The embodiments relate to the field of charging technologies, a charging circuit, a terminal device, an adapter, and a charging system and method.
An adapter is a common accessory of a terminal device that can store energy. For example, a terminal device such as a smartphone, a tablet computer, and a notebook computer is equipped with an adapter. The adapter may receive an industrial frequency alternating current, convert the industrial frequency alternating current into a direct current, and provide the direct current to the terminal device. Further, the terminal device may charge a terminal battery in the terminal device by using the direct current.
An electrolytic capacitor may need to be disposed in the terminal adapter to stabilize an output voltage of the adapter. However, due to a limitation of a process structure of the electrolytic capacitor, most electrolytic capacitors have a large volume, which is not conducive to achieving miniaturization of the adapter. After the electrolytic capacitor is removed, the output voltage of the adapter may fluctuate. That is, the adapter can output only a pulsating direct current.
Although in some current solutions, the adapter may directly charge the terminal battery, and clamp the output voltage of the adapter by using a battery voltage of the terminal battery, so that the output voltage of the adapter is stable near the battery voltage. However, in this solution, the output voltage of the adapter is limited by the battery voltage, and the adapter cannot flexibly adjust the output voltage based on a status of the terminal battery.
Therefore, currently a charging architecture between an adapter having no electrolytic capacitor and a terminal device needs to be further researched.
In view of this, the embodiments may provide a charging circuit, a terminal device, an adapter, a charging system and method. When the charging circuit provided in the embodiments is integrated into the terminal device, an electrolytic capacitor may be omitted from an adapter that charges the terminal device, which is conducive to achieving miniaturization of the adapter.
According to a first aspect, an embodiment may provide a charging circuit. The charging circuit may include a conversion circuit and a controller. A first transmission end of the conversion circuit is configured to connect to a charging interface of a terminal device, the charging interface is configured to receive a first direct current output by an adapter, and a second transmission end of the conversion circuit is configured to connect to a terminal battery. In this embodiment, when a voltage of the charging interface is greater than or equal to a threshold voltage, the conversion circuit may transmit the first direct current to the terminal battery from the charging interface, and the controller may modulate a voltage of the first direct current to a charging voltage to charge the terminal battery; or when a voltage of the charging interface is less than a threshold voltage, the conversion circuit may transmit a second direct current from the terminal battery to the charging interface, and the controller may control the conversion circuit to modulate a voltage of the second direct current to a first voltage, where the first voltage is greater than or equal to a lowest operating voltage of the adapter.
In this embodiment, the adapter may be an adapter having an electrolytic capacitor, or may be an adapter having no electrolytic capacitor. When the adapter is the adapter having no electrolytic capacitor, the first direct current output by the adapter is a pulsating direct current, that is, the voltage of the first direct current fluctuates periodically. The lowest operating voltage of the adapter may be understood as a minimum value of an output voltage of the adapter when the adapter can continuously charge the terminal device. In other words, when the output voltage of the adapter (that is, the voltage of the first direct current output by the adapter) is lower than the lowest operating voltage, the adapter stops charging the terminal device.
Because the first direct current is the pulsating direct current, an instantaneous voltage of the first direct current at some time points may be low, and a protection mechanism in the adapter is triggered, so that the adapter stops charging the terminal device. In this embodiment, when the voltage of the charging interface is less than the threshold voltage, it indicates that the voltage of the first direct current is low. The charging circuit may be discharged by using the terminal battery, and apply the first voltage to the charging interface, to stabilize the voltage of the charging interface at the first voltage, where the first voltage is greater than or equal to the lowest operating voltage of the adapter.
In addition, because when the adapter charges the terminal device, a voltage of an output interface of the adapter is equivalent to the voltage of the charging interface of the terminal device, and because the charging circuit may maintain the voltage of the charging interface above the lowest operating voltage of the adapter, the voltage of the output interface of the adapter may be clamped at a high voltage. In this way, the protection mechanism in the adapter is prevented from being triggered, so that the adapter can continuously charge the terminal device. For example, the threshold voltage in this embodiment may be greater than the first voltage, to ensure that the adapter can continuously charge the terminal device.
For example, the conversion circuit in this embodiment may include one or more direct current-direct current conversion circuits. For example, the conversion circuit includes at least one of the following circuits: a linear voltage regulator power supply circuit, a buck buck conversion circuit, a boost boost conversion circuit, a buck-boost buck-boost conversion circuit, a three-level buck buck conversion circuit, a switched-capacitor conversion circuit, an inductor-inductor-capacitor (LLC) resonant conversion circuit, a dual active full-bridge direct current-direct current (DAB) conversion circuit, a forward conversion circuit, a flyback conversion circuit, a half-bridge push-pull circuit, a full-bridge push-pull circuit, and a full-bridge phase-shift conversion circuit.
It should be noted that, in this embodiment, the controller may control a direct current transmission direction of the conversion circuit in an opened-loop manner, or may control a direct current transmission direction of the conversion circuit in a closed-loop manner. Details are as follows.
1. Open-Loop Control
The open-loop control may be applied to some direct current-direct current conversion circuits, such as a switched-capacitor conversion circuit. When the voltage of the charging interface is less than the threshold voltage, the conversion circuit may switch the direct current transmission direction to a direction from the terminal battery to the charging interface. When the voltage of the charging interface is greater than the threshold voltage, the conversion circuit may switch the direct current transmission direction to a direction from the charging interface to the terminal battery.
For the open-loop control mode, the controller does not need to control the direct current transmission direction of the conversion circuit, so that control logic of the controller for the conversion circuit is simpler.
2. Closed-Loop Control
In closed-loop control, the charging circuit needs to detect the voltage of the charging interface, to determine a time at which the direct current transmission direction of the conversion circuit is switched. To enable the charging circuit to detect the voltage of the charging interface, the charging circuit in this embodiment may further include a detection circuit. One end of the detection circuit is configured to connect to the charging interface, and the other end of the detection circuit is connected to the controller. The detection circuit may detect the voltage of the charging interface. When the voltage of the charging interface increases from being less than the threshold voltage to being greater than or equal to the threshold voltage, the detection circuit may send a first indication signal to the controller; or when the voltage of the charging interface decreases from being greater than or equal to the threshold voltage to being less than the threshold voltage, the detection circuit may send a second indication signal to the controller. In this case, after receiving the first indication signal, the controller may control the conversion circuit to modulate the voltage of the first direct current to the charging voltage to charge the terminal battery; or after receiving the second indication signal, the controller may further control the conversion circuit to modulate the voltage of the second direct current to the first voltage.
It may be understood that, because the voltage of the first direct current output by the adapter may be a periodic pulsating voltage, the voltage of the charging interface may also change periodically. Therefore, the controller may also periodically control, based on a voltage change period of the charging interface, the conversion circuit to switch the direct current transmission direction. In this implementation, the detection circuit can be omitted, and a structure of the charging circuit is simplified.
