KR102665363B1 - Hybrid type wireles power receiving device, method of controlling wireless power signal in hybrid type wireles power receiving device, and magnetic resonance type wireless power receiving device related to the same - Google Patents

Abstract

The present invention includes a transmission coil that receives an inductive power signal; an antenna installed around the transmitting coil to receive a resonance power signal; a rectifier that rectifies alternating current power generated by the inductive power signal and the resonance power signal to generate rectified power; A converter that converts the rectified power; a voltage stabilization circuit installed between the rectifier and the converter; and when the resonance power signal and the induced power signal are initially received, supply the rectified power to the voltage stabilization circuit, and determine that the rectified power rectified by the resonance power signal and the induced power signal is within a reference range. The present invention relates to a hybrid wireless power receiving device including a reception control unit that supplies the rectified power to the converter, a wireless power signal control method in the hybrid wireless power receiving device, and a magnetic resonance wireless power receiving device related thereto. .

Description

Hybrid type wireless power receiving device, method of controlling wireless power signal in the hybrid type wireless power receiving device, and magnetic resonance type wireless power receiving device related thereto DEVICE, AND MAGNETIC RESONANCE TYPE WIRELESS POWER RECEIVING DEVICE RELATED TO THE SAME}

The present invention relates to a hybrid type wireless power reception device, a wireless power signal control method in the hybrid type wireless power reception device, and a magnetic resonance type wireless power reception device related thereto.

With the development of wireless communication technology, it is becoming a ubiquitous information environment where anyone can exchange any information they want anytime, anywhere. However, most communication information devices still rely on batteries and are powered by a wired power cord, which limits the use of communication information devices.

Therefore, the wireless information network environment cannot be truly free without solving the problem of terminal power.

To solve these problems, many methods are being developed to transmit power wirelessly, such as a radio wave reception method using radio waves, a magnetic induction method using a magnetic field, or a magnetic resonance method using energy conversion between magnetic and electric fields, etc. This is a representative example.

Here, the radio wave reception type has the advantage of being able to transmit power over a long distance by radiating radio waves into the air through an antenna, but the radiation loss consumed in the air is very large, so there is a limit to the efficiency of power transmission.

In addition, the magnetic induction method uses a transmission coil as a transmitter and a secondary coil as a receiver, and has the advantage of high power transmission efficiency as a technology that uses magnetic energy combination by the primary and secondary coils. For this, the primary and secondary coils must be adjacent to each other at a short distance of several millimeters, and there is a disadvantage that the efficiency of power transmission changes drastically depending on the alignment of the primary and secondary coils.

Therefore, a magnetic resonance method has recently been developed, which is similar to the magnetic induction method but transmits power in the form of magnetic energy by concentrating energy at a specific resonance frequency using a coil-type inductor (L) and a capacitor (C). This magnetic resonance method has the advantage of being able to transmit relatively large energy up to several meters, but requires high resonance characteristics (high quality factor). In other words, the magnetic resonance method has the disadvantage that its efficiency changes drastically depending on whether impedance is matched and whether the resonance frequency is matched.

Accordingly, a wireless power transmission system that combines the advantages of the magnetic induction method and the magnetic resonance method is being proposed.

The present invention is a hybrid wireless power system that improves compatibility of wireless power communication by receiving both resonance power signals and induced power signals, and prevents defects due to unstable power supply that may occur at the beginning of wireless power signal input. The object is to provide a receiving device, a wireless power signal control method in a hybrid type wireless power receiving device, and a magnetic resonance type wireless power receiving device related thereto.

A hybrid wireless power transmission device, which is an embodiment of the present invention devised to solve the above-described problems, includes a transmission coil for receiving an inductive power signal; an antenna installed around the transmitting coil to receive a resonance power signal; a rectifier that rectifies alternating current power generated by the inductive power signal and the resonance power signal to generate rectified power; A converter that converts the rectified power; a voltage stabilization circuit installed between the rectifier and the converter; and when the resonance power signal and the induced power signal are initially received, supply the rectified power to the voltage stabilization circuit, and determine that the rectified power rectified by the resonance power signal and the induced power signal is within a reference range. When this happens, it may include a reception control unit that turns off the voltage stabilization circuit and then supplies the rectified power to the converter.

According to one aspect of an embodiment of the present invention, the hybrid type wireless power transmission device further includes a variable capacitor connected to the antenna, and the reception control unit recognizes the magnetic resonance type wireless power transmission device through the antenna. , the variable capacitor can be adjusted to receive the first resonance power signal at a reception frequency spaced apart from the resonance frequency.

