KR102303822B1 - Rectifier for wireless power reception capable of outputting constant voltage - Google Patents

Abstract

A rectifier for wireless power reception capable of outputting a constant voltage is disclosed. The rectifier capable of outputting a constant voltage according to the present invention adjusts the size of the combined resistance on the load side in such a way that a switching unit having a predetermined resistance is connected in parallel to or cut off from the load resistance according to the magnitude of the output DC voltage of the rectifier. By doing so, the magnitude of the output DC voltage may be maintained at a constant magnitude.

Description

Rectifier for wireless power reception capable of constant voltage output

The present invention relates to a rectifier for wireless power reception capable of outputting a constant voltage.

Recently, since a wired charging technique hinders the user's convenience, a wireless charging technology for charging a battery of a portable device in a wireless manner has been introduced.

As such a wireless charging technology, a wireless charging technique based on electromagnetic induction and a wireless charging technique based on magnetic resonance exist. Both the wireless charging technique based on electromagnetic induction and the wireless charging technique based on magnetic resonance use a non-radial attenuated AC signal that exists around the coil in the near field. That is, a method of charging the battery without a contact terminal is introduced using inductive coupling between the primary coil of the wireless power transmitter and the secondary coil of the wireless power receiver.

The wireless power receiver includes a receiver coil that receives a wireless power signal transmitted from the wireless power transmitter, a rectifier that converts an AC signal induced through the receiver coil into a DC voltage, and a rectifier that adjusts the output voltage of the rectifier to a constant voltage and supplies it to the battery. It consists of a constant voltage part.

The existing wireless power receiver consists of a rectifier and a constant voltage unit separately, and when a DC voltage is output from the rectifier, the constant voltage unit adjusts the DC voltage to a constant voltage. was made to do. For this reason, the impedance seen from the receiving coil of the wireless power receiving device increases, and the output voltage of the rectifier increases, which causes a problem of generating unnecessary energy loss in the wireless power receiving device.

Therefore, it is necessary to study a rectifier for wireless power reception that can stably output a DC voltage having a constant voltage from the rectifier by integrally configuring the rectifier and the constant voltage unit.

The rectifier capable of outputting a constant voltage according to the present invention adjusts the size of the combined resistance on the load side in such a way that a switching unit having a predetermined resistance is connected in parallel to or cut off from the load resistance according to the magnitude of the output DC voltage of the rectifier. By doing so, the magnitude of the output DC voltage can be maintained at a constant magnitude.

A rectifier for wireless power reception capable of outputting a constant voltage according to an embodiment of the present invention includes a first diode and a third diode for filtering a + signal from an AC signal received from a wireless power transmission device, and a - signal from the AC signal. A rectifying unit including a second diode and a fourth diode configured as a bridge, a load resistance to which an output DC voltage output by rectifying the AC signal is applied by the rectifying unit, a first reference resistance and a second reference resistance connected in parallel to the load resistance a reference resistor, the first reference resistor and the second reference resistor connected in series with each other, connected in parallel to the third diode, and a first voltage applied across the second reference resistor by filtering a signal. By performing an on/off switching operation according to the magnitude of An on/off switching operation is performed according to the magnitude of a second voltage that is connected in parallel to the first switching unit having a resistance of one magnitude and the fourth diode, and is applied to both ends of the second reference resistor by filtering the + signal. and a second switching unit having a resistance of the first predetermined magnitude for adjusting the magnitude of the output DC voltage to the constant voltage of the predetermined magnitude by being connected in parallel to the load resistor or blocked by performing .