According to a second aspect, an embodiment may further provide a charging circuit. The charging circuit may include a conversion circuit and a controller. A first transmission end of the conversion circuit is configured to connect to a charging interface of a terminal device, the charging interface is configured to receive a first direct current output by an adapter, and a second transmission end of the conversion circuit is configured to connect to a terminal battery. The conversion circuit may transmit the first direct current to the terminal battery from the charging interface. The controller may control the conversion circuit to modulate a voltage of the first direct current to a charging voltage to charge the terminal battery, and when a voltage of the charging interface decreases from being greater than or equal to a threshold voltage to being less than the threshold voltage, control the conversion circuit to decrease a charging current provided to the terminal battery, to maintain the voltage of the charging interface to be greater than or equal to a lowest operating voltage of the adapter.
In a case in which an output current of the adapter remains unchanged, when a power of the first direct current output by the adapter decreases, an output voltage of the adapter also decreases, so that the voltage of the charging interface decreases accordingly. In this embodiment, when the voltage of the charging interface is less than the threshold voltage, the controller controls the conversion circuit to decrease the charging current provided to the terminal battery, that is, an output current of the conversion circuit. As a result, the output current of the adapter is decreased. In addition, because of a conversion relationship between a voltage, a current, and a power, that is, a product of the voltage and the current is equal to the power, the output current of the adapter is decreased, so that when an output power of the adapter is decreased, the output voltage of the adapter can be maintained to be not excessively decreased, thereby avoiding triggering a protection mechanism in the adapter, and enabling the adapter to continuously charge the terminal device.
In this embodiment, the threshold voltage may be greater than the lowest operating voltage of the adapter, to avoid that the adapter stops charging the terminal device because the output voltage of the adapter is excessively low.
For example, the charging circuit may further include a detection circuit. One end of the detection circuit is connected to the first transmission end, and the other end of the detection circuit is connected to the controller. The detection circuit may detect the voltage of the charging interface. When the voltage of the charging interface decreases from being greater than or equal to the threshold voltage to being less than the threshold voltage, the detection circuit may send a third indication signal to the controller. After receiving the third indication signal, the controller may further control the conversion circuit to decrease the charging current provided to the terminal battery.
In a possible implementation, the charging circuit may further increase the charging current provided to the terminal battery after the voltage of the charging interface increases from being less than the threshold voltage to being greater than or equal to the threshold voltage. For example, when the voltage of the charging interface increases from being less than the threshold voltage to being greater than or equal to the threshold voltage, the detection circuit may further send a fourth indication signal to the controller. After receiving the fourth indication signal, the controller may further control the conversion circuit to increase the charging current provided to the terminal battery.
After the voltage of the charging interface increases from being less than the threshold voltage to being greater than or equal to the threshold voltage, the power of the first direct current may be large. In this case, the charging current provided to the terminal battery may be increased, and a voltage value of the first direct current may be appropriately decreased, to improve conversion efficiency of the conversion circuit.
In this embodiment, the conversion circuit may include one or more direct current-direct current conversion circuits. For example, the converter circuit may include one or more of the following circuits: a linear voltage regulator power supply circuit, a buck conversion circuit, a boost conversion circuit, a buck-boost conversion circuit, a three-level buck conversion circuit, a switched-capacitor conversion circuit, an LLC resonant conversion circuit, a DAB conversion circuit, a forward conversion circuit, a flyback conversion circuit, a half-bridge push-pull circuit, a full-bridge push-pull circuit, a full-bridge phase-shift conversion circuit, and the like. Details are not listed in this embodiment.
According to a third aspect, an embodiment may provide a terminal device. The terminal device may include a charging interface, a charging circuit, and a terminal battery, the charging circuit is separately connected to the charging interface and the terminal battery, and the charging circuit may be the charging circuit provided in any one of the first aspect. For an effect of a corresponding solution in the third aspect, refer to an effect that can be obtained in the corresponding solution in the first aspect. Repeated parts are not described in detail.
For example, in the terminal device provided in this embodiment, the charging interface may receive a first direct current output by the adapter. When a voltage of the charging interface is greater than or equal to a threshold voltage, the charging circuit may transmit the first direct current to the terminal battery from the charging interface, and modulate a voltage of the first direct current to a charging voltage to charge the terminal battery; or when a voltage of the charging interface is less than a threshold voltage, the charging circuit may transmit a second direct current from the terminal battery to the charging interface, and modulate a voltage of the second direct current to a first voltage, where the first voltage is greater than or equal to a lowest operating voltage of the adapter. In this embodiment, the threshold voltage may be greater than the first voltage, to ensure that the adapter can continuously work.
For example, the charging circuit may include a conversion circuit and a controller, a first transmission end of the conversion circuit is configured to connect to the charging interface of the terminal device, and a second transmission end of the conversion circuit is configured to connect to the terminal battery. When the voltage of the charging interface is greater than or equal to the threshold voltage, the conversion circuit may transmit the first direct current to the terminal battery from the charging interface, and the controller may control the conversion circuit to modulate the voltage of the first direct current to the charging voltage; or when the voltage of the charging interface is less than the threshold voltage, the conversion circuit may transmit the second direct current from the terminal battery to the charging interface, and the controller may control the conversion circuit to modulate the voltage of the second direct current to the first voltage.
To enable the charging circuit to detect the voltage of the charging interface, in a possible implementation, the charging circuit may further include a detection circuit. One end of the detection circuit is configured to connect to the charging interface, and the other end of the detection circuit is connected to the controller. The detection circuit may detect the voltage of the charging interface. When the voltage of the charging interface increases from being less than the threshold voltage to being greater than or equal to the threshold voltage, the detection circuit may send a first indication signal to the controller; or when the voltage of the charging interface decreases from being greater than or equal to the threshold voltage to being less than the threshold voltage, the detection circuit may send a second indication signal to the controller. In this case, after receiving the first indication signal, the controller may control the conversion circuit to modulate the voltage of the first direct current to the charging voltage; or after receiving the second indication signal, the controller may control the conversion circuit to modulate the voltage of the second direct current to the first voltage.
In this embodiment, the conversion circuit is a direct current-direct current conversion circuit. For example, the conversion circuit may include at least one of the following circuits: a linear voltage regulator power supply circuit, a buck buck conversion circuit, a boost boost conversion circuit, a buck-boost buck-boost conversion circuit, a three-level buck buck conversion circuit, a switched-capacitor conversion circuit, an inductor-inductor-capacitor (LLC) resonant conversion circuit, a dual active full-bridge direct current-direct current (DAB) conversion circuit, a forward conversion circuit, a flyback conversion circuit, a half-bridge push-pull circuit, a full-bridge push-pull circuit, and a full-bridge phase-shift conversion circuit.
According to a fourth aspect, an embodiment may provide a terminal device. The terminal device may include a charging interface, a charging circuit, and a terminal battery. The charging circuit is separately connected to the charging interface and the terminal battery. The charging interface may be the charging circuit provided in any one of the second aspect. For an effect of a corresponding solution in the fourth aspect, refer to an effect that can be obtained in the corresponding solution in the second aspect. Repeated parts are not described in detail.
