KR20220108752A - Wireless power receiving apparatus for low heat and method thereof - Google Patents

Abstract

The present invention is to receive a wireless power signal transmitted by a wireless power transmitting device to control to charge a battery with low heat. The present invention relates to a low heat wireless power receiving device and a method thereof which allow a control unit to control an impedance matching/control unit to match impedance when a power receiving coil receives a wireless power signal, allow the control unit to determine a charging load state of a power receiving device according to a lapse of time for charging power in a power receiving device and a current level that a current detecting unit detects, and selectively turn on a low heat transformation unit and a high heat transformation unit according to the determined charging load state to output power to the power receiving device while minimizing generation of heat.

Description

Apparatus and method for receiving low heat wireless power

The present invention relates to a low heat wireless power receiver and method for receiving a wireless power signal transmitted by a wireless power transmitter and charging a battery with low heat.

In general, various portable terminals such as cell phones and personal digital assistants (PDAs) are equipped with a power receiving device such as a battery pack for supplying operating power by charging power. The power receiving device charges power supplied from an external charging device, and supplies the charged power to the portable terminal to operate.

The power receiving device may include a battery cell for charging power, and a charging/discharging circuit for charging power supplied from an external charging device to the battery cell, discharging the charged power, and supplying it to the portable terminal.

As a method of electrically connecting the charging device and the power receiving device, a power output terminal of a charging device that inputs commercial AC power to output power of a voltage and current corresponding to the power receiving device and a power input terminal of the power receiving device A terminal connection method for directly connecting through cables is known.

However, in the terminal connection method, since the terminals of the charging device and the terminals of the power receiving device have different potentials from each other, an instantaneous discharge phenomenon when the terminal of the charging device and the terminal of the power receiving device are in contact with or separated from each other this will happen

This instantaneous discharge phenomenon wears out the terminal of the charging device and the terminal of the power receiving device, and when foreign substances are accumulated on the terminal of the charging device and the terminal of the power receiving device, heat is generated from the foreign material and a safety accident such as a fire may occur.

In addition, due to moisture, etc., the electric power charged in the battery cells of the power receiving device is naturally discharged to the outside through the terminal of the power receiving device, thereby shortening the service life of the power receiving device and causing deterioration in performance.

Recently, in order to solve various problems of the terminal connection method as described above, the wireless power transmitter wirelessly transmits a power signal, and the wireless power transmitter wirelessly receives the wireless power signal and charges the battery cells. A wireless power receiving device has been proposed (refer to Korean Patent Application Laid-Open No. 10-2012-0128114).

The wireless power receiver is coupled to the wireless power transmitter by electromagnetic induction, for example, receives a wireless power signal wirelessly transmitted by the wireless power transmitter, and charges the received power in a battery cell.

The wireless power receiving device has made a lot of effort to wirelessly receive power stably and with high efficiency so that it can be charged in a battery cell.

The wireless power receiver rectifies the wireless power signal received from the wireless power transmitter with a rectifier to convert it into DC power, and the DC/DC converter converts the converted DC power to the voltage level of the DC power to the voltage level corresponding to the battery cell. It is being converted to and charging the battery cells.

However, converting the voltage level of DC power using the DC/DC converter generates a lot of heat while the DC/DC converter converts the voltage level of DC power, thereby increasing power consumption as well as DC/DC converter. A separate heat dissipation means was required to dissipate the heat generated by the DC converter.

In addition, since the heat dissipation means must be installed on the circuit board, there is a problem in that the size of the circuit board becomes large.

Republic of Korea Patent Publication No. 10-2012-0128114 (published on November 26, 2012)

SUMMARY OF THE INVENTION An object of the present invention is to provide an apparatus and method for receiving low heat wireless power capable of reducing heat generation in the process of charging received power to a power receiving device.

In addition, the problem to be solved by the present invention is to provide a low-heat transformer and a high-heat transformer, and selectively operate the low-heat transformer and the high-heat transformer according to the charging power of the power receiving device while charging the power receiving device to reduce power loss and heat. Provided are an apparatus and method for receiving low heat wireless power that can increase charging efficiency by reducing generation.