In addition, the rectifier for wireless power reception capable of outputting a constant voltage according to another embodiment of the present invention includes a first diode and a third diode for filtering the + signal in the AC signal received from the wireless power transmission device, and a - in the AC signal. A rectifying unit comprising a second diode and a fourth diode for filtering a signal as a bridge, a load resistor to which an output DC voltage output by rectifying the AC signal is applied by the rectifying unit, and a first reference resistor connected in parallel to the load resistor and a second reference resistor, wherein the first reference resistor and the second reference resistor are connected in series with each other, wherein a first voltage applied across the second reference resistor by filtering a signal and a predetermined reference generating a first amplified signal according to a difference between voltages, and generating a second amplified signal according to a difference between a second voltage applied to both ends of the second reference resistor and the preset reference voltage by filtering the + signal An operational amplifier, connected in parallel to the third diode, and performing an on/off switching operation according to whether the first amplified signal is generated or not, is connected in parallel to the load resistor or blocked, so that the output A first switching unit having a resistance of a first predetermined magnitude for adjusting the magnitude of the DC voltage to a constant voltage of a predetermined magnitude is connected in parallel to the fourth diode, and is turned on/off according to whether the second amplified signal is generated. and a second switching unit having a resistance of the first predetermined magnitude for performing a switching operation to be connected in parallel to or cut off from the load resistor to adjust the magnitude of the output DC voltage to the constant voltage of the predetermined magnitude.

The rectifier capable of outputting a constant voltage according to the present invention adjusts the size of the combined resistance on the load side in such a way that a switching unit having a predetermined resistance is connected in parallel to or cut off from the load resistance according to the magnitude of the output DC voltage of the rectifier. By doing so, the magnitude of the output DC voltage may be maintained at a constant magnitude.

1 is a diagram illustrating a circuit structure of a rectifier for wireless power reception capable of outputting a constant voltage according to an embodiment of the present invention.
2 is a diagram illustrating a circuit structure of a rectifier for wireless power reception capable of outputting a constant voltage according to another embodiment of the present invention.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings. These descriptions are not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. While describing each drawing, like reference numerals are used for similar components, and unless otherwise defined, all terms used in this specification, including technical or scientific terms, refer to those of ordinary skill in the art to which the present invention belongs. It has the same meaning as is commonly understood by those who have it.

In this document, when a part "includes" a certain component, it means that other components may be further included, rather than excluding other components, unless otherwise stated. In addition, in various embodiments of the present invention, each of the components, functional blocks or means may be composed of one or more sub-components, and the electrical, electronic, and mechanical functions performed by each component are electronic. A circuit, an integrated circuit, an ASIC (Application Specific Integrated Circuit), etc. may be implemented with various well-known devices or mechanical elements, and may be implemented separately or two or more may be integrated into one.

1 is a diagram illustrating a circuit structure of a rectifier for wireless power reception capable of outputting a constant voltage according to an embodiment of the present invention.

1, the rectifier 110 according to the present invention is a first diode 111 and a third diode 113 for filtering the + signal in the AC signal received from the wireless power transmission device, and - The second diode 112 and the fourth diode 114 for filtering a signal are a rectifying unit configured as a bridge, a load resistor 115 to which an output DC voltage output by rectifying the AC signal is applied by the rectifying unit, and the load resistor A first reference resistor 116 and a second reference resistor 117 connected in parallel to 115 (the first reference resistor 116 and the second reference resistor 117 are connected in series with each other), the third It includes a first switching unit 118 connected in parallel to the diode 113 and a second switching unit 119 connected in parallel to the fourth diode 114 .

At this time, the first switching unit 118 is configured to have a resistance of a first predetermined magnitude, and is turned on according to the magnitude of the first voltage applied to both ends of the second reference resistor 117 by filtering the - signal. By performing an (on)/off switching operation to be connected in parallel to or cut off from the load resistor 115 , the magnitude of the output DC voltage is adjusted to a predetermined constant voltage.

In addition, the second switching unit 119 is configured to have a resistance of the first predetermined magnitude, and according to the magnitude of the second voltage applied to both ends of the second reference resistor 117 by filtering the + signal. By performing an on/off switching operation to be connected in parallel to or cut off from the load resistor 115 , the magnitude of the output DC voltage is adjusted to the constant voltage of the preset magnitude.

At this time, according to an embodiment of the present invention, the first switching unit 118 receives the first voltage as an input to the gate and turns on/off depending on whether the magnitude of the first voltage exceeds a preset threshold. may be constituted by an N-channel Metal Oxide Semiconductor Field Effect Transistor (NMOS) that performs an operation, and the second switching unit 119 receives the second voltage as an input to the gate and increases the level of the second voltage. It may be configured as an NMOS that performs an on/off operation according to whether a preset threshold is exceeded.

