KR20170017039A - Wireless power receiver capable of protection against external noise - Google Patents

Abstract

The present invention discloses a control device including: an AC input/output terminal; a first voltage supply unit including a first control unit for supplying a first voltage through the AC input/output terminal, and a first NMOS; a second voltage supply unit including a second control unit for supplying a second voltage through the AC input/output terminal, and a second NMOS; and a first protection unit having a first voltage sensing terminal and a first voltage following terminal. In order to allow the first NMOS to have an off state when an electric potential lower than a reference electric potential of the control device is applied to the AC input/output terminal from the outside, the first protection unit allows an electric potential of the first voltage following terminal to follow an electric potential of the first voltage sensing terminal.

Description

[0001] The present invention relates to a wireless charging device capable of blocking external noise,

The present invention relates to a wireless power receiving apparatus (wireless charging apparatus) capable of performing a wireless charging function, and more particularly to a wireless power receiving apparatus capable of protecting the wireless power receiving apparatus from the influence of external noise input through an AC input / Technology.

Smartphone wireless charging technology is beginning to be adopted in places such as cafes and vehicles, and many global IT user device manufacturers are offering these technologies competitively.

1 is a conceptual diagram showing a general 'dual mode wireless power receiving device' (right side) for wirelessly receiving power through a coil and a 'wireless power transmitting device' (left side) for wirelessly transmitting power . In the first mode, the wireless power receiving apparatus may provide power to the wireless power receiving apparatus, and in the second mode, the wireless power receiving apparatus may provide communication information to the wireless power transmitting apparatus. In the second mode, the wireless power receiving apparatus may function as a 'current driving apparatus'.

The above-described wireless power receiving apparatus is used together with other kinds of current driving apparatuses (driver ICs) used for implementing communication technologies such as MST (Magnetic Stripe Transmission) technology, and devices for power electronics such as DC motors and BLDC motors And may share the coil. In one embodiment, the coils may be coupled together to the wireless power receiver and the driver IC. That is, one coil can be shared by the wireless power receiving apparatus and the driver IC in a time division manner and used. For example, one coil may be connected to the wireless power receiving device, and at the same time may be connected to the driver IC. At this time, if any one of the wireless power receiving apparatus and the driver IC is activated, the other one may be inactivated. Here, being in the inactive state may mean a rest state in which the right to control the current to be supplied to the coil is left to another device and the coil does not operate according to the intended purpose. Even in this deactivation state, the device can maintain a state connected to the reference potential of the electronic system to which the device belongs.

Meanwhile, in the early stage of this technique, the position of the wireless power receiving apparatus and the wireless power transmitting apparatus are relatively fixed, and the 'magnetic induction technique' in which the wireless power receiving apparatus and the wireless power transmitting apparatus correspond to each other at a ratio of 1: 1 Respectively. This initial technology has evolved into a "self-resonant wireless charging technology" in which the positions of the wireless power receiving apparatus and the wireless power transmitting apparatus are relatively free, and the wireless power receiving apparatus and the wireless power transmitting apparatus correspond to N: 1 .

However, in the case of the self-resonant wireless charging technique described above, the power supplied from the wireless power transmission apparatus to the first wireless power reception apparatus may be a noise to the second wireless power reception apparatus. For example, when the second wireless power receiving apparatus operates in the second mode to generate the communication signal, the power signal provided to the first wireless power receiving apparatus may act as noise to the first wireless power receiving apparatus . Also, even in such a situation, a signal exceeding an allowable range may be provided to AC input / output terminals of a specific wireless power receiving apparatus due to mutual resonance of power signals provided to a plurality of wireless power receiving apparatuses, have. Or as another example, an externally input surge noise may be out of an allowable range at the AC input / output terminal of the wireless power receiving apparatus. If the size of the noise is very large, the wireless power receiving apparatus may be destroyed or malfunctioned.

In order to solve the above-described problems, the present invention provides a technique for protecting a wireless power receiving apparatus from noise applied from the outside.