According to the low-heat wireless power receiving apparatus and method of the present invention, a low-heat transformer that supplies charging power to the power receiving device while operating with low heat to the charging power output unit, and stable charging power to the power receiving device while operating with high heat It is provided with a high-heat transformer.

In addition, the control unit determines the charging load of the power receiving device as an initial light load state at the initial stage of charging the battery, and turns on the high-heat transformer according to the determined initial light load state to supply stable charging power to the power receiving device. do.

And when stable charging power is supplied to the power receiving device for a set time in the initial light load state, it is determined as a heavy load state, and the low heat generating transformer is turned on to supply sufficient charging power to the power receiving device.

At this time, before turning on the low-heat transformer, both the low-heat transformer and the high-heat transformer are first turned on during the time the low-heat transformer supplies stable power, and the low-heat transformer supplies stable power. When time elapses, the high heat generating transformer is turned off to minimize heat generation.

In addition, the control unit determines the charging current of the power receiving device, and determines whether the power charging of the power receiving device is a light load state or a charging completion state according to the determined charging current.

When the power charging of the power receiving device is in a light load state, the control unit turns on the high-heat transformer to supply charging power to the power receiving device until charging is complete.

In addition, when the charging completion state of the power receiving device is determined, the control unit turns off both the low heat generating transformer and the high heat generating transformer, and ends the charging operation.

Therefore, the low-heat wireless power receiver of the present invention includes a power receiving coil for receiving a wireless power signal, impedance matching so that the power receiving coil resonates with the wireless power signal, and rectifying the wireless power signal into DC power A charging power supply unit comprising an impedance matching/rectifying unit that converts, and a low-heat transformer and a high-heat transformer that are connected in parallel to each other and supply the output power of the impedance matching/rectifying unit as charging power to the power receiving device; and charging the power receiving device A current detection unit for detecting the current level of the electric power to be used, and the impedance matching/rectifying unit controlling the impedance matching of the power receiving device and charging the power to the power receiving device according to the lapse of time and the current level detected by the current detecting unit It may include a control unit that determines the charging load state and selectively turns on the low-heat transformer and the high-heat transformer according to the determined charging load state.

When the power receiving device starts charging power, the controller determines that it is an initial light load state and controls the low heat generating transformer to be turned off and the high heat generating transformer to be turned on. In this case, it is determined as a heavy load state, so that the low heat generating transformer is controlled to be turned on and the high heat generating transformer is controlled to be turned off.

In addition, the control unit turns on both the low-heat transformer and the high-heat transformer for a preset period of time when determining the heavy load, and when the predetermined time elapses, the low-heat transformer continues to be turned on. maintained, and the high-heat transformer may be controlled to be turned off.

In addition, the control unit, when the detected current level of the current detection unit enters a range of a preset first level, it is determined as a light load state, the low-heat transformer is turned off and the high-heat transformer can be controlled to be turned on. .

In addition, when determining the light load state, the control unit controls both the low-heat transformer and the high-heat transformer to be turned on for a predetermined time period, and after the predetermined time elapses, the low-heat transformer is turned off. and the high-heat transformer can be controlled to be turned on.

In addition, the control unit may control to turn off both the low heat generating transformer and the high heat generating transformer when it is determined that the charging of the power receiving device is complete based on the current detected by the current detecting unit.

The low heat generating transformer may be a transformer using an FET as a switching element, and the high heat generating transformer may be an LDO.

And the low-heat wireless power receiving method of the present invention comprises the steps of: when a wireless power signal is received by a power receiving coil, the control unit controls the impedance matching/control unit to match the impedance; the control unit charges the power receiving device with power determining the charging load state of the power receiving device according to the lapse of time and the current level detected by the current detection unit; The method may include controlling charging power according to the wireless power signal to be charged to the power receiving device.

The step of determining, by the control unit, the charging load state of the power receiving device according to the lapse of time for charging the power receiving device and the current level detected by the current detecting unit, may include: The method may include determining that the charging load state of the power receiving device is an initial light load state, and determining the heavy load state when a preset initial charging time elapses.