For example, the charging interface may receive a first direct current output by an adapter. The charging circuit may transmit the first direct current to the terminal battery from the charging interface and modulate a voltage of the first direct current to a charging voltage to charge the terminal battery. When a voltage of the charging interface decreases from being greater than or equal to a threshold voltage to being less than the threshold voltage, the charging circuit may decrease a charging current provided to the terminal battery, to maintain the voltage of the charging interface to be greater than or equal to a lowest operating voltage of the adapter. The threshold voltage may be greater than the lowest operating voltage of the adapter.
For example, the charging circuit may include a conversion circuit and a controller, a first transmission end of the conversion circuit is configured to connect to the charging interface of the terminal device, and a second transmission end of the conversion circuit is configured to connect to the terminal battery. The conversion circuit may transmit the first direct current to the terminal battery from the charging interface. The controller may control the conversion circuit to modulate the voltage of the first direct current to the charging voltage, and when the voltage of the charging interface is less than the threshold voltage, control the conversion circuit to decrease the charging circuit.
To enable the charging circuit to detect the voltage of the charging interface, in a possible implementation, the charging circuit may further include a detection circuit. One end of the detection circuit is configured to connect to the first transmission end, and the other end of the detection circuit is connected to the controller. The detection circuit may detect the voltage of the charging interface. When the voltage of the charging interface decreases from being greater than or equal to the threshold voltage to being less than the threshold voltage, the detection circuit may send a third indication signal to the controller. After receiving the third indication signal, the controller may further control the conversion circuit to decrease the charging current.
In a possible implementation, when the voltage of the charging interface increases from being less than the threshold voltage to being greater than or equal to the threshold voltage, the detection circuit may further send a fourth indication signal to the controller. After receiving the fourth indication signal, the controller may further control the conversion circuit to increase the charging current provided to the terminal battery.
In this embodiment, the conversion circuit is a direct current-direct current conversion circuit. For example, the conversion circuit may include at least one of the following circuits: a linear voltage regulator power supply circuit, a buck buck conversion circuit, a boost boost conversion circuit, a buck-boost buck-boost conversion circuit, a three-level buck buck conversion circuit, a switched-capacitor conversion circuit, an inductor-inductor-capacitor (LLC) resonant conversion circuit, a dual active full-bridge direct current-direct current (DAB) conversion circuit, a forward conversion circuit, a flyback conversion circuit, a half-bridge push-pull circuit, a full-bridge push-pull circuit, and a full-bridge phase-shift conversion circuit.
According to a fifth aspect, an embodiment may further provide an adapter. The adapter is adapted to the terminal device provided in any one of the third aspect or the fourth aspect. The adapter may include an alternating current interface, a first rectifier circuit, a direct current-direct current converter, and an output interface. An input end of the first rectifier circuit is connected to the alternating current interface, an output end of the first rectifier circuit is connected to an input end of the direct current-direct current converter, and an output end of the direct current-direct current converter is connected to the output interface. In the adapter, the alternating current interface may receive an alternating current. The first rectifier circuit may convert the alternating current into a first direct current, and then output the first direct current to the direct current-direct current converter. The direct current-direct current converter may modulate a voltage of the first direct current, and then output the first direct current through the output interface.
The first rectifier circuit may be a non-controlled rectifier circuit or a PFC circuit. The adapter may be an adapter having an electrolytic capacitor, or may be an adapter having no electrolytic capacitor. When the adapter has no electrolytic capacitor, the first direct current output by the adapter is a pulsating direct current. When the adapter has no electrolytic capacitor, it is conducive to achieving miniaturization of the adapter.
According to a sixth aspect, an embodiment may further provide a charging system. The charging system may include the terminal device according to any one of the third aspect and the fourth aspect and the adapter according to any one of the fifth aspect. An output interface of the adapter is coupled to a charging interface of the terminal device. The adapter may charge the terminal device.
According to a seventh aspect, an embodiment may further provide a charging method. The charging method is applied to the charging circuit provided in any one of the first aspect, the charging circuit is separately connected to a charging interface of a terminal device and a terminal battery, and the charging interface may receive a first direct current output by an adapter. For an effect of a corresponding solution in the seventh aspect, refer to an effect that can be obtained in the corresponding solution in the first aspect. Repeated parts are not described in detail.
For example, the charging method provided in this embodiment may include: when a voltage of the charging interface is greater than or equal to a threshold voltage, transmitting the first direct current to the terminal battery from the charging interface, and modulating a voltage of the first direct current to a charging voltage to charge the terminal battery; or when a voltage of the charging interface is less than a threshold voltage, transmitting a second direct current from the terminal battery to the charging interface, and modulating a voltage of the second direct current to a first voltage, where the first voltage is greater than or equal to a lowest operating voltage of the adapter. The threshold voltage may be greater than the first voltage.
According to a seventh aspect, an embodiment may further provide a charging method. The charging method is applied to the charging circuit provided in any one of the second aspect, the charging circuit is separately connected to a charging interface of a terminal device and a terminal battery, and the charging interface may receive a first direct current output by an adapter. For an effect of a corresponding solution in the eighth aspect, refer to an effect that can be obtained in the corresponding solution in the second aspect. Repeated parts are not described in detail.
For example, the charging method provided in this embodiment may include: transmitting the first direct current to the terminal battery from the charging interface, and modulating a voltage of the first direct current to a charging voltage to charge the terminal battery, and when a voltage of the charging interface decreases from being greater than or equal to a threshold voltage to being less than the threshold voltage, decreasing a charging current provided to the terminal battery, to maintain the voltage of the charging interface to be greater than or equal to a lowest operating voltage of the adapter. The threshold voltage may be greater than the lowest operating voltage of the adapter.
These aspects may be more readily apparent from the following description of the embodiments.
To make the objectives, solutions, and advantages clearer, the following further describes the embodiments in detail with reference to the accompanying drawings. A operation in a method embodiment may also be applied to an apparatus embodiment or a system embodiment. It should be noted that “at least one” means one or more, and “a plurality of” means two or more. In view of this, “a plurality of” may also be understood as “at least two”. The term “and/or” describes an association relationship for describing associated objects and represents that three relationships may exist. For example, A and/or B may represent the following three cases: only A exists, both A and B exist, and only B exists. In addition, the character “/” may indicate an “or” relationship between the associated objects. In addition, it should be understood that in description, terms such as “first” and “second” are merely used for distinguishing and description, but should not be understood as indicating or implying relative importance, or should not be understood as indicating or implying a sequence.
The following clearly and completely describes the embodiments with reference to the accompanying drawings.
In a current terminal consumer market, most terminal devices have a feature of energy storage. For a mobile terminal device, such as a smartphone, a tablet computer, or a notebook computer, energy storage becomes one of basic functions of the mobile terminal device. An energy storage function of the terminal device may depend on a terminal battery inside the terminal device, and the terminal battery is a battery (which may also be referred to as a secondary battery). The terminal battery may supply power to the terminal device when the terminal device works, or may store electric energy when the terminal device is charged.
The terminal device may be provided with an adapter and the adapter may charge the terminal device. As shown in
The industrial frequency power supply 14 may be a household socket, a power strip, and the like, and may output an alternating current. The adapter 12 may convert the alternating current output by the industrial frequency power supply 14 into a direct current, and then input the direct current to the terminal device 11 by using the data cable 13. The terminal device 11 may further charge the terminal battery inside the terminal device 11 by using the received direct current.