According to one aspect of the present invention, there are provided an AC input / output terminal 41; (2) a first control unit 21; And a first NMOS (11) having a drain, a gate, and a source respectively connected to an operation power source, a control signal AC input / output terminal (output terminal) of the first control unit, and the AC input / output terminal, (100). The wireless power receiving apparatus further includes a first protection unit (1) having a first voltage sensing terminal (A) connected to the AC input / output terminal and a first voltage follower terminal (B) connected to the gate of the first NMOS . At this time, in order that the first NMOS is in an off state when a potential lower than the reference potential of the wireless power receiving apparatus is applied to the AC input / output terminal from the outside, the first protection unit detects the potential of the first voltage follow- So as to follow the potential of the first voltage sensing terminal.

In this case, the first protection unit may include an internal NMOS, an internal diode, and a voltage divider. And the drain, source, and gate of the internal NMOS may be connected to the first voltage follower terminal, the anode of the internal diode, and the distributed voltage output terminal of the voltage divider, respectively. The cathode of the internal diode is connected to the first voltage sensing terminal, and the first connection terminal and the second connection terminal of the voltage distributor may be connected to the anode and the reference potential, respectively. At this time, the first voltage follower terminal may be connected to the reference potential through a resistor.

Here, the wireless power receiving apparatus may include a second controller; A second NMOS having a source, a gate, and a drain respectively connected to a reference potential, a control signal output terminal of the second control unit, and the AC input / output terminal; And a second protection unit having a second voltage sensing terminal connected to the AC input / output terminal and a second voltage follower terminal connected to a gate of the second NMOS transistor. And the second protection unit is configured to prevent the potential of the second voltage follower terminal from exceeding the potential of the second voltage follower terminal when the potential of the second voltage follower terminal is higher than the reference potential of the wireless power receiving apparatus, 2 voltage sensing terminal.

According to another aspect of the present invention, there is provided an AC / (2) a first control unit; (3) a first NMOS having a drain and a gate connected to an operation power source and a control signal output terminal of the first control unit, respectively; And a third NMOS (13) having a drain, a gate, and a source connected to the AC input / output terminal, a control signal output terminal of the first control unit, and a source of the first NMOS, respectively . The wireless power receiving apparatus may further include a first protection unit having a first voltage sensing terminal connected to the AC input / output terminal and a first voltage follower terminal connected to a gate of the first NMOS and a gate of the third NMOS. In order to make the first NMOS to be in the OFF state when a potential lower than the reference potential of the wireless power receiving apparatus is applied from the outside to the AC input / output terminal, the first protection unit monitors the first voltage follow- And the potential of the terminal follows the potential of the first voltage sensing terminal.

At this time, in order to make the third NMOS have an off state when a potential higher than the reference potential of the wireless power receiving apparatus is applied to the AC input / output terminal from the AC input / output terminal, the gate of the third NMOS and the reference potential And a resistor connected between the first and second electrodes.

In this case, the first protection unit may include an internal NMOS, an internal diode, and a voltage divider. And the drain, source, and gate of the internal NMOS may be connected to the first voltage follower terminal, the anode of the internal diode, and the distributed voltage output terminal of the voltage divider, respectively. The cathode of the internal diode is connected to the first voltage sensing terminal, and the first connection terminal and the second connection terminal of the voltage distributor may be connected to the anode and the reference potential, respectively.

Here, the wireless power receiving apparatus may include a second controller; A second NMOS having a gate and a drain connected to the control signal output terminal of the second control unit and the AC input / output terminal, respectively; A fourth NMOS having a drain, a gate, and a source respectively connected to a reference potential, a control signal output terminal of the second control unit, and a source of the second NMOS; And a second protection unit having a second voltage sensing terminal connected to the AC input / output terminal and a second voltage follower terminal connected to a gate of the second NMOS transistor. In order to make the second NMOS to be in the OFF state when a potential lower than the reference potential of the wireless power receiving apparatus is applied from the outside to the AC input / output terminal, the second protection unit monitors the second voltage And the potential of the terminal may follow the potential of the second voltage sensing terminal.