Hereinafter, operations of the first switching unit 118 and the second switching unit 119 will be described in detail by distinguishing between when the AC signal received from the wireless power transmitter is a - signal and a + signal.

First, when a signal is applied to the rectifier 110 , a current flows through the second diode 112 and the fourth diode 114 , thereby filtering the signal. At this time, an AC signal is converted into a DC signal by applying an output DC voltage to the -signal to the load resistor 115 . When the strength of the wireless power transmitted from the wireless power transmitter is large, the output DC voltage is will increase

When the magnitude of the output DC voltage increases, the magnitude of the first voltage applied to both ends of the second reference resistor 117 will increase, and as the magnitude of the first voltage increases, the first switching unit 118 ) when the first voltage applied to the gate exceeds a preset threshold for turning on the first switching unit 118 , the first switching unit 118 may be turned on.

In this way, when the first switching unit 118 is turned on, the resistance of the first switching unit 118 is connected in parallel to the load resistor 115 and the first and second reference resistors 116 and 117, thereby Due to this, the magnitude of the combined resistance on the load side decreases when viewed from the input terminal.

When the magnitude of the combined resistance on the load side decreases, as the magnitude of the output DC voltage applied to the load side decreases, the rectifier 110 eventually produces a constant voltage even if the strength of the signal received from the wireless power transmitter is large. can be printed out.

For reference, when the first voltage exceeds the preset threshold, the second switching unit 119 is also turned on, but in the - signal, the fourth diode 114 connected in parallel with the second switching unit 119 is In the ON state, since the current flows through the fourth diode 114 , the second switching unit 119 is turned on, so that the rectifier 110 is hardly affected.

If the first switching unit 118 is turned on to decrease the level of the output DC voltage, the level of the first voltage applied to both ends of the second reference resistor 117 is lower than the preset threshold. When reduced, the first switching unit 118 will be turned off (turn-off), and when the first switching unit 118 is turned off in this way, the load resistance for the resistance of the first switching unit 118 ( 115) is blocked.

When the connection to the resistance of the first switching unit 118 is cut off, when viewed from the input side, the combined resistance of the load is calculated as the combined resistance according to the load resistance 115 and the first and second reference resistors 116 and 117 . will increase again, and when the combined resistance of the load side increases, the magnitude of the output DC voltage also increases.

In this way, by performing a switching operation according to the magnitude of the first voltage, the first switching unit 118 may adjust the combined resistance of the load to adjust the magnitude of the output DC voltage to a voltage of a certain magnitude.

Meanwhile, when a + signal is applied to the rectifier 110 , a current flows through the first diode 111 and the third diode 113 , thereby filtering the + signal. At this time, when the output DC voltage for the + signal is applied to the load resistor 115 , the AC signal is converted into a DC signal. When the strength of wireless power transmitted from the wireless power transmitter is large, the output DC voltage will increase

When the magnitude of the output DC voltage increases, the magnitude of the second voltage applied to both ends of the second reference resistor 117 increases, and as the magnitude of the second voltage increases, the second switching unit 119 ) when the second voltage applied to the gate exceeds a preset threshold for turning on the second switching unit 119 , the second switching unit 119 may be turned on.

In this way, when the second switching unit 119 is turned on, the resistance of the second switching unit 119 is connected in parallel to the load resistor 115 and the first and second reference resistors 116 and 117, thereby Due to this, the magnitude of the combined resistance on the load side decreases when viewed from the input terminal.

When the magnitude of the combined resistance on the load side decreases, as the magnitude of the output DC voltage applied to the load side decreases, the rectifier 110 eventually produces a constant voltage even if the strength of the signal received from the wireless power transmitter is large. can be printed out.

For reference, when the second voltage exceeds the preset threshold, the first switching unit 118 is also turned on, but in the + signal, the third diode 113 connected in parallel with the first switching unit 118 is In the ON state, since the current flows through the third diode 113 , there is little effect on the rectifier 110 due to the first switching unit 118 being turned on.

