit 270 to determine whether the charging capacity of the secondary battery 104 is in a charged state, an empty state, or neither a charged state nor an empty state. In the charged state or the empty state, the charge capacity detection unit 270 charges the secondary battery 104 in the single charge mode in step S36. If the charging capacity detection unit 270 is neither in the charged state nor in the empty state, in step S40, the secondary battery 104 is charged in the simultaneous charging mode.

As described above, in the third embodiment, as in the first embodiment, both the charging current by the first DC power supply 101 and the charging current by the second DC power supply 102 are used to charge the secondary battery 104. Efficiency can be improved and charging time can be shortened.

Furthermore, in the third embodiment, charging at 24 V is stopped when the charging state is close to the fully charged state, and the charging is switched to charging at 5 V, so that charging stop control by the charging current control unit 240 is performed normally. It is possible to prevent the secondary battery 104 from being overcharged. As a result, it is possible to prevent the occurrence of abnormal voltage and current, and for example, it is possible to prevent the image forming apparatus 100 from malfunctioning due to the abnormal current flowing through the first DC load 105 . Furthermore, the occurrence of memory effects can be prevented.

Further, by stopping charging at 24 V and switching to charging at 5 V in an empty state, deterioration of the secondary battery 104 can be suppressed as compared with charging at 24 V. can be protected.

(Fourth embodiment)
FIG. 12 is a block diagram showing an example of a charging device according to the fourth embodiment of the invention. Elements similar to those in FIGS. 3, 7 and 10 are denoted by the same reference numerals, and detailed description thereof is omitted. A charging device 200C shown in FIG. 12 is mounted in the image forming apparatus 100 instead of the charging device 200 shown in FIG. The image forming apparatus 100 is the same as that in FIG. 1 except that the mounted charging device is different, so the description of the image forming apparatus 100 is omitted.

The charging device 200C has a switching unit 292 instead of the switching unit 290 of the charging device 200A shown in FIG. Switching unit 292 operates under the control of charging capacity detecting unit 270 and charging efficiency comparing unit 280 .

In the standby mode or the copy mode, similarly to FIG. 10, when the charge capacity detection unit 270 determines the charged state or the empty state, a switching signal for connecting the output of the voltage/current detection unit 211 to the input of the charger 251 is generated. to the switching unit 292 (single charge mode). In addition, charging capacity detection unit 270 outputs an instruction to stop the operation of charger 252 to charging current control unit 240 .

In addition, when charging capacity detection section 270 determines that it is neither the charged state nor the empty state during the standby mode or copy mode, the output of voltage/current detection section 211 is applied to the input of voltage adjustment/boost circuit 230 . A switching signal for connection is output to the switching unit 292 (simultaneous charging mode). In addition, charging capacity detection section 270 outputs an instruction to operate charger 252 to charging current control section 240 .

Similarly to FIG. 7, charging efficiency comparing section 280 outputs a switching signal to switching section 292 for connecting the output of voltage/current detecting section 211 to the input of charger 251 during the sleep mode (single charging mode). Also, the charging efficiency comparison unit 280 compares the charging efficiency between the simultaneous charging mode and the single charging mode during the standby mode or the copy mode.

When charging efficiency comparison section 280 determines that the charging efficiency in the simultaneous charging mode is high, charging efficiency comparison section 280 outputs to switching section 292 a switching signal for connecting the output of voltage/current detection section 211 to the input of voltage adjustment/boosting circuit 230 . and charge the secondary battery 104 in the simultaneous charge mode. When charging efficiency comparing section 280 determines that the charging efficiency in the single charging mode is high, charging efficiency comparing section 280 outputs a switching signal for connecting the output of voltage/current detecting section 211 to the input of charger 251 to switching section 292 to switch to the single charging mode. to charge the secondary battery 104 .

The second point is that the charging current control unit 240 operates both the chargers 251 and 252 in the simultaneous charging mode, and stops the operation of the charger 252 and operates only the charger 251 in the single charging mode. is similar to the embodiment of

Based on the switching signal from the charging capacity detecting section 270 and the switching signal from the charging efficiency comparing section 280, the switching section 292 switches the output of the voltage/current detecting section 211 to the input of the voltage adjusting/boosting circuit 230 or the charger 251. input to one of the When switching unit 292 receives a switching signal instructing reverse connection from charging capacity detecting unit 270 and charging efficiency comparing unit 280, switching unit 292 connects the output of voltage/current detecting unit 211 to the input of charger 251. do. That is, the single charge mode has priority over the simultaneous charge mode. This prevents the simultaneous charging mode from being performed when the secondary battery 104 is in a charged state or an empty state, and the secondary battery 104 can be reliably protected.