According to another aspect of the present invention, a first AC input / output terminal 41; A first control unit 21; A first NMOS transistor having a drain, a gate, and a source connected to an operation power source, a control signal output terminal of the first control unit, and the first AC input / output terminal, respectively; A first protection unit (1) having a first voltage sensing terminal connected to the first AC input / output terminal and a first voltage follower terminal connected to a gate of the first NMOS; A second AC input / output terminal 42; A fourth control unit 24; A sixth NMOS (16) having a source, a gate, and a drain connected to a reference potential, a control signal output terminal of the fourth control unit, and the second AC input / output terminal; A fourth protection unit (4) having a fourth voltage sensing terminal connected to the second AC input / output terminal and a fourth voltage follower terminal connected to the gate of the sixth NMOS transistor; And an element (60) having an inductance component connected between the first AC input / output terminal and the second AC input / output terminal. In order to make the first NMOS have an off state when a potential lower than the reference potential of the wireless power receiving apparatus is applied to the first AC input / output terminal from the outside, the first protection unit detects that the potential of the first voltage follower terminal is And may follow the potential of the first voltage sensing terminal. The fourth protection unit is connected to the fourth voltage follower terminal so that the potential of the fourth voltage follower terminal is higher than the potential of the fourth voltage sense terminal when the potential is lower than the reference potential to the second AC input / As shown in FIG.

According to the present invention, it is possible to provide a technique for protecting a wireless power receiving apparatus from noise applied from the outside.

FIG. 1 is a conceptual diagram showing a general 'dual mode wireless power receiving device' for receiving power wirelessly through a coil and a 'wireless power transmitting device' for wirelessly transmitting power.
2 shows a circuit of a wireless power receiving apparatus according to an embodiment.
FIG. 3A is a graph illustrating an example of noise, FIG. 3B is a graph showing a voltage flow when a voltage corresponding to a first noise region is applied, FIG. 3C is a graph illustrating a voltage waveform when a voltage corresponding to a second noise region is applied Of FIG.
4 illustrates a protection circuit according to an embodiment of the present invention for protecting the wireless power receiving apparatus when a noise having a negative value is applied through an AC input / output terminal of the wireless power receiving apparatus .
5A shows the operation state of the protection circuit in Fig. 4 when the voltage corresponding to the potential of the operation power source VM is outputted via the first AC input / output terminal 41 of the wireless power receiving apparatus.
FIG. 5B shows the operation state of the protection circuit of FIG. 4 in the case of outputting a voltage corresponding to the reference potential GND through the first AC input / output terminal 41 of the wireless power receiving apparatus.
FIG. 5C shows an operation state of the protection circuit of FIG. 4 when a noise having a negative voltage is inputted through the first AC input / output terminal in a state in which the wireless power receiving apparatus is inactivated.
6 is a circuit diagram of a protection circuit 300 according to an embodiment of the present invention for protecting the wireless power receiving apparatus when noise having a positive voltage is applied through the AC input / ).
7A shows an operation state of the protection circuit in Fig. 6 when a voltage corresponding to the potential of the operation power source VM is output through the first AC input / output terminal of the wireless power receiving apparatus.
FIG. 7B shows the operation state of the protection circuit of FIG. 6 in the case of outputting the voltage corresponding to the reference potential (GND) through the first AC input / output terminal of the wireless power receiving apparatus.
7C shows a flow of current when a noise having a positive voltage is input through a first AC input / output terminal in a state in which the wireless power receiving apparatus is inactivated according to an embodiment of the present invention.
Figure 8 shows a circuit that can block both negative and positive noises, according to one embodiment of the present invention.
FIG. 9 shows a wireless power receiving apparatus according to an embodiment of the present invention constructed using the protection circuit shown in FIG.
10 shows a configuration according to a first mode in which a wireless power receiving apparatus according to an embodiment of the present invention receives AC power from a coil and outputs a DC voltage.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein, but may be implemented in various other forms. The terminology used herein is for the purpose of understanding the embodiments and is not intended to limit the scope of the present invention. Also, the singular forms as used below include plural forms unless the phrases expressly have the opposite meaning.

2 shows a circuit of a wireless power receiving apparatus 401 according to an embodiment.