If, as the second switching unit 119 is turned on and the magnitude of the output DC voltage is decreased, the magnitude of the second voltage applied to both ends of the second reference resistor 117 is lower than the preset threshold. When reduced, the second switching unit 119 will be turned off. When the second switching unit 119 is turned off in this way, the resistance of the second switching unit 119 is in parallel with the load resistance 115 . The connection is blocked.

When the connection to the resistance of the second switching unit 119 is cut off, when viewed from the input side, the combined resistance of the load is calculated as the combined resistance according to the load resistance 115 and the first and second reference resistors 116 and 117 . will increase again, and when the combined resistance of the load side increases, the magnitude of the output DC voltage also increases.

In this way, the second switching unit 119 performs a switching operation according to the magnitude of the second voltage, thereby adjusting the combined resistance of the load side to adjust the magnitude of the output DC voltage to a voltage of a certain magnitude.

2 is a diagram illustrating a circuit structure of a rectifier for wireless power reception capable of outputting a constant voltage according to another embodiment of the present invention.

Referring to FIG. 2 , the rectifier 210 according to another embodiment of the present invention includes a first diode 211 and a third diode 213 for filtering a + signal in an AC signal received from a wireless power transmitter, and the In the AC signal - a rectifying unit configured as a bridge in which the second diode 212 and the fourth diode 214 for filtering the signal, the AC signal is rectified by the rectifying unit and the output DC voltage outputted is applied to the load resistor 215 , a first reference resistor 216 and a second reference resistor 217 connected in parallel to the load resistor 215 (the first reference resistor 216 and the second reference resistor 217 are connected in series with each other) , generating a first amplified signal according to a difference between a first voltage applied to both ends of the second reference resistor 217 and a preset reference voltage by filtering the - signal, and filtering the + signal to generate the first amplified signal 2 An operational amplifier 218 that generates a second amplified signal according to a difference between a second voltage applied to both ends of the reference resistor 217 and the preset reference voltage, and a first connected to the third diode 213 in parallel It includes a first switching unit 219 and a second switching unit 220 connected in parallel to the fourth diode 214 .

At this time, the first switching unit 219 is configured to have a resistance of a first predetermined magnitude, and performs an on/off switching operation according to whether the first amplified signal is generated to the load resistance ( 215), the magnitude of the output DC voltage is adjusted to a constant voltage of a preset magnitude by being connected in parallel or blocked.

In addition, the second switching unit 220 is configured to have a resistance of the predetermined first size, and performs an on/off switching operation according to whether the second amplified signal is generated in parallel to the load resistor 215 . By being connected or disconnected, the magnitude of the output DC voltage is adjusted to the constant voltage of the preset magnitude.

At this time, according to an embodiment of the present invention, the first switching unit 219 may be configured as an NMOS that receives the first amplified signal as an input to a gate and performs an on/off operation, and the second switching unit 219 The unit 220 may include an NMOS that receives the second amplified signal as an input to the gate and performs an on/off operation.

In this case, it is assumed that the amplitudes of the first amplified signal and the second amplified signal exceed both thresholds for turning on the first switching unit 219 and the second switching unit 220 .

Hereinafter, operations of the first switching unit 219 and the second switching unit 220 will be described in detail by distinguishing between when the AC signal received from the wireless power transmitter is a - signal and a + signal.

First, when a signal is applied to the rectifier 210 , a current flows through the second diode 212 and the fourth diode 214 , thereby filtering the signal. At this time, an AC signal is converted into a DC signal by applying an output DC voltage to the -signal to the load resistor 215 . When the strength of the wireless power transmitted from the wireless power transmitter is large, the output DC voltage is will increase

When the magnitude of the output DC voltage increases, the magnitude of the first voltage applied to both ends of the second reference resistor 217 will increase, and as the magnitude of the first voltage increases, the first voltage and the When a difference between the set reference voltages occurs, the operational amplifier 218 may generate a first amplified signal according to the difference.

In this way, when the first amplified signal is generated, the first amplified signal is applied to the gate of the first switching unit 219 so that the first switching unit 219 may be turned on.