Controlling, by the control unit, to selectively turn on the low-heat transformer and the high-heat transformer according to the determined charging load state to charge the charging power according to the wireless power signal to the power receiving device, the initial light load state It may include the step of controlling the low heat generating transformer to turn off and the high heat generating transformer to turn on, and controlling the low heat generating transformer to turn on and the high heat generating transformer to turn off when it is determined that the heavy load is turned off. have.

The step of controlling to turn on the low heating transformer and turn off the high heating transformer when it is determined as the heavy load includes controlling both the low heating transformer and the high heating transformer to be turned on for a predetermined period of time; , when the predetermined time elapses, controlling the low heat generating transformer to turn on and the high heat generating transformer to turn off.

The step of determining, by the control unit, the charging load state of the power receiving device according to the lapse of time for charging the power receiving device and the current level detected by the current detecting unit, may include setting the detected current level of the current detecting unit to a preset first level. Determining a light load state when entering the range of , and determining that the charging of the power receiving device is complete when the detected current level of the current detection unit is lower than the first level and below a preset second level. can do.

When the detected current level of the current detection unit enters the range of the preset first level, the determining of the light load state includes, by the control unit, the low-heat transforming unit is turned off and the high-heating transformer is turned on. may include steps.

The controlling, by the controller, to turn off the low-heat transformer and turn on the high-heat transformer, includes, by the controller, controlling both the low-heat transformer and the high-heat transformer to be turned on for a predetermined time. and controlling, by the control unit, to turn off the low heat generating transformer and keep the high heat generating transformer turned on when the predetermined time elapses.

The determining of the completion of charging of the power receiving device when the detected current level of the current detection unit is lower than the first level and below a preset second level, the control unit turning both the low-heat transformer and the high-heat transformer It may include the step of controlling to be turned off.

The low-heat wireless power receiver and method of the present invention include a low-heat transformer and a high-heat transformer, and determine the power charging load state of the power receiving device according to the elapsed charging time and current source of the power receiving device, and the determined power charging load According to the state, the low heat generating transformer and the high heat generating transformer are selectively turned off to supply charging power to the power receiving device.

Therefore, it is possible to charge the power receiving device by supplying sufficient power while minimizing heat generation, and also to reduce power consumption due to low heat generation.

Hereinafter, the present invention will be described in more detail by way of example which does not limit the present invention with reference to the accompanying drawings, and the same reference numerals are given to the same elements in some drawings.
1 is a block diagram showing the configuration of an embodiment of a low-heat wireless power receiver of the present invention;
2a and 2b are signal flow diagrams showing the operation of the control unit according to the low-heat wireless power receiving method of the present invention;
3 is a diagram for explaining the output voltage of the impedance matching/rectifying unit according to the present invention and the charging current of the power receiving device as an example, and
4 is a graph for explaining the operating state by taking the output voltage of the impedance matching/rectifying unit and the charging current of the power receiving device according to the present invention as an example.

Hereinafter, an apparatus and method for receiving low heat wireless power related to the present invention will be described in more detail with reference to the drawings.

The suffixes "module" and "part" for components used in the following description are given or mixed in consideration of only the ease of writing the specification, and do not have distinct meanings or roles by themselves.

1 is a block diagram showing the configuration of an embodiment of a low-heat wireless power receiver of the present invention. Referring to FIG. 1 , the apparatus for receiving low heat wireless power according to the present invention includes a power receiving coil 110 , an impedance matching/rectifying unit 120 , a charging power supply unit 130 , a current detecting unit 140 , and a power receiving device. (150; for example, a battery cell, etc.) and a control unit 160 may be included.

The power receiving coil 110 is, for example, coupled to a power transmitting coil of a wireless power transmitting device by an electromagnetic induction method or a magnetic resonance method to receive a wireless power signal transmitted by the power transmitting coil.

The impedance matching/rectifying unit 120 matches the impedance so that the power receiving coil 110 resonates with the wireless power signal, rectifies the wireless power signal received by the power receiving coil 110 and converts it into DC power.