The wireless power receiving apparatus 401 may be connected to an external inductor 60 through two AC input / output terminals 41 and 42. [

The wireless power receiving apparatus 401 provides a voltage to the first voltage providing unit 51 and the second voltage providing unit 52 and the second AC input / output terminal 42 configured to supply the voltage to the first AC input / output terminal 41 And a third voltage supplier 53 and a fourth voltage supplier 54 configured to receive the second voltage.

An AC voltage may be input from the external inductor 60 through the AC input / output terminals 41 and 42. [ At this time, the four NMOSs 11 to 14 may constitute a full bridge circuit, and the wireless power receiving apparatus 401 may include an AC-DC converter for converting the inputted AC voltage into DC.

Outputting the voltage to the external inductor 60 through the AC input / output terminals 41 and 42 may be performed in the second mode to provide a communication signal to the outside.

The first voltage providing unit 51 may include a first control unit 21 and a first NMOS 11. At this time, the first voltage providing unit 51 may be configured to provide a first voltage (ex: VM) to the first AC input / output terminal 41.

The second voltage supplier 52 may include a second controller 22 and a second NMOS transistor 12. At this time, the second voltage providing unit 52 may be configured to provide a second voltage (ex: GND) to the first AC input / output terminal 41.

The third voltage supplier 53 and the fourth voltage supplier 54 may be configured to be identical to the first voltage supplier and the second voltage supplier, respectively.

The control signal AC input / output terminals of the control units 21, 22, 23, and 24 may be connected to the gate terminals of the corresponding NMOSs 11, 12, 23, and 24.

The drain terminal of the first NMOS 11 may be connected to the operating power supply VM. The source terminal of the first NMOS 11 is connected to the drain terminal of the second NMOS 12 and may be connected to the first AC input / output terminal 41 to output a voltage to the first AC input / output terminal 41.

(GND to VM) of the wireless power receiving apparatus 401 to the first AC input / output terminal 41 and the second AC input / output terminal 42 in the same configuration as that of the wireless power receiving apparatus 401 shown in FIG. A malfunction may be caused or destroyed in the wireless power receiving apparatus 401 when noise having an exiting voltage is input.

3A is a graph 500 showing an example of noise that can be input to the AC input / output terminal of the wireless power receiving apparatus 401. In FIG.

3A shows an example in which the operating voltage is + 5V, but the operating voltage of the wireless power receiving apparatus according to the single-row mode may be +20 V, for example.

In Fig. 3A, the ordinate axis represents potential and the abscissa axis represents time (t). A noise exceeding the operating range (VM to GND) of the wireless power receiving apparatus 401, for example, a region including a region of + 5V to + 30V through the first AC input / output terminal 41 and the second AC input / The voltage of the noise region 510 or the second noise region 520 including the 0V to -30V region may be applied.

3B shows a penetration path 470 of a voltage when a voltage corresponding to the first noise region 510 is applied. The voltage input through the first AC input / output terminal 41 may affect the other components 490 of the wireless power receiving apparatus 401 through the first NMOS 11. That is, the chip may malfunction or be destroyed due to a voltage out of the operating range of the wireless power receiving apparatus 401. Similarly, the same result may be obtained when the voltage corresponding to the first noise region 510 affects the inside of the wireless power receiving apparatus through the second AC input / output terminal 42.

3C is a circuit showing a voltage penetration path 471 when a voltage corresponding to the second noise region 520 is applied. An excessive negative voltage input through the first AC input / output terminal 41 may cause a current to flow through the penetration path 471 and affect the other components 490 of the wireless power receiving apparatus 401. That is, the chip may malfunction or be destroyed due to a voltage out of the operating range of the wireless power receiving apparatus 401. Similarly, the same result may occur when a voltage corresponding to the second noise region 520 flows through the second AC input / output terminal 42.

4 shows a protection circuit 200 according to an embodiment of the present invention for protecting the wireless power receiving apparatus when a noise having a negative value is applied through an AC input / output terminal of the wireless power receiving apparatus .

4 is a circuit in which the first AC input / output terminal 41, the first voltage provider 51 and the second voltage provider 52 shown in FIG. 2 are modified. 4 is described with reference to the first AC input / output terminal 41, but the circuit shown in FIG. 4 can be applied to the second AC input / output terminal 42 as well.