The following further describes the adapter 12 by using an example.
When the adapter 12 works, the industrial frequency rectifier unit 122 may convert an alternating current received by the alternating current interface 121 into a direct current, and provide the direct current to the electrolytic capacitor 123. The industrial frequency rectifier unit 122 may include an alternating current-direct current conversion circuit, to implement rectification. The industrial frequency rectifier unit 122 may convert the alternating current into the direct current and may not have a function of regulating the direct current. Therefore, the direct current obtained by the industrial frequency rectifier unit 122 is a pulsating direct current, that is, a voltage of the direct current is a pulsating direct current voltage, and a voltage fluctuates periodically.
A sine alternating current is used as an example. A voltage of the direct current obtained after rectification by the industrial frequency rectifier unit 122 may be shown in
The electrolytic capacitor 123 may regulate the voltage of the pulsating direct current provided by the industrial frequency rectifier unit 122, to provide a stable direct current to the transformer 124. For example, as shown in
If a stable direct current needs to be provided to the transformer 124, power of the direct current provided to the transformer 124 may need to be stable. However, for the pulsating direct current output by the industrial frequency rectifier unit 122, a power of the pulsating direct current also pulsates. In other words, although an average output power of the industrial frequency rectifier unit 122 can match an input power required by the transformer 124, an instantaneous output power of the industrial frequency rectifier unit 122 does not match an instantaneous input power required by the transformer 124.
In view of this, the electrolytic capacitor 123 may be disposed between the industrial frequency rectifier unit 122 and the transformer 124. When the instantaneous output power of the industrial frequency rectifier unit 122 is greater than the instantaneous input power required by the transformer 124, the electrolytic capacitor 123 may store redundant electric energy to stabilize an input power of the transformer 124. Therefore, the capacitor voltage of the electrolytic capacitor 123 increases. When the instantaneous output power of the industrial frequency rectifier unit 122 is less than the instantaneous input power required by the transformer 124, the electrolytic capacitor 123 may release stored electric energy to stabilize the input power of the transformer 124. Therefore, the capacitor voltage of the electrolytic capacitor 123 decreases.
In other words, the electrolytic capacitor 123 is disposed between the industrial frequency rectifier unit 122 and the transformer 124, so that an output power of the industrial frequency rectifier unit 122 and the input power of the transformer 124 can be decoupled. In addition, because the output power of the industrial frequency rectifier unit 122 depends on the input power of the adapter 12, and the input power of the transformer 124 determines an output power of the adapter 12. Therefore, the electrolytic capacitor 123 is disposed to decouple the input power and the output power of the adapter 12, that is, the instantaneous output power of the adapter 12 may be unequal to the instantaneous input power of the adapter 12. The adapter 12 may maintain a stable output power, and the adapter 12 may maintain a stable output voltage without considering a change of an output current.
The control unit 128 may control the switch unit 127 to be periodically turned on and off, so that the transformer 124 completes voltage conversion. The switch unit 127 may be a power switch tube, and the control unit 128 may be a logic circuit having a logical operation capability, or may be a controller. The control unit 128 may control, by using the switch unit 127, the transformer 124, and modulate the voltage of the direct current provided by the electrolytic capacitor 123. This process may also be referred to as voltage conversion.
A voltage of the alternating current provided by most industrial frequency power supplies 14 may be excessively high, and consequently, the voltage of the direct current provided by the electrolytic capacitor 123 may also be high and may not be directly provided to the terminal device 11. The control unit 128 may control the transformer 124 to modulate the voltage of the direct current provided by the electrolytic capacitor 123 to a lower voltage of an alternating current by controlling the switch unit 127 to be turned on and off. The back-end rectifier unit 125 may convert the alternating current output by the transformer 124 into a direct current, and may further output the direct current through the output interface 126. The transformer 124 cooperates with the back-end rectifier unit 125 to implement voltage reduction, so that the voltage of the direct current output by the adapter 12 can adapt to the terminal device 11.
It can be understood from the foregoing example that, in the adapter 12 shown in
In addition, for the stable direct current, a power, a voltage, and a current of the stable direct current may also be changed under control of the control unit 128. For example, the control unit 128 may flexibly adjust control logic of the switch unit 127 based on a charging status of the terminal device 11, to adjust the output voltage, the output current, and/or the output power of the adapter 12.
Although the adapter 12 in
As shown in
In a possible implementation, the adapter 14 may further include an electromagnetic interference (EMI) filter. One end of the EMI filter is connected to the alternating current interface 121, and the other end is connected to the industrial frequency rectifier unit 122, so that high-frequency noise in the alternating current can be preliminarily filtered out.
By comparing the adapter 14 with the adapter 12, the adapter 14 may not include an electrolytic capacitor 123, so that a volume of the adapter 14 is reduced, costs are reduced, and power density is increased. In addition, the adapter 14 does not include the electrolytic capacitor 123, so that a safety problem caused by electrolyte leakage of the electrolytic capacitor and a service life bottleneck problem of the electrolytic capacitor can be avoided.
However, as described above, the electrolytic capacitor 123 in the adapter 12 enables the adapter 12 to output the stable direct current. After the electrolytic capacitor 123 is removed, the adapter 14 cannot output the stable direct current. A direct current output by the adapter 14 is changed to a pulsating direct current, that is, a power of the direct current output by the adapter 14 fluctuates.
For example, as shown in
After the electrolytic capacitor 123 is removed from the adapter 14, it is possible that the adapter 14 cannot continuously charge the terminal device 11. For example, a protection mechanism may be disposed in the adapter 14, and the control unit 128 may monitor, by detecting a voltage of the output interface 126, whether the adapter 14 works normally. When the voltage of the output interface 126 is low, the protection mechanism may be triggered, and the control unit 128 controls the transformer 124 to stop working, so that the adapter 14 stops working.
Because the adapter 14 may output the pulsating direct current, the voltage of the output interface 126 (that is, the output voltage of the adapter 14) fluctuates periodically. When the voltage of the output interface 126 fluctuates to a low voltage, the protection mechanism in the adapter 14 may be triggered by mistake, so that the adapter 14 stops working.
In addition, the adapter 14 is further provided with a plurality of functional chips, such as a charging protocol chip. A direct current output by the output interface 126 may further supply power to the charging protocol chip. When the voltage of the output interface 126 is low, the charging protocol chip may stop working, so that the adapter 14 stops working.
In conclusion, after the electrolytic capacitor 123 in the adapter 14 is removed, although a volume of the adapter 14 is reduced, a problem that the adapter 14 cannot continuously charge the terminal device 11 is caused. In view of this, how to enable the adapter 14 having no electrolytic capacitor to continuously charge the terminal device 11 becomes one of problems to be resolved.