The charging power supply unit 130 outputs the DC power output from the impedance matching/rectifying unit 120 as charging power to be charged in the power receiving device 150 , and a low-heat transformer 132 and a high-heat transformer 134 . may include.

The low-heat transformer 132 uses, for example, a switching device such as a Field Effect Transistor (FET). When the switching device is turned on, the DC power output from the impedance matching/rectifying unit 120 is passed. to output as charging power, and block the DC power output by the impedance matching/rectifying unit 120 when the switching element is turned off. The low-heat transformer 132 does not convert the level of the DC power output by the impedance matching/rectifying unit 120, but only performs a function of switching and passing or blocking, and thus provides stable DC power to the power receiving device 150. Although it cannot supply power, almost no heat is generated because it does not perform functions such as lowering the voltage level of DC power.

The high-heat transformer 134 uses, for example, an LDO (Low Drop Output), and when the LDO is turned on, the voltage level of the DC power output by the impedance matching/rectifying unit 120 is transmitted to the power receiving device ( 150) down to the required voltage level, and when the LDO is turned off, the impedance matching/rectifying unit 120 cuts off the DC power output. Since the high voltage transformer 134 outputs DC power of the voltage level required by the power receiving device 150, it is possible to supply stable DC power to the power receiving device 150, but a lot of heat is generated in the process of lowering the voltage level. Occurs.

The current detection unit 140 detects a current of charging power output from the low-heat transformer 132 or the high-heat transformer 134 of the charging power supply unit 130 to be charged in the power receiving device 150 .

The control unit 160 controls the impedance of the impedance matching/rectifying unit 120 so that the power receiving coil 110 can optimally receive the wireless power signal, and the power charging time of the power receiving device 150 and The power charging load state of the power receiving device 150 is determined according to the detected current of the current detector 140, and the low heat generating transformer 132 and the high heat generating transformer 134 are selectively selected according to the determined load state. It controls charging of power to the power receiving device 150 while turning on and off.

2A and 2B are signal flow diagrams showing the operation of the control unit according to the method for receiving low heat wireless power according to the present invention. Referring to FIG. 2A , the control unit 160 determines whether a wireless power signal is received by the impedance matching/rectifying unit 120 ( S200 ). That is, the power receiving coil 110 receives the wireless power signal transmitted when the wireless power transmitter transmits the wireless power signal, and the received wireless power signal is input to the impedance matching/rectifying unit 120, and the control unit ( 160 monitors the impedance matching/rectification unit 120 to determine whether a wireless power signal is received.

When the wireless power signal is received as a result of the determination, the controller 160 controls the impedance matching/rectifying unit 120 to match the impedance (S202).

Here, there are various methods of matching the impedance of the impedance matching/rectifying unit 120 .

For example, the control unit 160 performs communication with a wireless power transmitter through a communication unit (not shown in the drawing) to receive and receive a setting value to match the impedance of the impedance matching/rectifying unit 120 . The impedance may be matched by controlling the impedance matching/rectifying unit 120 according to a set value.

Alternatively, as the setting value has a predetermined range, the control unit 160 detects and detects the strength of the received wireless power signal while varying the impedance of the impedance matching/rectifying unit 120 according to the range of the setting value. The impedance may be matched by controlling the impedance matching/rectifying unit 120 to a value at which the strength of the wireless power signal is greatest.

Alternatively, the control unit 160 detects the intensity of the input wireless power signal while varying the impedance of the impedance matching/rectifying unit 120, and sets the intensity of the detected wireless power signal to a value at which the impedance matching/rectifying unit ( 120) to match the impedance.

In addition to the above methods, various methods may be used to match the impedance of the impedance matching/rectifying unit 120 .

In this state, the impedance matching/rectifying unit 120 rectifies the wireless power signal input from the power receiving coil 100 and converts it into DC power, and converts the converted DC power into a low-heat transformer of the charging power supply unit 130 . It is output to the unit 132 and the high-heat transformer 134 .

At this time, the control unit 160 does not charge power to the power receiving device 150 so that both the low heat generating transformer 132 and the high heat generating transformer 134 of the charging power supply unit 130 are turned off. .