The protection circuit 200 may include a first voltage providing unit 51 and a second voltage providing unit 52 shown in FIG. In addition, the protection circuit 200 may further include a first protection unit 1 and a second protection unit 2. The first protection unit 1 may include a first voltage sensing terminal A and a first voltage following terminal B. [ The second protection unit 2 may include a second voltage sensing terminal A 'and a second voltage following terminal B'.

The first voltage sensing terminal A and the first voltage follower terminal B may be connected to the gate terminals of the first AC input / output terminal 41 and the first NMOS 11, respectively. The second voltage sensing terminal A 'and the second voltage following terminal B' may be connected to the gate terminals of the first AC input / output terminal 41 and the second NMOS 12, respectively.

5A shows the operation state of the protection circuit of FIG. 4 in the case of outputting the voltage corresponding to the potential of the operation power source VM through the first AC input / output terminal 41. FIG.

FIG. 5B shows the operation state of the protection circuit of FIG. 4 in the case of outputting a voltage corresponding to the reference potential GND through the first AC input / output terminal 41 of the wireless power receiving apparatus.

5C shows an operation state of the protection circuit of FIG. 4 when noise having a negative voltage is input through the first AC input / output terminal 41. FIG.

5A, the first protection unit 1 and the second protection unit 2 may be OFF when the voltage VM of the operation power source is to be outputted through the first AC input / output terminal 41. [ In this case, since the first protection unit 1 and / or the second protection unit 2 perform no function, the voltage follower terminal does not follow the voltage of the voltage sense terminal. Therefore, the voltage follower terminals do not affect the gates of the first NMOS 11 and the second NMOS 12. The first control unit 21 may output VM + 2Vt, which is a voltage for keeping the first NMOS 11 in the ON state. Here, Vt may correspond to the turn-on voltage of the NMOS. At this time, the voltage VM of the operation power source can be substantially applied to the first AC input / output terminal 41 through the first NMOS 11. At this time, the second control unit 22 provides the reference voltage GND to the gate of the second NMOS 12, and the second NMOS 12 is turned off, so that the drain terminal of the second NMOS 12 can be floated.

5B, when the reference potential GND is to be output to the first AC input / output terminal 41, the first protection unit 1 and the second protection unit 2 may be in the OFF state. The second control unit 22 may output 2Vt, which is a voltage for keeping the second NMOS 12 in the ON state. The reference potential GND can be substantially applied to the first AC input / output terminal 41 via the second NMOS 12. The first control unit 21 is configured to provide a reference voltage GND to the gate of the first NMOS 11 and the first NMOS 11 may be turned off so that the source terminal of the first NMOS 11 may be floating.

(For example, -30 V) lower than the reference potential through the first AC input / output terminal 41, as shown in FIG. 5C. At this time, the first protection unit 1 and the second protection unit 2 may be operated so that each voltage follow-up terminal follows the voltage of each voltage sense terminal.

At this time, the potential of the first voltage follower terminal B of the first protection unit 1 may follow the potential of the first voltage sense terminal A of the first protection unit 1. [ As a result, since the first NMOS 11 is turned off, the noise introduction through the first NMOS 11 can be blocked. In addition, due to the polarity of the parasitic diode of the first NMOS 11, noise having a negative voltage can not pass through the parasitic diode. Therefore, the chip can be protected from noise having an unintended negative voltage.

At this time, the potential of the second voltage follower terminal B 'of the second protection unit 2 may follow the potential of the second voltage sense terminal A' of the second protection unit 2. As a result, since the second NMOS 12 is turned off, the noise introduction through the second NMOS 12 can be blocked. 6 or FIG. 9, when the fourth NMOS 14 is added to the circuit, a noise having a negative voltage due to the polarity of the parasitic diode 141 of the fourth NMOS 14 is generated by the parasitic diode 141). Therefore, the chip can be protected from noise having an unintended negative voltage.

6 illustrates a protection circuit 300 according to an embodiment of the present invention for protecting the wireless power receiving apparatus when a noise having a positive voltage is applied through an AC input / output terminal of the wireless power receiving apparatus will be.

In the present embodiment, the first AC input / output terminal 41 will be mainly described. The second AC input / output terminal 42 may be connected to the same circuit as shown in FIG.