For the problem, in a direct charging architecture, a function of replacing the electrolytic capacitor 123 with a terminal battery may be used, so that the adapter 14 can continuously charge the terminal device 11. For example, as shown in
In the terminal device 11-1 shown in
In the direct charging architecture, the terminal battery 112 may clamp the output voltage of the adapter 14, and function as the electrolytic capacitor 123. In the direct charging architecture, the voltage of the output interface 126 of the adapter 14 may be equivalent to a battery voltage of the terminal battery 112. When the output voltage of the adapter 14 is low, the terminal battery 112 may discharge for a short time, so that the voltage of the output interface 126 of the adapter 14 is maintained near the battery voltage. Therefore, in the direct charging architecture shown in
However, because the output voltage of the adapter 14 is clamped by the terminal battery 112, flexible configuration of the adapter 14 is also limited. For example, if an output power of the adapter 14 needs to be further increased, when the output voltage of the adapter 14 remains unchanged, the output power of the adapter 14 can be increased only by increasing the output current of the adapter 14. However, an excessively high output current imposes a high requirement on an overcurrent capability of a structure or a component such as the output interface 126, a data line 13, and the charging interface 111.
If an output power is increased by increasing the output voltage of the adapter 14, the battery voltage may be increased by connecting a battery electric core in series, to increase the output voltage of the adapter 14. In this implementation, a volume of the terminal battery 112 is increased, which is not conducive to improving energy density of the terminal battery 112. In addition, if the battery voltage of the terminal battery 112 is excessively high, when the terminal battery 112 supplies power to the terminal device 11-1, utilization of electric energy in the terminal battery 112 by the terminal device 11-1 is also reduced.
In view of this, an embodiment may provide a terminal device. The terminal device not only includes a charging interface and a terminal battery, but also includes a charging circuit between the charging interface and the terminal battery. The charging circuit is disposed, the output voltage of the adapter may be clamped, and the charging interface may be decoupled from the terminal battery, which is not only conducive to achieving miniaturization of the adapter, but also conducive to flexible configuration of the adapter.
Next, the charging interface 111 and the charging circuit 113 are separately further described.
1. Charging Interface 111
In this embodiment, the charging interface 111 may be an interface that complies with a charging protocol in the terminal device 11-2, for example, a universal serial bus (USB) interface or a type-C (Type-C) interface. When charging the terminal device 11-2, the charging interface 111 may be directly connected to the adapter 14 or may be connected to the adapter 14 by using a data cable, so that the charging interface 111 may receive a first direct current I1 provided by the adapter 14 or the adapter 12.
It should be noted that the terminal device 11-2 provided in this embodiment may support charging of the adapter 12 having the electrolytic capacitor 123, and may also support charging of the adapter 14 having no electrolytic capacitor 123. In other words, the first direct current I1 received by the charging interface 111 may be a stable direct current, or may be a pulsating direct current, and the terminal device 11-2 may complete charging by using the first direct current I1 received by the charging interface 111.
For ease of understanding, in this embodiment, an example in which the adapter 14 charges the terminal device 11-2 and the first direct current I1 is the pulsating direct current is used for description. When the first direct current I1 is the stable direct current, refer to a conventional stable direct current charging process, and details are not described herein again.
2. Charging Circuit 113
In this embodiment, the charging circuit 113 may modulate a voltage of the first direct current I1 output by the adapter 14 to a charging voltage that adapts to the terminal battery 112, to charge the terminal battery 112. In other words, the output voltage of the adapter 14 is no longer limited by clamping of the battery voltage of the terminal battery 112, so that decoupling between the output voltage of the adapter 14 and the battery voltage of the terminal battery 112 is implemented. In this case, the adapter 14 can increase the output power by increasing the output voltage, to further improve a charging speed. Therefore, a charging system shown in
In addition, the charging circuit 113 may further clamp the output voltage of the adapter 14, so that the adapter 14 can continuously charge the terminal device 11-2. In a possible implementation, the charging circuit 113 may have a bidirectional power transmission function. In this case, the charging circuit 113 may discharge by using the terminal battery 112 and apply a stable first voltage V1 to the charging interface 111. In another possible implementation, the charging circuit 113 may have a unidirectional transmission function. In this case, the charging circuit 113 may adjust the output current of the adapter 14 by adjusting the charging current provided to the terminal battery 112, so that when an instantaneous power of the first direct current I1 output by the adapter 14 is small, the output voltage of the adapter 14 may remain at a large value.
The following further describes the foregoing two implementations separately by using examples.
Implementation 1: Bidirectional Transmission
For the charging circuit 113 of bidirectional transmission, the charging circuit 113 may transmit a direct current from the charging interface 111 to the terminal battery 112 and may also transmit a direct current from the terminal battery 112 to the charging interface 111. In this embodiment, when a voltage of the charging interface 111 is greater than or equal to a threshold voltage V0, the charging circuit 113 may modulate a voltage of the first direct current I1 received by the charging interface 111, to modulate the voltage of the first direct current I1 to a charging voltage, to charge the terminal battery 112.
When the terminal battery 112 is charged, the charging voltage output by the charging circuit 113 may meet a charging requirement of the terminal battery 112, and the charging voltage may be a voltage within a range. The charging voltage output by the charging circuit 113 may need to be greater than the battery voltage of the terminal battery 112, to implement charging. The charging voltage cannot be excessively high, to prevent the terminal battery 112 from being overheated, thereby affecting a life of the terminal battery 112.
In this embodiment, the adapter 14 may have a large average output voltage, to improve a charging speed. When the voltage of the charging interface 111 is greater than or equal to the threshold voltage V0, it indicates that a current output voltage of the adapter 14 is large, and the adapter 14 does not stop working. In this case, the charging circuit 113 may modulate the voltage of the received first direct current I1, so that the modulated voltage of the first direct current I1 can adapt to the terminal battery 112, thereby charging the terminal battery 112.
The charging circuit 113 may further transmit a second direct current I2 from the terminal battery 112 to the charging interface 111 when the voltage of the charging interface 111 is less than the threshold voltage V0. The second direct current I2 is a direct current output by the terminal battery 112. The charging circuit 113 may modulate a voltage of the second direct current I2, and modulate the voltage of the second direct current I2 to a first voltage V1, where the first voltage V1 is greater than or equal to lowest operating voltage of the adapter 14.
In this embodiment, the lowest operating voltage of the adapter 14 may be understood as a minimum value of an output voltage of the adapter 14 when the adapter 14 can continuously charge the terminal device 11-2. In other words, when the output voltage of the adapter 14 is lower than the lowest operating voltage, the adapter 14 stops charging the terminal device 11-2.
As described above, because the first direct current I1 is the pulsating direct current, an instantaneous voltage of the first direct current I1 at some time points may be low, so that the adapter 14 stops charging the terminal device 11-2. In this embodiment, when the voltage of the charging interface 111 is less than the threshold voltage V0, it indicates that the voltage of the first direct current I1 is low. In this case, the charging circuit 113 may discharge by using the terminal battery 112, and stabilize the voltage of the charging interface 111 at the first voltage V1, where the first voltage V1 is greater than or equal to the lowest operating voltage of the adapter 14.
It can be understood from
It should be noted that when the charging circuit 113 applies the first voltage V1 to the charging interface 111, electric energy is transmitted by the terminal device 11-2 to the adapter 14. In this embodiment, “the adapter 14 may continuously charge the terminal device 11-2” is described from a perspective of a complete charging process. In other words, although the terminal battery 112 may be temporarily discharged at some time points in the charging process, overall, power stored in the terminal battery 112 continuously increases.