When the first switching unit 219 is turned on, the resistance of the first switching unit 219 is connected in parallel to the load resistor 215 and the first and second reference resistors 216 and 217, thereby the input terminal When viewed from , the magnitude of the combined resistance on the load side decreases.

When the magnitude of the combined resistance on the load side is reduced, as the magnitude of the output DC voltage applied to the load side is decreased, the rectifier 210 is eventually a voltage of a constant magnitude even if the strength of the signal received from the wireless power transmitter is large. can be printed out.

For reference, since the first amplified signal is also applied to the gate of the second switching unit 220, the second switching unit 220 is also turned on, but in the - signal, the fourth switch connected in parallel with the second switching unit 220 is Since the diode 214 is turned on and a current flows through the fourth diode 214 , the second switching unit 220 is turned on, so that the rectifier 210 is hardly affected.

If the first switching unit 219 is turned on and the level of the output DC voltage is reduced, the level of the first voltage applied to both ends of the second reference resistor 217 is equal to or less than the preset reference voltage. , the operational amplifier 218 may not generate the first amplified signal.

At this time, the first switching unit 219 will be turned off, and when the first switching unit 219 is turned off in this way, the resistance of the first switching unit 219 is connected in parallel with the load resistor 215 to the resistance of the first switching unit 219 . this is blocked

When the connection to the resistance of the first switching unit 219 is cut off, when viewed from the input side, the combined resistance of the load is calculated as the combined resistance according to the load resistance 215 and the first and second reference resistors 216 and 217 . will increase again, and when the combined resistance of the load side increases, the magnitude of the output DC voltage also increases.

In this way, the first switching unit 219 performs a switching operation according to whether the first amplified signal is generated, thereby adjusting the combined resistance of the load side to adjust the output DC voltage to a constant voltage. .

Meanwhile, when a + signal is applied to the rectifier 210 , current flows through the first diode 211 and the third diode 213 , thereby filtering the + signal. At this time, when the output DC voltage for the + signal is applied to the load resistor 215 , the AC signal is converted into a DC signal. When the strength of the wireless power transmitted from the wireless power transmitter is large, the output DC voltage will increase

When the magnitude of the output DC voltage increases, the magnitude of the second voltage applied to both ends of the second reference resistor 217 will increase, and as the magnitude of the second voltage increases, the second voltage and the When a difference between the set reference voltages occurs, the operational amplifier 218 may generate a second amplified signal according to the difference.

In this way, when the second amplified signal is generated, the second amplified signal is applied to the gate of the second switching unit 220 so that the second switching unit 220 may be turned on.

When the second switching unit 220 is turned on, the resistance of the second switching unit 220 is connected in parallel to the load resistor 215 and the first and second reference resistors 216 and 217, and thus the input terminal When viewed from , the magnitude of the combined resistance on the load side decreases.

When the magnitude of the combined resistance on the load side is reduced, as the magnitude of the output DC voltage applied to the load side is decreased, the rectifier 210 is eventually a voltage of a constant magnitude even if the strength of the signal received from the wireless power transmitter is large. can be printed out.

For reference, since the second amplified signal is also applied to the gate of the first switching unit 219 , the first switching unit 219 is also turned on, but in the + signal, the third signal connected in parallel with the first switching unit 219 is Since the diode 213 is on and a current flows through the third diode 213 , the first switching unit 219 is turned on, so that the rectifier 210 is hardly affected.

If the second switching unit 220 is turned on and the magnitude of the output DC voltage is decreased, the magnitude of the second voltage applied to both ends of the second reference resistor 217 is equal to or less than the preset reference voltage. , the operational amplifier 218 may not generate the second amplified signal.

At this time, the second switching unit 220 will be turned off, and when the second switching unit 220 is turned off in this way, the resistance of the second switching unit 220 is connected in parallel with the load resistor 215 to the resistance of the second switching unit 220 . this is blocked

When the connection to the resistance of the second switching unit 220 is cut off, when viewed from the input side, the combined resistance of the load is calculated as the combined resistance according to the load resistor 215 and the first and second reference resistors 216 and 217 . will increase again, and when the combined resistance of the load side increases, the magnitude of the output DC voltage also increases.