Then, the voltage level of the power output from the impedance matching/rectifying unit 120 is, for example, about 7 to 10.5 V as shown in FIGS. 3 and 4 , and there is no detection current of the current detecting unit 140 . is the state

In such a state, the control unit 160 determines that the charging load of the power receiving device 150 is in the initial light load state at the initial stage of charging the power receiving device 150 , and the low heat generating transformer of the charging power supply unit 130 . 132 is turned off, and the high-heat transformer 134 is turned on (S204).

Then, the high-heat transformer 134 converts the voltage level of the DC power output from the impedance matching/rectification unit 120 to DC/DC and outputs it, and the DC power output from the high-heat transformer 134 is a current detection unit It is input to the power receiving device 150 through 140 and charged.

Here, the high-heat transformer 134 reduces the voltage level of the DC power output by the impedance matching/rectifying unit 120 to the voltage level required by the power receiving device 150 and outputs it down to the voltage level required by the power receiving device as described above. A stable DC power is supplied to 150, but the high heat transformer 134 converts the voltage level of the DC power to DC/DC, so that a lot of heat is generated.

And as the high-heat transformer 134 outputs DC power and is charged in the power receiving device 150 , the voltage level of the DC power output by the impedance matching/rectifying unit 120 is, for example, in FIGS. 3 and 4 . As shown in Fig., it is lowered to about 5.45 ~ 5.6V, and the current detection unit 140 is different depending on the power charging state of the power receiving device 150, but when the power charging state is low, for example, 200 ~ A current of 1000 mA is detected.

Here, the reason that the control unit 160 charges the power receiving device 150 by turning on the high-heat transformer 134 in the initial light load state is to provide a stable DC power to the power receiving device 150 . for charging.

In such a state, the control unit 160 determines whether the charging set time in the initial light load state has elapsed (S206).

As a result of the determination, if the charging set time has not elapsed, the control unit 160 inputs the detection current of the current detection unit 140 to determine the current level of the power charged in the power receiving device 150 (S208), and the determined It is determined whether the charging load of the power receiving device 150 is a light load state or a charging completion state based on the current level (S210, S212).

That is, when power charging is started in a state in which power is charged in the power receiving device 150, the current level of the power charged in the power receiving device 150 is lowered according to the amount of charged power, and the control unit 160 For example, when the current level of the power charged in the power receiving device 150 is about 200 to 500 mA, it is determined that the charging load of the power receiving device 150 is a light load, and when it is 80 mA or less, the power receiving device It is determined that the charging of 150 is completed.

As a result of the determination of the step (S208), when the charging load of the power receiving device 150 is not a light load state or a charging completion state, the control unit 160 returns to the step (S204) and the charging power supply unit 130 of the The low-heat transformer 132 continues to turn off, and the high-heat transformer 134 continues to turn on to charge power to the power receiving device 150, and the operation of determining whether a charging set time has elapsed is repeated. carry out

When the charging set time has elapsed in this state, the power receiving device 150 is charged with stable initial power, and the control unit 160 determines that the charging load of the power receiving device 150 is a heavy load.

When it is determined that the charging load of the power receiving device 150 is in a heavy load state, the control unit 160 turns on both the low heat generating transformer 132 and the high heat generating transformer 134 to turn on the impedance matching/rectifying unit. The DC power output from 120 passes through the low-heat transformer 132 or the high-heat transformer 134, and is charged in the power receiving device 150 through the current detection unit 140 (S214), and the A state in which both the heating transformer 132 and the high heating transformer 134 are turned on is maintained for a set time (S216).

Here, the reason why the control unit 160 maintains the state in which both the low heat generating transformer 132 and the high heat generating transformer 134 are turned on for a set time is that the low heat generating transformer 132 is charged with power This is so that the high-heat transformer 134 continues to supply charging power until it outputs .

The control unit 160, after maintaining the state in which both the low heat generation transformer 132 and the high heat generation transformer 134 are turned on for a set time, the low heat generation transformer 132 continues to turn on and turn off the high-heat transformer 134 (S218).

As the control unit 160 continues to turn on the low heat generating transformer 132 , power is continuously charged to the power receiving device 150 , and heat generated by the charging of power can be minimized.