It may be understood that the charging circuit 113 in this embodiment has a plurality of possible implementations. For example, the charging circuit 113 may include a first transmission path and a second transmission path. The first transmission path may be used to transmit the first direct current I1 to the terminal battery 112 from the charging interface 111, and the second transmission path may be used to transmit the second direct current to the charging interface 111 from the terminal battery 112. The charging circuit 113 may separately connect or disconnect the first transmission path and the second transmission path based on a relative value relationship between the voltage of the charging interface 111 and the threshold voltage V0.
In another possible implementation, as shown in
The conversion circuit 1131 may transmit the first direct current to the terminal battery 112 from the charging interface 111, or may transmit the second direct current to the charging interface 111 from the terminal battery 112. When transmitting the first direct current and the second direct current, the conversion circuit 1131 may further modulate voltages of the first direct current and the second direct current under control of the controller 1132.
In this embodiment, the conversion circuit 1131 may include one or more direct current-to-direct current conversion circuits connected in series or in parallel. For example, the conversion circuit 1131 may include, but is not limited to, one or more of the following circuits: a linear voltage regulator power supply circuit, a buck (Buck) conversion circuit, a boost (Boost) conversion circuit, a buck-boost (Buck-Boost) conversion circuit, a three-level buck (Buck) conversion circuit, a switched-capacitor conversion circuit, an inductor-inductor-capacitor (LLC) resonant conversion circuit, a dual active full-bridge direct current-direct current (dual active bridge, DAB) conversion circuit, a forward conversion circuit, a flyback conversion circuit, a half-bridge push-pull circuit, a full-bridge push-pull circuit, a full-bridge phase-shift conversion circuit, and the like. Details are not listed in this embodiment.
The controller 1132 is connected to a control end of the conversion circuit 1131 and may control the conversion circuit 1131 to perform voltage modulation (conversion). The conversion circuit 1131 may include one or more switching transistors, and a control end of the conversion circuit 1131 may include control electrodes (gates) of these switching transistors. The controller 1132 may be a logic circuit having a logic operation capability, can generate a control signal, and separately control, based on the control signal, each of the switch transistors in the conversion circuit 1131 to be turned on or off, to control the conversion circuit 1131 to implement voltage conversion.
In this embodiment, when the voltage of the charging interface 111 is greater than or equal to the threshold voltage V0, the controller 1132 may control the conversion circuit 1131 to modulate the voltage of the first direct current I1 to the charging voltage, to charge the terminal battery 112. When the voltage of the charging interface 111 is less than the threshold voltage V0, the conversion circuit 1131 is controlled to modulate the voltage of the second direct current I2 to the first voltage V1.
In the first implementation, the controller 1132 may control the conversion circuit 1131 to switch a direct current transmission direction in an opened-loop manner, that is, the conversion circuit 1131 automatically switches the direct current transmission direction. The controller 1132 may alternatively control the conversion circuit 1131 to switch a direct current transmission direction in a closed-loop manner, that is, the conversion circuit 1131 switches the direct current transmission direction under control of the controller 1132. The following separately describes the cases.
1. Control the Conversion Circuit 1131 in the Opened-Loop Manner
The open-loop control may be applied to some direct current-direct current conversion circuits, such as a switched-capacitor conversion circuit. When the voltage of the charging interface 111 is less than the threshold voltage V0, the conversion circuit 1131 may switch the direct current transmission direction to a direction from the terminal battery 112 to the charging interface 111. When the voltage of the charging interface 111 is greater than the threshold voltage V0, the conversion circuit 1131 may switch the direct current transmission direction to a direction from the charging interface 111 to the terminal battery 112.
The threshold voltage V0 may be N times a current battery voltage of the terminal battery 112, where N is a voltage conversion ratio of the conversion circuit 1131.
For example, it is assumed that a current voltage conversion ratio of the conversion circuit 1131 is 2:1, that is, the conversion circuit 1131 may modulate the voltage of the first direct current I1 from V to V/2. The threshold voltage is twice the battery voltage. For example, if the battery voltage is 3 V, the threshold voltage is 6 V. When the voltage of the charging interface 111 is lower than 6 V, the voltage of the first direct current I1 modulated by the conversion circuit 1131 is lower than 3 V and cannot meet a charging requirement of the terminal battery 112. Therefore, the terminal battery 112 stops charging and starts discharging. The terminal battery 112 outputs the second direct current, so that the conversion circuit 1131 automatically switches the direct current transmission direction to a direction from the terminal battery 112 to the charging interface 111.
It should be understood that, in a charging process of the terminal battery 112, both the battery voltage of the terminal battery 112 and the voltage conversion ratio of the conversion circuit 1131 may dynamically change. Therefore, for the conversion circuit 1131 applicable to the open-loop control, the threshold voltage V0 may also dynamically change. For the conversion circuit 1131 applicable to the open-loop control, the controller 1132 does not need to change a control signal provided to the conversion circuit 1131 due to the change of the direct current transmission direction, and control logic of the controller 1132 is simpler.
The following further describes the charging circuit 113 by using an example in which the converter circuit 1131 is a switched-capacitor converter circuit. As shown in
In a charging process, the controller 1132 may periodically control the switching transistors T1, T2, T3, and T4. The switching transistors T1 and T4 are synchronously turned on and off, the switching transistors T2 and T3 are synchronously turned on and off, and the switching transistors T1 and T2 are alternately turned on and off. In this embodiment, control of the switching transistors T1, T2, T3, and T4 by the controller 1132 is not affected by the direct current transmission direction in the conversion circuit 1131.
2. Control the Conversion Circuit 1131 in the Closed-Loop Manner
The open-loop control may be applied to some direct current-direct current conversion circuits, such as a buck conversion circuit, a boost conversion circuit, and a buck-boost conversion circuit. That is, these direct current-direct current conversion circuits each cannot automatically switch a direct current transmission direction, and the controller 1132 may control each of these direct current-direct current conversion circuits to change the direct current transmission direction.
In this case, the controller 1132 needs to be capable of detecting a voltage status of the charging interface 111, to control the direct current transmission direction of the conversion circuit 1131. In view of this, as shown in
When the voltage of the charging interface 111 increases from being less than the threshold voltage V0 to being greater than or equal to the threshold voltage V0, the charging interface 111 may further send a first indication signal to the controller 1132. In this case, after the controller 1132 receives the first instruction signal, it means that the voltage of the charging interface 111 is in a state greater than or equal to the threshold voltage V0. The controller 1132 may control the conversion circuit 1131 to transmit the first direct current I1 to the terminal battery 112 from the charging interface 111. In addition, the controller 1132 may further control the conversion circuit 1131 to modulate the voltage of the first direct current I1 to the charging voltage, to charge the terminal battery 112.