In this way, by performing a switching operation according to whether the second amplified signal is generated, the second switching unit 220 adjusts the combined resistance of the load to adjust the output DC voltage to a constant voltage. .

As described above, the present invention has been described with specific matters such as specific components and limited embodiments and drawings, but these are provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , various modifications and variations are possible from these descriptions by those of ordinary skill in the art to which the present invention pertains.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and not only the claims to be described later, but also all those with equivalent or equivalent modifications to the claims will be said to belong to the scope of the spirit of the present invention. .

110: rectifier
111, 112, 113, 114: first, second, third, fourth diode
115: load resistance
116, 117: first and second reference resistors
118: first switching unit
119: second switching unit
210: rectifier
211, 212, 213, 214: first, second, third and fourth diodes
215: load resistance
216, 217: first and second reference resistors
218: operational amplifier
219: first switching unit
220: second switching unit

Claims (8)

a rectifier comprising a first diode and a third diode for filtering the + signal from the AC signal received from the wireless power transmitter, and a second diode and a fourth diode for filtering the - signal from the AC signal as a bridge;
a load resistor to which an output DC voltage output by rectifying the AC signal is applied by the rectifying unit;
a first reference resistor and a second reference resistor connected in parallel to the load resistor, the first reference resistor and the second reference resistor connected in series with each other;
The load is connected in parallel to the third diode and performs an on/off switching operation according to the magnitude of the first voltage applied to both ends of the second reference resistor by filtering the signal. a first switching unit having a resistance of a first predetermined magnitude for adjusting the magnitude of the output DC voltage to a constant voltage of a predetermined magnitude by being connected or blocked in parallel with the resistor; and
It is connected in parallel to the fourth diode and is connected in parallel to the load resistor by performing an on/off switching operation according to the magnitude of a second voltage applied to both ends of the second reference resistor by filtering the + signal. A second switching unit having a resistance of the first preset magnitude for adjusting the magnitude of the output DC voltage to the constant voltage of the preset magnitude by being cut off
including,
The first switching unit
When the magnitude of the first voltage exceeds a preset threshold, a turn-on switching operation is performed to decrease the magnitude of the combined resistance of the load side as it is connected in parallel to the load resistor, and the output DC When the magnitude of the voltage is reduced and the magnitude of the first voltage becomes less than or equal to the preset threshold in response to the decrease in the magnitude of the output DC voltage, a turn-off switching operation is performed to perform a turn-off switching operation to the load A constant voltage for adjusting the magnitude of the output DC voltage to the constant voltage of the preset magnitude by increasing the magnitude of the combined resistance of the load side and increasing the magnitude of the output DC voltage as the connection with the resistor is cut off Rectifier for wireless power reception with output. delete According to claim 1,
The second switching unit
When the magnitude of the second voltage exceeds the preset threshold, a turn-on switching operation is performed to decrease the magnitude of the combined resistance of the load side as it is connected in parallel to the load resistor, thereby increasing the magnitude of the output DC voltage and when the level of the second voltage becomes less than or equal to the preset threshold in response to the decrease in the level of the output DC voltage, a turn-off switching operation is performed to cut off the connection with the load resistor. A rectifier for wireless power reception capable of outputting a constant voltage that adjusts the magnitude of the output DC voltage to the constant voltage of the preset magnitude by performing an operation of increasing the magnitude of the output DC voltage by increasing the magnitude of the combined resistance on the load side. 4. The method of claim 3,
The first switching unit
and an N-channel Metal Oxide Semiconductor Field Effect Transistor (NMOS) that receives the first voltage as an input to the gate and performs an on/off operation depending on whether the level of the first voltage exceeds the preset threshold, and ,
The second switching unit
A rectifier for wireless power reception capable of outputting a constant voltage comprising an NMOS that receives the second voltage as an input to the gate and performs an on/off operation depending on whether the magnitude of the second voltage exceeds the preset threshold. delete delete delete delete

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