The protection circuit 300 may include a first voltage providing unit 51 and a second voltage providing unit 52 shown in FIG. The protection circuit 300 may further include a third NMOS 13, a fourth NMOS 14, and resistors 31 and 32. At this time, the third NMOS 13 and the fourth NMOS 14 may include parasitic diodes 131 and 141, respectively.

One terminal and the other terminal of the resistor 31 are connected to the gate terminal of the third NMOS 13 so that the third NMOS 13 remains off when a potential having a value larger than the reference potential of the control device is applied from the outside, And the reference potential GND. At this time, the one terminal may be connected to the gate terminal of the first NMOS 11 in common.

Similarly, one terminal of the resistor 32 may be connected to the gate terminal of the second NMOS 12 and the fourth NMOS 14, and the other terminal of the resistor 32 may be connected to the reference potential GND.

7A shows the operation state of the protection circuit in Fig. 6 when a voltage corresponding to the potential of the operation power source VM is output through the first AC input / output terminal 41. Fig.

Fig. 7B shows the operation state of the protection circuit of Fig. 6 in the case of outputting the voltage corresponding to the reference potential GND through the first AC input / output terminal 41. Fig.

7C shows a current flow when noise having a positive voltage is input through the first AC input / output terminal 41 according to an embodiment of the present invention.

7A, when the wireless power receiving apparatus is activated and the voltage VM of the operation power source is to be output through the first AC input / output terminal 41, the first controller 21 controls the first and second NMOSs 11 and 12, It is possible to output VM + 2Vt, which is a voltage for operating the 3NMOS 13. As a result, the first NMOS 11 and the third NMOS 13 are turned on, so that the voltage VM of the operating power source can be substantially applied to the first AC input / output terminal 41. At this time, the second controller 22 is configured to provide the reference voltage GND to the gate of the second NMOS 12. As a result, the second NMOS 12 maintains the off state, and the drain terminal of the second NMOS 12 can be floated.

7B, when the wireless power receiving apparatus is activated and the reference potential GND is to be output via the first AC input / output terminal 41, the second controller 22 controls the second and third NMOS 12 and 4, 14) can be output. As a result, the reference potential GND can be substantially provided to the first AC input / output terminal 41 through the second NMOS 12 and the fourth NMOS 14. At this time, the first controller 21 supplies the reference potential GND to the gate of the third NMOS 13, and as a result, the third NMOS 13 is turned off and the drain terminal of the third NMOS 13 is turned off .

A positive potential (for example, +30 V) may be applied through the first AC input / output terminal 41 as shown in FIG. 7C. At this time, the first NMOS 11, the second NMOS 12, the third NMOS 13, and the fourth NMOS 14 may be connected to the reference potential through the resistors 31 and 32 and turned off.

Since the third NMOS 13 is in the off state, the influence of the positive potential can be blocked by the third NMOS 13 (see 171). Also, because of the direction of the parasitic diode formed in the third NMOS 13, the influence of the positive potential can be blocked by the parasitic diode (see 172).

In addition, since the second NMOS 12 is in the off state, the influence of the positive potential can be blocked by the second NMOS 12 (see 173). Also, because of the direction of the parasitic diode formed in the second NMOS 12, the influence of the potential having the positive value can be blocked by the parasitic diode (see 174).

Figure 8 shows a circuit that can block both negative and positive noises, according to one embodiment of the present invention.

The protection circuit 400 of FIG. 8 can be configured by combining the protection circuit 200 shown in FIG. 4 and the protection circuit 300 shown in FIG.

The operation principle of the protection circuit 400 of Fig. 8 is the same as that described with reference to Figs. 4 to 7 in the case where any external noise is applied through the first AC input / output terminal 41. Fig.

FIG. 9 shows a wireless power receiving apparatus according to an embodiment of the present invention constructed using the protection circuit shown in FIG.