When the voltage of the charging interface 111 decreases from being greater than or equal to the threshold voltage V0 to being less than the threshold voltage V0, the detection circuit 1133 may send a second indication signal to the controller 1132. In this case, after the controller 1132 receives the second indication signal, it means that the voltage of the charging interface 111 is in a state less than the threshold voltage V0. The controller 1132 may control the conversion circuit 1131 to transmit the second direct current I2 from the terminal battery 112 to the charging interface 111. In addition, the controller 1132 may further control the conversion circuit 1131 to modulate the voltage of the second direct current I2 to the first voltage V1.
It may be understood that, because a voltage change of the charging interface 111 is periodic, the controller 1132 may also periodically control, based on a voltage change period of the charging interface 111, the conversion circuit 1131 to switch the direct current transmission direction. For example, the voltage change period of the charging interface 111 is T, the voltage of the charging interface 111 is greater than or equal to the threshold voltage V0 in a first T/2 time of a period, and the voltage of the charging interface 111 is less than the threshold voltage V0 in a second T/2 time of a period. In this case, the controller 1132 may also control the conversion circuit 1131 to switch the direct current transmission direction based on the period T, control the conversion circuit 1131 to transmit the first direct current I1 from the charging interface 111 to the terminal battery 112 in the first T/2 time of a period, and control the conversion circuit 1131 to transmit the second direct current I1 from the terminal battery 112 to the charging interface 111 in the second T/2 time of a period. In this implementation, the detection circuit 1133 can be omitted, and a structure of the charging circuit 113 is simplified.
Implementation 2: Unidirectional Transmission
In this implementation 2, the charging circuit 113 may modulate the voltage of the first direct current I1 received by the charging interface 111 to a charging voltage, to charge the terminal battery 112. In addition, when the voltage of the charging interface 111 decreases from being greater than or equal to the threshold voltage V0 to being less than the threshold voltage V0, the charging circuit 113 may decrease a charging current provided to the terminal battery 112, to maintain the voltage of the charging interface 111 to be greater than or equal to a lowest operating voltage of the adapter 14.
In a case in which an output current of the adapter 14 remains unchanged, when a power of the first direct current output I1 by the adapter 14 decreases, an output voltage of the adapter 14 may also decrease, so that the voltage of the charging interface 111 may decrease accordingly. In this embodiment, when the voltage of the charging interface 111 is less than the threshold voltage V0, the charging circuit 113 decreases the charging current provided to the terminal battery 112, that is, the output current of the charging circuit 113.
Because an input current and an output current of the charging circuit 113 need to meet a current conversion ratio, when the current conversion ratio remains unchanged, an output current of the charging circuit 113 decreases, and consequently, an output current of the adapter 14 decreases. In addition, because of a conversion relationship between a voltage, a current, and a power, that is, a product of the voltage and the current is equal to the power, the adapter 14 decreases the output current, so that when the output power of the adapter 14 is decreased, the output voltage of the adapter 14 can be maintained to be not excessively decreased, thereby avoiding triggering a protection mechanism in the adapter 14, and enabling the adapter 14 to continuously charge the terminal device 11-2.
Similar to the foregoing implementation 1, in the implementation 2, the charging circuit 113 may also include a conversion circuit 1131 and a controller 1132. A first transmission end of the conversion circuit 1131 is configured to connect to the charging interface 111 of the terminal device 11-2, and the charging interface 111 receives the first direct current I1 provided by the adapter 14. A second transmission end of the conversion circuit 1131 is configured to connect to the terminal battery 112.
The controller 1132 may control the conversion circuit 1131 to modulate the voltage of the first direct current I1 to the charging voltage, to charge the terminal battery 112. For an implementation of the process, refer to the foregoing implementation of bidirectional transmission, and details are not described herein again. When the voltage of the charging interface 111 is less than the threshold voltage V0, the controller 1132 may further decrease the charging current provided to the terminal battery 112, to maintain the voltage of the charging interface 112 to be greater than or equal to the lowest operating voltage of the adapter.
The threshold voltage V0 may be greater than the lowest operating voltage of the adapter 14, to avoid that the adapter 14 stops charging the terminal device 11-2 because the output voltage of the adapter 14 is excessively low.
In a possible implementation, the charging circuit 112 may further increase the charging current provided to the terminal battery 11-2 after the voltage of the charging interface 111 increases from being less than the threshold voltage V0 to being greater than or equal to the threshold voltage V0.
After the voltage of the charging interface 111 increases from being less than the threshold voltage V0 to being greater than or equal to the threshold voltage V0, the power of the first direct current I1 may be large. In this case, the charging current provided to the terminal battery 11-2 may be increased, and the voltage value of the first direct current I1 may be appropriately decreased, to improve conversion efficiency of the conversion circuit 1131.
For example, the conversion circuit 1131 may include one or more direct current-direct current conversion circuits. For example, the converter circuit 1131 may include, but is not limited to, one or more of the following circuits: a linear voltage regulator power supply circuit, a buck conversion circuit, a boost conversion circuit, a buck-boost conversion circuit, a three-level buck conversion circuit, a switched-capacitor conversion circuit, an LLC resonant conversion circuit, a DAB conversion circuit, a forward conversion circuit, a flyback conversion circuit, a half-bridge push-pull circuit, a full-bridge push-pull circuit, a full-bridge phase-shift conversion circuit, and the like. Details are not listed in this embodiment.
An example in which the conversion circuit 1131 is the buck conversion circuit is used. As shown in
In this embodiment, the charging circuit 113 may further include a detection circuit 1133. One end of the detection circuit 1133 is connected to the first transmission end, and the other end of the detection circuit 1133 is connected to the controller 1132. The detection circuit 1133 may detect the voltage of the charging interface 111. In the implementation 2, the voltage of the charging interface 111 is equivalent to the voltage of the first direct current I1.
When the voltage of the charging interface 111 decreases from being greater than or equal to the threshold voltage V0 to being less than the threshold voltage V0, the detection circuit 1133 may send a third indication signal to the controller 1132. After receiving the third indication signal, the controller 1132 may further reduce the output current of the conversion circuit 1131, that is, the charging current provided to the terminal battery 112.
In a possible implementation, when the voltage of the charging interface 111 increases from being less than the threshold voltage V0 to being greater than or equal to the threshold voltage V0, the detection circuit 1133 may further send a fourth indication signal to the controller 1132. After receiving the fourth indication signal, the controller 1132 may further increase the output current of the conversion circuit 1131, that is, the charging current provided to the terminal battery 112.
It can be understood from the foregoing descriptions of the terminal device 11-2 that the terminal device 11-2 in this embodiment may be continuously charged by using the adapter 14 having no electrolytic capacitor. For example, an embodiment may further provide an adapter 1100 having no electrolytic capacitor shown in
The adapter 1100 may include an alternating current interface 1101, a first rectifier circuit 1102, a direct-to-direct current converter 1103, and an output interface 1104. An input end of the first rectifier circuit 1101 is connected to the alternating current interface 1101. An output end of the first rectifier circuit 1101 is connected to an input end of the direct current-direct current converter 1102. An output end of the direct current-direct current converter 1102 is connected to the output interface 1104.