According to one aspect of an embodiment of the present invention, the reception control unit, after a reference time has elapsed after receiving the first resonance power signal, readjusts the variable capacitor to control the reception of the resonance power reception signal at a resonance frequency. You can.

According to one aspect of an embodiment of the present invention, the hybrid type wireless power receiving device may further include a short-distance communication module for transmitting charging state information generated by the resonance power signal.

According to one aspect of an embodiment of the present invention, the hybrid type wireless power reception device further includes a voltage sensor disposed between the rectifier and the converter, and the reception control unit uses the voltage measured from the voltage sensor as a reference. If it is within the range, the rectified power can be controlled to turn off the voltage stabilization circuit and supply the rectified power to the converter.

According to one aspect of an embodiment of the present invention, the rectifier includes: a resonance rectifier that rectifies power generated by the resonance power signal; an inductive rectifier that rectifies power generated by the inductive power signal; And it may include a switching unit for selecting one of the resonance rectifier and the inductive rectifier.

Another embodiment of the present invention, a method of controlling a wireless power signal in a hybrid wireless power receiving device, includes initially receiving one of a resonance power signal from a magnetic resonance transmission device and a wireless power signal from an inductive transmission device, and a rectifier unit Turning on the voltage stabilization circuit located at the rear end; And when the rectified power rectified by the resonance power signal and the induced power signal is determined to be within a reference range, turning off the stabilization circuit and then supplying the rectified power to the converter.

According to one aspect of another embodiment of the present invention, the resonance power signal may be received through a loop antenna, and the induced power signal may be received through a receiving coil surrounded by the loop antenna.

According to one aspect of another embodiment of the present invention, upon initially receiving one of the resonance power signal from the magnetic resonance transmission device and the wireless power signal from the inductive transmission device, turning on the voltage stabilization circuit located at the rear of the rectifier. may include the step of receiving the first resonance power signal at a receiving frequency spaced apart from the resonance frequency by adjusting a variable capacitor connected to the antenna when first receiving the resonance power signal.

According to one aspect of another embodiment of the present invention, the wireless power signal control method in the hybrid type wireless power receiving device includes readjusting the variable condenser after a reference time has elapsed after receiving the first resonance power signal to achieve resonance. It may further include receiving the resonance power reception signal at a frequency.

A magnetic resonance wireless power reception device according to another embodiment of the present invention includes a receiving antenna for receiving a resonance power signal; A variable condenser connected to the antenna; a rectifier that rectifies alternating current power generated by the resonance power signal to generate rectified power; A converter that converts the rectified power; When the magnetic resonance type wireless power transmission device is recognized through the antenna, it may include a resonance reception control unit that controls the variable capacitor to receive the first resonance power signal at a reception frequency spaced apart from the resonance frequency.

According to one aspect of another embodiment of the present invention, the resonance reception control unit readjusts the variable condenser after a reference time has elapsed after receiving the first resonance power signal to receive the resonance power reception signal at the resonance frequency. You can control it.

According to an embodiment of the present invention having the above-described configuration, device compatibility is increased because both the inductive power signal and the resonance power signal can be received and charged regardless of the type of transmission device.

In addition, according to one embodiment of the present invention, it is possible to contribute to improving the durability of the product by preventing sudden pressure increases outside the standard range that may occur at the beginning of charging.

1 is a block diagram illustrating the operation of a wireless power transmission system including a hybrid wireless power reception device according to an embodiment of the present invention.
Figure 2 is a block diagram for explaining the electronic configuration of a hybrid wireless power reception device according to an embodiment of the present invention.
Figure 3 is a block diagram illustrating the electronic configuration of a rectifier in a hybrid wireless power reception device according to an embodiment of the present invention.
Figure 4 is a block diagram illustrating the electronic configuration of a magnetic resonance wireless power receiving device according to another embodiment of the present invention.
Figure 5 is a flowchart illustrating a wireless power transmission control method according to a hybrid type wireless power reception device, which is an embodiment of the present invention.

Hereinafter, the present invention's high-hybrid wireless power receiving device, the wireless power signal control method in the hybrid wireless power receiving device, and the magnetic resonance type wireless power receiving device related thereto will be described in more detail with reference to the drawings.