Referring to FIG. 9, the first protection unit 1 may include an internal NMOS, an internal diode (e.g., Schottky diode), and a voltage distribution unit R01 and R02. The drain, source, and gate terminals of the internal NMOS may be connected to a first voltage follower terminal B, an anode of the internal diode, and a distributed voltage output terminal C of the voltage divider, respectively. The cathode of the internal diode may be connected to the first voltage sensing terminal (A). The voltage divider may comprise two resistors R01 and R02. At this time, the first connection terminal and the second connection terminal of the voltage distributor may be respectively connected to the anode and the reference potential (GND) of the internal diode. And the first voltage follower terminal may be connected to the reference potential GND through the resistor 31. [

The second protection portion 2 may include an internal NMOS, an internal diode (e.g., a Schottky diode), and a voltage distribution portion R12 and R22. The drain, source, and gate terminals of the internal NMOS may be connected to a second voltage follower terminal B ', an anode of the internal diode, and a distributed voltage output terminal C' of the voltage divider, respectively. The cathode of the inner diode may be connected to the second voltage sensing terminal A '. The voltage divider may comprise two resistors R12 and R22. At this time, the third connection terminal and the fourth connection terminal of the voltage distributor may be respectively connected to the anode and the reference potential (GND) of the internal diode. And the second voltage follower terminal B 'may be connected to the reference potential GND through the resistor 32. [

The first voltage follower terminal B and the second voltage follower terminal B 'may be connected to the control signal output terminals of the first controller 21 and the second controller 22, respectively. That is, the first voltage follower terminal B and the second voltage follower terminal B 'may be connected to the gates of the first NMOS 11 and the second NMOS 12, respectively.

In order to make the first NMOS 11 and the third NMOS 13 have an off state when a negative (-) potential lower than the reference potential GND of the control device is applied from the outside to the first AC input / output terminal 41, 1 protection section 1 may be arranged such that the potential of the first voltage follower terminal B follows the potential of the first voltage sense terminal A. [ The potential of the second voltage follower terminal B 'is applied to the second voltage sense terminal A' so that the second NMOS 12 and the fourth NMOS 14 are turned off at this time. As shown in FIG.

In order to make the first NMOS 11 and the third NMOS 13 have an off state when a positive potential higher than the reference potential GND of the control device is applied from the outside to the first AC input / output terminal 41, The gate terminals of the first NMOS 11 and the third NMOS 13 may be connected to a reference potential GND through a resistor 31. [ The gate terminal of the second NMOS 12 and the fourth NMOS 14 may be connected to the reference potential through the resistor 32 so that the second NMOS 12 and the fourth NMOS 14 are turned off at this time. At this time, the voltage of the first voltage sensing terminal A does not affect the first voltage following terminal B due to the diode included in the first protection unit 1. [ Similarly, the voltage of the second voltage sensing terminal A 'does not affect the second voltage follower terminal B' by the diode included in the second protection portion 2.

In FIG. 9, the internal circuit connected to the first AC input / output terminal 41 may be the same as the internal circuit connected to the second AC input / output terminal 42. The reference potential GND can be applied to the second AC input / output terminal 42 when the operation potential VM is applied to the first AC input / output terminal 41, and vice versa.

The protection circuits described with reference to Figs. 4 to 9 may be compared with an internal circuit connected to the first AC input / output terminal 41 shown in Fig. The internal circuits connected to the second AC input / output terminal 42 shown in FIG. 2 may also be replaced by the protection circuit shown in FIGS.

Output terminal 42 is connected to the first AC input / output terminal 41. The first AC input / output terminal 41 is connected to the first AC input /

10 is a functional block diagram according to a first mode in which a wireless power receiving apparatus according to an embodiment of the present invention receives AC power from a coil and outputs a DC voltage.

The four FETs in the configuration diagram shown in Fig. 10 correspond to the NMOSs 11 to 14 shown in Fig. At this time, the gates of the four FETs can be controlled by a Sync Rectifier Control. In Fig. 10, the terminal Tout may be a terminal from which a rectified DC voltage is output. The terminals 741 and 742 may be terminals for connecting the bootstrap capacitors for driving the two FETs shown in the upper part of Fig. Such a structure is illustrated in the prior art, for example, in the data sheet of part number bq51221 of TI.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the essential characteristics thereof. The contents of each claim in the claims may be combined with other claims without departing from the scope of the claims.