At this time, the voltage level of the DC power output by the impedance matching/rectifying unit 120 is lowered to about 5.15 to 5.3 V, for example, as shown in FIGS. 3 and 4, and the current detecting unit 140 Although it is different depending on the power charging state of the power receiving device 150, a current of 350 to 1000 mA is detected.

In this state, the control unit 160 determines the current level of the DC power charged in the power receiving device 150 by inputting the detected current of the current detecting unit 140 (S220), and sets the current level to the determined current level. It is determined whether the charging load of (150) is in the light load state (S222). That is, the control unit 160 determines whether the current level of the DC power charged in the power receiving device 150 is, for example, about 200 to 500 mA, and when it is about 200 to 500 mA, the power receiving device ( 150) is determined to be a light load state.

The control unit 160 turns on both the low-heat transformer 132 and the high-heat transformer 134 when the light load state is determined in the step S210 or S222 (S224). ), a state in which both the low heat generating transformer 132 and the high heat generating transformer 134 are turned on is maintained for a set time (S226).

Here, the reason that the control unit 160 maintains the state in which both the low heat generating transformer 132 and the high heat generating transformer 134 are turned on for a set time is that the high heat generating transformer 134 starts to output stable power. This is to allow the low-heat transformer 132 to continuously output charging power until the

The control unit 160, after maintaining a state in which both the low heat generating transformer 132 and the high heat generating transformer 134 are turned on for a set time, the low heat generating transformer 132 is turned off and , the high-heat transformer 134 maintains a turned-on state so that the high-heat transformer 134 supplies charging power to the power receiving device 150 (S228).

At this time, as the high-heat transformer 134 supplies charging power to the power receiving device 150 , the voltage level of the DC power output by the impedance matching/rectifying unit 120 is shown in FIGS. 3 and 4 . As shown, for example, it rises to about 5.45~6.0V, and as the charging time elapses, for example, it rises to about 7.0~7.2V, and the current detection unit 140 sets the power charging state of the power receiving device 150 . Although it is different depending on the , a current of about 200 to 500 mA is detected.

In this state, the control unit 160 determines the current level of the power charged in the power receiving device 150 by inputting the detected current of the current detecting unit 140 (S230), and using the determined current level, the power receiving device ( 150), it is determined whether the power is fully charged (S232). That is, as shown in FIGS. 3 and 4 , when the power receiving device 150 is fully charged, the voltage level of the DC power output by the impedance matching/rectifying unit 120 is, for example, about 7.2 to 7.4. V, and the detection current of the current detection unit 140 is, for example, about 80 mA or less.

The control unit 160 determines that the power receiving device 150 is fully charged when the detected current of the current detection unit 140 is about 80 mA or less, and the low-heat transformer 132 and the high-heat All of the transformers 134 are turned off (S234), and the charging operation is terminated.

The apparatus and method for receiving low heat wireless power described above are not limited to the configuration and method of the above-described embodiments, but all or part of each embodiment may be modified so that various modifications of the embodiments may be made. They may be selectively combined and configured.

110: power receiving coil 120: impedance matching / rectifying unit
130: charging power supply 132: low heat transformer
134: high heat transformer 140: current detection unit
150: power receiving device 160: control unit

Claims (17)