1 is a block diagram for explaining the operation of a wireless power transmission system including a hybrid wireless power reception device according to an embodiment of the present invention. As shown in FIG. 1, the wireless power system according to the present invention may be composed of a wireless power transmission device 100 and a wireless power reception device 200.

The hybrid wireless power reception device 200 according to the present invention can receive both power signals (inductive power signal and resonance power signal) from the inductive wireless power transmission device 100 and the resonance type power transmission device 10. You can.

In more detail, the inductive power signal from the inductive power transmission device 20 is received through the receiving coil 211 of the receiving block 210 (see FIG. 2), and the resonance type power transmission device ( The resonance power signal from 10) is received through the loop antenna 213 located around the receiving coil 211.

Accordingly, the hybrid wireless power reception device 200 according to the present invention can receive both the induced power signal and the resonance power signal, and can supply power to the load 280 using these power signals.

Hereinafter, the configuration of the hybrid type wireless power receiving device will be described in more detail with reference to FIG. 2.

FIG. 2 is a block diagram for explaining the electronic configuration of a hybrid type wireless power reception device according to an embodiment of the present invention. As shown in FIG. 2, the hybrid wireless power reception device 200 according to the present invention includes a reception block 210, a rectifier 220, a voltage stabilization circuit 230, a converter 240, and a voltage sensor 250. ), a short-range communication module 260, a reception control unit 270, and a load 280.

The receiving block 210 is a component for receiving a wireless power signal, and as shown in FIG. 2, it includes a receiving coil 211, an antenna 213, and a variable condenser 215 connected to the antenna 213. can do.

The receiving coil 211 is used to receive the induced power signal when the wireless power transmission device 200 oscillates the induced power signal. This receiving coil 211 functions to generate alternating current power by electromagnetic induction from power signals in the low-frequency range of usually 100 to 205 KHz.

The antenna 213 is used to receive the resonance power signal when the wireless power transmission device 100 oscillates the resonance power signal. This antenna 213 functions to generate alternating current power using a power signal in a high frequency range of typically 6.78 MHz ± 5% through resonance.

The variable condenser 215 serves to separate the resonance frequency of the antenna 213 when the resonance type wireless power transmission device 10 is recognized through the antenna 213. That is, the reception control unit 270 can adjust the variable capacitor 215 to receive a resonance power signal at a reception frequency spaced apart from the resonance frequency.

The rectifier 220 functions to rectify the alternating current power received in the receiving block 210 into direct current power. That is, it functions to generate rectified power by rectifying the AC power in the receiving coil 211 generated from the inductive power signal or the AC power in the antenna 213 generated by the resonance power signal. The structure of this rectifier 220 will be described in more detail in FIG. 3.

The voltage stabilization circuit 230 is located between the rectifier 220 and the converter 240, and has the function of stabilizing the voltage of the power flowing into the converter 240 by applying a virtual load when receiving the initial wireless power signal. Perform.

The voltage sensor 250 is located between the rectifier 220 and the converter 240 and functions to measure the voltage of the rectified power generated by the wireless power signal. That is, the reception control unit 270 can check whether the power currently flowing into the converter 240 is within a normal range through the voltage of the rectified power received through the voltage sensor 250.

The converter 240 functions to convert the rectified power into power required by the load 280.

When the wireless power transmission device 100 is a resonance type, the short-range communication module 260 receives a resonance power signal and supplies power to the load 280 accordingly. At this time, the power of the load 280 It functions to transmit charging status information of the load 280 in order to smooth supply. In the case of the inductive method, the charging state information of the load 280 is transmitted through ASK communication through the receiving coil 211.

When the resonance power signal and the induced power signal are initially received, the reception control unit 270 supplies the rectified power to the voltage stabilization circuit 230, and supplies the rectified power to the voltage stabilization circuit 230 by the resonance power signal and the induced power signal. If the rectified power is determined to be within the standard range, the voltage stabilization circuit 230 is turned off and the rectified power is supplied to the converter 240. In addition, the reception control unit 270 functions to control the variable condenser 215 to receive the resonance power reception signal at the resonance frequency after a reference time has elapsed after receiving the first resonance power signal.

In addition, the reception control unit 270 receives the voltage information signal measured from the voltage sensor 250, and can normally supply power to the load 280 when the measured voltage value of this voltage information signal is within the reference range. This functions to turn off the voltage stabilization circuit 230 and supply the rectified power to the converter 240. The operation of the reception control unit 270 and the overall power reception operation of the hybrid wireless power reception device 200 will be described in more detail with reference to FIG. 5.