Claims (7)

① AC input / output terminal; (2) a first control unit; And a first NMOS having a drain, a gate, and a source connected to an operation power source, a control signal output terminal of the first control unit, and the AC input / output terminal, respectively,
A first protection unit having a first voltage sensing terminal connected to the AC input / output terminal and a first voltage follower terminal connected to a gate of the first NMOS,
Further comprising:
The first protection unit may be configured such that the potential of the first voltage follower terminal is higher than the potential of the first voltage follower terminal when the potential of the first voltage follower terminal is higher than the potential of the first voltage follower terminal, The voltage detection terminal being adapted to follow the potential of the voltage detection terminal,
Wireless power receiving device. The method according to claim 1,
The first protection unit includes an internal NMOS, an internal diode, and a voltage distribution unit,
A drain, a source, and a gate of the internal NMOS are respectively connected to the first voltage follower terminal, an anode of the internal diode, and a distributed voltage output terminal of the voltage divider,
The cathode of the internal diode is connected to the first voltage sensing terminal,
Wherein the first connection terminal and the second connection terminal of the voltage distributor are respectively connected to the anode and the reference potential,
Wireless power receiving device. The method according to claim 1,
A second control unit;
A second NMOS having a source, a gate, and a drain respectively connected to a reference potential, a control signal output terminal of the second control unit, and the AC input / output terminal; And
A second protection unit having a second voltage sensing terminal connected to the AC input / output terminal and a second voltage follower terminal connected to a gate of the second NMOS,
Further comprising:
The second protection unit is configured to prevent the potential of the second voltage follower terminal from being higher than the potential of the second voltage follower terminal when the potential of the second voltage follower terminal is higher than the potential of the second voltage follower terminal, The voltage detection terminal being adapted to follow the potential of the voltage detection terminal,
Wireless power receiving device. ① AC input / output terminal; (2) a first control unit; (3) a first NMOS having a drain and a gate connected to an operation power source and a control signal output terminal of the first control unit, respectively; And a third NMOS having a drain, a gate, and a source connected to the AC input / output terminal, a control signal output terminal of the first control unit, and a source of the first NMOS, respectively,
A first protection unit having a first voltage sensing terminal connected to the AC input / output terminal and a first voltage follower terminal connected to a gate of the first NMOS and a gate of the third NMOS,
Further comprising:
The first protection unit may be configured such that the potential of the first voltage follower terminal is higher than the potential of the first voltage follower terminal when the potential of the first voltage follower terminal is higher than the potential of the first voltage follower terminal, The voltage detection terminal being adapted to follow the potential of the voltage detection terminal,
Wireless power receiving device. 5. The method of claim 4, further comprising: connecting the gate of the third NMOS to the reference potential to make the third NMOS have an off state when a potential higher than the reference potential of the wireless power receiving apparatus is applied to the AC input / Further comprising: a resistor that is connected to the power supply. 6. The method of claim 5,
The first protection unit includes an internal NMOS, an internal diode, and a voltage distribution unit,
A drain, a source, and a gate of the internal NMOS are respectively connected to the first voltage follower terminal, an anode of the internal diode, and a distributed voltage output terminal of the voltage divider,
The cathode of the internal diode is connected to the first voltage sensing terminal,
Wherein the first connection terminal and the second connection terminal of the voltage distributor are respectively connected to the anode and the reference potential,
Wireless power receiving device. 5. The method of claim 4,
A second control unit;
A second NMOS having a gate and a drain connected to the control signal output terminal of the second control unit and the AC input / output terminal, respectively;
A fourth NMOS having a drain, a gate, and a source respectively connected to a reference potential, a control signal output terminal of the second control unit, and a source of the second NMOS; And
A second protection unit having a second voltage sensing terminal connected to the AC input / output terminal and a second voltage follower terminal connected to a gate of the second NMOS;
Further comprising:
The second protection unit is configured to prevent the potential of the second voltage follower terminal from being higher than the potential of the second voltage follower terminal when the potential of the second voltage follower terminal is higher than the potential of the second voltage follower terminal, The voltage detection terminal being adapted to follow the potential of the voltage detection terminal,
Wireless power receiving device.

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