The alternating current interface 1101 may receive an alternating current. The first rectifier circuit 1102 may convert the alternating current into the first direct current I1, and then output the first direct current I1 to the direct current-direct current converter 1103. A voltage of the first direct current I1 output by the first rectifier circuit 1102 may be high, so that the first direct current I1 cannot be directly input to the terminal device 11-2. The direct current-direct current converter 1103 may modulate the voltage of the first direct current I1, reduce the voltage of the first direct current I1, and output the modulated first direct current I1 through the output interface 1104.
In this embodiment, the first rectifier circuit 1102 may be an uncontrolled rectifier circuit or a PFC circuit. For example, as shown in
For example, the direct current-direct current converter 1103 in this embodiment may include a transformer 124, a downstream rectifier circuit 125, a control unit 128, and a switch unit 127. A first electrode of the switch unit 127 is connected to the transformer 124, a second electrode of the switch unit 127 is grounded, and a control electrode of the switch unit 127 is connected to the control unit 128. The switch unit 127 may be turned on and off under control of the control unit 128.
The back-end rectifier circuit 125 may include a rectifier diode and a secondary capacitor, where an anode of the rectifier diode is connected to the transformer 124, a cathode of the rectifier diode is separately connected to one end of the secondary capacitor and the output interface 1104, and the other end of the secondary capacitor is separately connected to the transformer 124 and the output interface 1104. The back-end rectifier circuit 125 may convert the alternating current voltage output by the transformer 124 into the first direct current I1, and output the first direct current I1 through the output interface 1104.
It may be understood that, in a process in which the adapter 14 continuously charges the terminal device 11-2, the control unit 128 may further interact with the terminal device 11-2 through the output interface 126, to obtain current status information of the terminal battery 112. The control unit 128 may further flexibly adjust a control policy for the switch unit 127 based on the current status information of the terminal battery 112, to adjust the output power and/or the output current and/or the output voltage of the adapter 14, thereby further optimizing a charging effect.
An embodiment may further provide a charging method. The charging method may be further applied to the charging circuit 123 shown in
For example, in a possible implementation, the charging method provided in this embodiment may include the following steps shown in
S1201: When a voltage of the charging interface 121 is greater than or equal to a threshold voltage V0, transmit the first direct current I1 from the charging interface 121 to the terminal battery 122, and modulate a voltage of the first direct current I1 to a charging voltage to charge the terminal battery 122.
S1202. When a voltage of the charging interface 121 is less than a threshold voltage V0, transmit a second direct current I2 from the terminal battery 122 to the charging interface 121, and modulate a voltage of the second direct current I2 to a first voltage V1.
In this embodiment, the first voltage V1 is greater than or equal to a lowest operating voltage of the adapter 124. Therefore, when the voltage of the first direct current I1 output by the adapter 14 is low, the first voltage V1 may be applied to the charging interface 121. The first voltage V1 may be equivalent to a voltage of an output interface 126 of the adapter 14. Therefore, according to the charging method provided in this embodiment, the voltage of the output interface 126 of the adapter 14 can be maintained above the lowest operating voltage of the adapter 14, so that the adapter 14 can continuously charge the terminal device 12-2.
In a possible implementation, the threshold voltage V0 is greater than the first voltage V1. In this case, the charging circuit 123 may switch a direct current transmission direction when the voltage of the charging interface 121 is low, to prevent the adapter 14 from stopping working when the voltage of the charging interface 121 (that is, the voltage of the output interface 126) is excessively low and the charging circuit 123 does not switch the direct current transmission direction.
For implementations of S1201 and S1202, refer to the actions performed by the charging circuit 123 in the foregoing implementation 1. Details are not described herein again.
For example, in another possible implementation, the charging method provided in this embodiment may include the following steps shown in
S1301: Transmit the first direct current I1 from the charging interface 111 to the terminal battery 113 and modulate a voltage of the first direct current I1 to a charging voltage to charge the terminal battery 113.
S1302: When a voltage of the charging interface 111 decreases from being greater than or equal to a threshold voltage V0 to being less than the threshold voltage V0, decrease a charging current provided to the terminal battery 113, to maintain the voltage of the charging interface 111 to be greater than or equal to a lowest operating voltage of the adapter 14.
In this implementation, the voltage of the charging interface 111 is equivalent to the voltage of the first direct current I1. When the voltage of the charging interface 111 decreases from being greater than or equal to the threshold voltage V0 to being less than the threshold voltage V0, it indicates that the current voltage of the first direct current I1 is too low. The charging circuit 113 decreases a charging current provided to the terminal battery 113, so that an output current of the adapter 14 can be reduced. It can be understood from a correlation relationship between a current, a voltage, and a power that, when a power of the first direct current I1 output by the adapter 14 is reduced, output voltage reduction may be suppressed by reducing the output current, so that the voltage of the output interface 136 may be maintained above the lowest operating voltage of the adapter 14, and the adapter 14 can continuously charge the terminal device 11-2.
In a possible implementation, the threshold voltage V0 is greater than the lowest operating voltage of the adapter 14. In this way, the adapter 14 can be prevented from stopping working because the voltage of the output interface 136 is excessively low.
For implementations of S1301 and S1302, refer to the actions performed by the charging circuit 113 in the foregoing implementation 2. Details are not described herein again.
A person skilled in the art should understand that embodiments may be provided as a method, a system, or a computer program product. Therefore, the embodiments may use a form of hardware or a combination of software and hardware. In addition, the embodiments may use a form of a computer program product that is implemented on one or more non-transitory computer-usable storage media (including, but not limited to, a disk memory, a CD-ROM, an optical memory, and the like) that include computer-usable program code.
The embodiments are described with reference to the flowcharts and/or block diagrams of the method, the device (system), and the computer program product. It should be understood that computer program instructions may be used to implement each process and/or each block in the flowcharts and/or the block diagrams and a combination of a process and/or a block in the flowcharts and/or the block diagrams. These computer program instructions may be provided to a general-purpose computer, a dedicated computer, an embedded processor, or a processor of any other programmable data processing device to generate a machine, so that the instructions executed by a computer or a processor of any other programmable data processing device generate an apparatus for implementing a function in one or more processes in the flowcharts and/or in one or more blocks in the block diagrams.
These computer program instructions may be stored in a non-transitory computer-readable memory that can instruct the computer or any other programmable data processing device to work in a manner, so that the instructions stored in the non-transitory computer-readable memory generate an artifact that includes an instruction apparatus. The instruction apparatus implements a function in one or more processes in the flowcharts and/or in one or more blocks in the block diagrams.
The computer program instructions may alternatively be loaded onto a computer or another programmable data processing device, so that a series of operations and steps are performed on the computer or the another programmable device, so that computer-implemented processing is generated. Therefore, the instructions executed on the computer or the another programmable device provide steps for implementing a function in one or more procedures in the flowcharts and/or in one or more blocks in the block diagrams.
It is clearly that a person skilled in the art can make various modifications and variations without departing from the scope of the embodiments and their equivalent technologies.
This application is a continuation of International Application No. PCT/CN2020/109574, filed on Aug. 17, 2020, the disclosure of which is hereby incorporated by reference in its entirety.
Number | Date | Country | |
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Parent | PCT/CN2020/109574 | Aug 2020 | US |
Child | 18170603 | US |