Hereinafter, the specific configuration of the rectifier 220 of the hybrid wireless power reception device 200 will be described in more detail with reference to FIG. 3.

Figure 3 is a block diagram for explaining the electronic configuration of a rectifier in a hybrid wireless power transmission device according to an embodiment of the present invention.

As described above, the rectifier 220 functions to rectify the alternating current power generated in the receiving block 210 and convert it into direct current power. Such a rectifier 220 is a resonance rectifier 221 that rectifies the power generated by the resonance power signal from the resonance power transmission device 10 and the induction power signal from the induction power transmission device 20. It may include an inductive rectifier 223 that rectifies the power generated by the power, and a switching unit 225 for selecting one of the resonance rectifier 221 and the inductive rectifier 223.

That is, when the reception control unit 270 confirms the type of the wireless power transmission device 100 that oscillates a wireless power signal, it controls the switching unit 225 to select one of the rectifiers corresponding to the type to perform rectification. . In this way, rectification using a two-channel method not only improves rectification efficiency, but also improves power transmission efficiency by preventing current leakage into the receiving block 210 on the side that does not receive the wireless power signal.

Hereinafter, an example in which the function of the hybrid wireless power receiving device, which is an embodiment of the present invention, is applied to a magnetic resonance type will be described in more detail with reference to FIG. 4.

Figure 4 is a block diagram for explaining the electronic configuration of a magnetic resonance type wireless power receiving device, which is another embodiment of the present invention. As shown in FIG. 4, the magnetic resonance wireless power reception device 300 includes a reception block 310 including an antenna 313 and a variable condenser 315, a rectifier 320, a voltage stabilization circuit 330, It may include a converter 340, a voltage sensor 350, a short-range communication module 360, a resonance reception control unit 370, and a load 380.

Here, the rectifier 320, voltage stabilization circuit 330, converter 340, voltage sensor 350, short-range communication module 360, and load 380 have the same function as the components of the same name in FIG. 3. , the explanation regarding this will be omitted.

Unlike the receiving block 210 in FIG. 3, the receiving block 310 of the magnetic resonance wireless power receiving device 300 shown in FIG. 4 consists only of an antenna 313 and a variable condenser 315. When the resonance reception control unit 370 recognizes a magnetic resonance wireless power transmission device through the antenna 313, it adjusts the variable condenser 315 to receive the first resonance power signal at a receiving frequency spaced apart from the resonance frequency. Take control. That is, when the power is first received, the resonance power signal is received through the separated reception frequency rather than the resonance frequency, thereby preventing the generation of surge voltage. In addition, the resonance reception control unit 370 controls the variable capacitor 315 to receive the resonance power signal at a resonance frequency after a reference time has elapsed after receiving the first resonance power signal, thereby controlling the surge voltage. After preventing this, optimal charging is possible.

Hereinafter, the wireless power signal control method in the hybrid type wireless power receiving device having the configuration described above in FIGS. 2 and 3 will be described in detail with reference to FIG. 5. It should be understood that the wireless power signal control method described in FIG. 5 can also be used in the magnetic resonance type wireless power receiving device in FIG. 4.

Figure 5 is a flowchart for explaining a wireless power transmission control method according to a hybrid type wireless power reception device, which is an embodiment of the present invention. As shown in FIG. 4, when the hybrid type wireless power receiving device 200 is located at the charging distance (resonant method) or charging position (inductive method), the wireless power transmitting device 100 detects the device by an object detection signal. It is confirmed that an external object is detected. At this time, when the wireless power transmission device 100 is an inductive type, it is possible to check whether the external object is the inductive power receiving device 20 using a pulse signal from the transmission coil. That is, when the external object is the inductive power transmission device 20, the wireless power reception device 200 transmits the ASK communication signal through the receiving coil 211, and accordingly, the wireless power transmission device 100 receives the ID The request signal is transmitted through the transmission coil.

If the wireless power transmission device 100 is a resonance type, it is possible to check whether the external object is the resonance type power receiving device 10 using the pulse signal from the antenna 213, and the external object is a resonance type power transmission device. When confirmed as the device 10, the wireless power transmission device 100 transmits an ID request signal to the wireless power reception device 200 through the short-range communication module 260 (S13).