FIG. 13 is a flow diagram showing an example of the operation of charging device 200C of FIG. That is, FIG. 13 shows an example of a charging method of the secondary battery 104 by the charging device 200C. The same reference numerals are assigned to the same operations as those in FIGS. 6, 9 and 11, and detailed description thereof will be omitted. In FIG. 13, the operation of step S34 of FIG. 11 is inserted between steps S32 and S40 of FIG. That is, when charging device 200C determines in step S32 that the charging efficiency in the simultaneous charging mode is higher than the charging efficiency in the single charging mode, step S34 is performed.

In step S34, the charging device 200C performs step S36 if the charging capacity of the secondary battery 104 is in a charged state or an empty state, and if the charging capacity of the secondary battery 104 is neither in a charged state nor in an empty state, step S40 is implemented.

As described above, even in the fourth embodiment, the same effects as in the first to third embodiments can be obtained. In addition, when either the single charging mode or the simultaneous charging mode is performed according to the charging efficiency and the charging capacity of the secondary battery 104, the simultaneous charging mode is selected when the secondary battery 104 is in a charged state or in an empty state. can be prevented from being carried out. As a result, the secondary battery 104 can be reliably protected.

In the above-described first to fourth embodiments, examples of the charging devices 200, 200A, 200B, and 200C that charge the secondary battery 104 using the first DC power supply 101 and the second DC power supply 102 are described. However, secondary battery 104 may be charged using three or more DC power supplies.

In this case, the charging device has a plurality of boost circuits for boosting the DC voltages generated by the DC power sources other than the DC power source generating the maximum DC voltage to the maximum DC voltage. In addition, the charging device includes a charger that supplies charging current to the secondary battery 104 using the maximum DC voltage, and a charging current to the secondary battery 104 using boosted voltages generated by a plurality of boosting circuits. Having multiple chargers to supply. Thereby, for example, the charging time of the secondary battery 104 can be shortened regardless of the number of DC power sources that the image forming apparatus 100 has.

Although the present invention has been described above based on each embodiment, the present invention is not limited to the requirements shown in the above embodiments. These points can be changed without impairing the gist of the present invention, and can be determined appropriately according to the application form.

1 Operation panel 2 Start switch 3 Controller 4 Reading unit 5 Engine control unit 6 Printer units 7A, 7B Paper feed cassette 8 Conveyance unit 9 AC control unit 10 DC power supply unit 100 Image forming apparatus 101 First DC power supply 102 Second DC power supply 200 , 200A, 200B, 200C charging devices 211, 212 voltage/current detection unit 220 output voltage control unit 230 voltage adjustment/booster circuit 240 charging current control units 251, 252 chargers 261, 262 diode 270 charging capacity detection unit 280 charging efficiency comparison Sections 290 and 292 Switching section

Japanese Patent No. 4126329

Claims (8)