A wireless power receiver comprising:
a power receiving coil configured to receive wireless power;
a rectifier configured to convert the wireless power into source power;
A first power transformer coupled to the rectifying unit, wherein the first power transformer includes a first type of voltage regulator configured to convert the source power into first charging power when the first power transformer is turned on to, the first power transformer;
A second power transformer coupled to the rectifying unit, wherein the second power transformer includes a second type of voltage regulator configured to convert the source power into second charging power when the second power transformer is turned on to, the second power transformer;
a current detection unit configured to detect a current level of at least one of the first charging power and the second charging power provided to a power receiving device; and
control unit - the control unit comprises:
determine a charging load state and an amount of power stored in the power receiving device based on the current level; and
the first power transformer and the power receiving device to respectively provide at least one of the first charging power and the second charging power to the power receiving device based at least in part on the charging load state and the amount of power stored in the power receiving device and configured to selectively turn on at least one of the second power transformers. The method of claim 1,
wherein the first type of voltage regulator includes a field effect transistor (FET) voltage regulator and the second type of voltage regulator includes a low drop output (LDO) voltage regulator. The method of claim 1,
The control unit is further configured to determine the charging load state and the amount of power stored in the power receiving device, the wireless power receiving device. The method of claim 1,
The first power transformer and the second power transformer are connected in parallel to each other between the rectifying unit and the power receiving device. The method of claim 1,
The first power transformer includes a low-heat transformer, and the second power transformer includes a high-heat transformer. The method of claim 1,
The first power transformer has a power loss lower than the power loss of the second power transformer, and the second power transformer provides a charging power greater than the charging power of the first power transformer, the wireless power receiver. The method of claim 1,
The rectifying unit includes an impedance matching/rectifying unit configured to match an impedance so that the power receiving coil can resonate with the wireless power, and the control unit is further configured to control the impedance. The method of claim 1,
The control unit is:
determining an initial light load state of the power receiving device when the power receiving device starts charging;
Turning off the first power transformer and turning on the second power transformer during the initial light load state,
determining a heavy load state of the power receiving device after a predetermined initial charging time, and
and to turn on the first power transformer and turn off the second power transformer during the heavy load state. 9. The method of claim 8,
The control unit is configured to turn on the first power transformer and turn off the second power transformer during the heavy load state, wherein the control unit includes:
Turn on both the first power transformer and the second power transformer for a predetermined time in response to determining the heavy load state, and
When the predetermined time has elapsed, the wireless power receiver comprising: maintaining the first power transformer turned on and configured to turn off the second power transformer. The method of claim 1,
The control unit is:
determine a subsequent light load state when the power receiving device reaches a first level lower than the charging complete state; and
The wireless power receiver is configured to turn off the first power transformer and turn on the second power transformer. 11. The method of claim 10,
The control unit is configured to turn off the first power transformer and turn on the second power transformer, wherein the control unit includes:
turning on both the first power transformer and the second power transformer for a predetermined time in response to determining the subsequent light load state, and
Including being configured to keep the second power transformer turned on and turn off the first power transformer when the predetermined time has elapsed. The method of claim 1,
The control unit is:
determining that the power receiving device has been charged; and
The wireless power receiver is configured to turn off both the first power transformer and the second power transformer. A method performed by a wireless power receiving device, comprising:
receiving wireless power using a power receiving coil;
converting the wireless power into source power;
converting the source power into at least one of first charging power and second charging power;
detecting a current level of at least one of the first charging power and the second charging power provided to a power receiving device of the wireless power receiving device;
determining a charging load state and an amount of power stored in the power receiving device based on the current level; and
and selectively turning on at least one of a first power transformer and a second power transformer based at least in part on the charging load state and the amount of power stored in the power receiving device,
The first power transformer includes a first type of voltage regulator configured to convert the source power into the first charging power when the first power transformer is turned on,
The method performed by the wireless power receiver, wherein the second power transformer includes a second type of voltage regulator configured to convert the source power into the second charging power when the second power transformer is turned on. 14. The method of claim 13,
The method performed by the wireless power receiver further comprising matching an impedance of a rectifier of the wireless power receiver so that the power receiver coil can resonate with the wireless power. 14. The method of claim 13,
determining an initial light load state of the power receiving device when the power receiving device starts being charged;
turning off the first power transformer and turning on the second power transformer during the initial light load state;
determining a heavy load state of the power receiving device after a predetermined initial charging time; and
Further comprising the step of turning on the first power transformer and turning off the second power transformer during the heavy load state, the method performed by the wireless power receiver. 14. The method of claim 13,
determining a subsequent light load state when the power receiving device reaches a first level lower than a charging completion state; and
The method performed by the wireless power receiving apparatus further comprising the step of turning off the first power transformer and turning on the second power transformer. 14. The method of claim 13,
determining that the power receiving device has been charged; and
The method performed by the wireless power receiver further comprising the step of turning off both the first power transformer and the second power transformer.

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