Then, the wireless power receiving device 200 transmits the ID signal to the receiving coil 211 (in the case of the inductive method) or the short-range communication module 260 (in the case of the resonance method) (S21). Then, the wireless power transmission device 100 transmits a wireless power signal accordingly. That is, when the hybrid wireless power reception device 200 initially receives one of the resonance power signal from the resonance power transmission device 10 and the wireless power signal from the inductive power transmission device 20, the rectifier 220 ) Turn on the voltage stabilization circuit 230 located at the rear end. If the power signal is a resonance power signal, the variable capacitor 215 connected to the antenna 213 is adjusted to set a receiving frequency spaced apart from the resonance frequency to receive the first resonance power signal (S23).

Next, the reception control unit 270 checks the voltage of the rectified power between the rectifier 220 and the converter 240 through the voltage sensor 250 (S25). If it is determined that the checked rectified voltage is in the normal range, the voltage stabilization circuit 230 is turned off and the variable condenser 215 is readjusted to receive a resonance signal at the resonance frequency (S27). Meanwhile, in the case of the induction method, if the rectified power rectified by the inductive power signal is determined to be within the standard range, the stabilization circuit 230 is turned off and the rectified power is supplied to the converter 240. Alternatively, without checking the voltage of the rectified power before rectification, the reception control unit 270 readjusts the variable condenser 215 after a reference time has elapsed after receiving the first resonance power signal to receive the resonance power at the resonance frequency. A signal can be received.

In this way, the variable condenser 215 of the antenna 213 is readjusted to receive a resonance power signal through the antenna 213 having a resonance frequency, and the rectified power is applied to the load 280 for charging. Continue (S29). At this time, the reception control unit 270 of the wireless power reception device 200 generates charging state information of the load 280 and transmits it to the wireless power transmission device through the short-range communication module 260, and the wireless power transmission device ( 100) changes the frequency or intensity of the wireless power signal accordingly to change the wireless power signal to have optimal transmission efficiency and oscillate (S31, S17).

According to an embodiment of the present invention having the above-described configuration, device compatibility is increased because both the inductive power signal and the resonance power signal can be received and charged regardless of the type of transmission device.

In addition, according to one embodiment of the present invention, it is possible to contribute to improving the durability of the product by preventing a sudden voltage increase (surge voltage) outside the standard range that may occur at the beginning of charging.

The hybrid type wireless power receiving device described above, the wireless power signal control method in the hybrid wireless power receiving device, and the magnetic resonance type wireless power receiving device related thereto may be limited to the configuration and method of the embodiments described above. Rather, the above embodiments may be configured by selectively combining all or part of each embodiment so that various modifications can be made.

10: Magnetic resonance type power transmission device
20: Inductive power transmission device
100: wireless power transmission device
200: Hybrid wireless power receiving device
210: Receiving block
211: receiving coil
213: Antenna (loop antenna)
215: variable condenser
220: rectifier
230: Voltage stabilization circuit
240: converter
250: voltage sensor
260: Short-distance communication module
270: Reception control unit
280: load (battery)

Claims (6)

a receiving coil that receives the inductive power signal;
a receiving antenna installed around the receiving coil to receive a resonance power signal;
a rectifier that rectifies alternating current power generated by the induced power signal or the resonance power signal to generate rectified power;
A converter that converts the rectified power;
a voltage stabilization circuit installed between the rectifier and the converter;
a reception control unit configured to control supply of the rectified power to the voltage stabilization circuit when the resonance power signal or the induced power signal is initially received; and
It includes a voltage sensor disposed between the rectifier and the reception control unit,
The rectifier unit,
a resonance rectifier that rectifies power generated by the resonance power signal;
an inductive rectifier that rectifies power generated by the inductive power signal; and
A switching unit for selecting one of the resonance rectifier and the inductive rectifier,
The reception control unit is configured to control the reception antenna to receive an initial resonance power signal at a reception frequency spaced apart from the resonance frequency.
According to claim 1,
Further comprising a variable condenser connected to the receiving antenna,
The reception control unit,
When a magnetic resonance wireless power transmission device is recognized through the receiving antenna, the variable condenser is adjusted to receive the first resonance power signal at the reception frequency spaced from the resonance frequency,
The reception control unit,
A hybrid wireless power reception device that controls to receive the resonance power signal at the resonance frequency by readjusting the variable condenser when a reference time has elapsed after receiving the first resonance power signal.
According to claim 1,
A hybrid wireless power reception device further comprising a short-range communication module for transmitting charging state information generated by the resonance power signal.
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