a booster circuit that boosts the first DC voltage generated by the first DC power supply to generate a boosted voltage;
a first charging unit that supplies a secondary battery with a first charging current corresponding to the boosted voltage;
a second charging unit that supplies the secondary battery with a second charging current input from a second DC power supply that generates a second DC voltage higher than the first DC voltage ;
a switching unit that connects the output of the first DC power supply or the output of the booster circuit to the input of the first charging unit;
When the charging efficiency of the secondary battery with the first charging current and the second charging current is lower than the charging efficiency of the secondary battery with only the first DC current of the first DC power supply, the switching unit is controlled. a switching control unit that connects the output of the first DC power supply to the input of the first charging unit and stops charging of the secondary battery by the second charging unit;
The charging device, wherein the boosted voltage generated by the booster circuit is equal to the second DC voltage. a booster circuit that boosts the first DC voltage generated by the first DC power supply to generate a boosted voltage;
a first charging unit that supplies a secondary battery with a first charging current corresponding to the boosted voltage;
a second charging unit that supplies the secondary battery with a second charging current input from a second DC power supply that generates a second DC voltage higher than the first DC voltage ;
a switching unit that connects the output of the first DC power supply or the output of the booster circuit to the input of the first charging unit;
a charge capacity detection unit that detects the charge capacity of the secondary battery;
When the charging capacity detection unit detects that the charging capacity is in a state of charge close to a fully charged state, the switching unit is controlled to connect the output of the first DC power supply to the input of the first charging unit. and a switching control unit that stops charging of the secondary battery by the second charging unit ,
The charging device, wherein the boosted voltage generated by the booster circuit is equal to the second DC voltage. a booster circuit that boosts the first DC voltage generated by the first DC power supply to generate a boosted voltage;
a first charging unit that supplies a secondary battery with a first charging current corresponding to the boosted voltage;
a second charging unit that supplies the secondary battery with a second charging current input from a second DC power supply that generates a second DC voltage higher than the first DC voltage ;
a switching unit that connects the output of the first DC power supply or the output of the booster circuit to the input of the first charging unit;
and a charge capacity detection unit that detects the charge capacity of the secondary battery,
when the charge capacity detection unit detects that the charge capacity is empty or nearly empty, controlling the switching unit to connect the output of the first DC power supply to the input of the first charging unit; a switching control unit that stops charging of the secondary battery by the second charging unit ;
The charging device, wherein the boosted voltage generated by the booster circuit is equal to the second DC voltage. a power detection unit that detects a first power consumption of a first DC load connected to the first DC power supply and a second power consumption of a second DC load connected to the second DC power supply;
a charging current control unit that controls the first charging current and the second charging current supplied to the secondary battery so that each of the first power consumption and the second power consumption is equal to or less than the allowable power; The charging device according to any one of claims 1 to 3, comprising: a plurality of booster circuits each generating a plurality of boosted voltages by boosting a plurality of first DC voltages having different voltage values respectively generated by the plurality of first DC power supplies;
a plurality of the first charging units that supply the first charging current corresponding to each of the boosted voltages to terminals of the secondary battery;
The charging device according to any one of claims 1 to 3 , wherein the plurality of booster circuits each generate the boosted voltage equal to the second DC voltage. A secondary battery charging method using a charging device connected to a first DC power supply that generates a first DC voltage and a second DC power supply that generates a second DC voltage higher than the first DC voltage,
stepping up the first DC voltage to generate a stepped-up voltage equal to the second DC voltage;
supplying a charging current corresponding to the first DC voltage or a first charging current corresponding to the boosted voltage to the secondary battery;
supplying a second charging current input from the second DC power supply to the secondary battery;
When the charging efficiency of the secondary battery with the first charging current and the second charging current is lower than the charging efficiency of the secondary battery with only the charging current corresponding to the first DC voltage, the first DC voltage charging the secondary battery with the corresponding charging current, and stopping the charging of the secondary battery with the second charging current. A secondary battery charging method using a charging device connected to a first DC power supply that generates a first DC voltage and a second DC power supply that generates a second DC voltage higher than the first DC voltage,
stepping up the first DC voltage to generate a stepped-up voltage equal to the second DC voltage;
supplying a charging current corresponding to the first DC voltage or a first charging current corresponding to the boosted voltage to the secondary battery;
supplying a second charging current input from the second DC power supply to the secondary battery;
detecting the charge capacity of the secondary battery;
When it is detected that the charge capacity is in a state of charge close to a fully charged state, the secondary battery is charged with a charging current corresponding to the first DC voltage, and the secondary battery is charged with the second charging current. How to stop the charging. A secondary battery charging method using a charging device connected to a first DC power supply that generates a first DC voltage and a second DC power supply that generates a second DC voltage higher than the first DC voltage,
stepping up the first DC voltage to generate a stepped-up voltage equal to the second DC voltage;
supplying a charging current corresponding to the first DC voltage or a first charging current corresponding to the boosted voltage to the secondary battery;
supplying a second charging current input from the second DC power supply to the secondary battery;
detecting the charge capacity of the secondary battery;
When it is detected that the charge capacity is empty or nearly empty, the secondary battery is charged with a charging current corresponding to the first DC voltage, and charging of the secondary battery with the second charging current is stopped. Yes, how to charge.

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