KR20150055753A - Wireless power transmission systme which enables to transmit and receive induced power signal and resonance power signal - Google Patents

Abstract

A wireless power transmission system which enables the transmission and receipt of induced power signals and resonance power signals is provided to increase the control efficiency and to simplify the composition, by comprising: a hybrid wireless power transmission device that can resonate an induced power signal and a resonance power signal; and a wireless power receiving device that can receive a power signal from the hybrid wireless power transmission device, the hybrid wireless power transmission device by comprising: a transmission coil made for resonating an induced power signal; a transmission antenna made for resonating a resonance power signal; a first variable capacitor block connected to the transmission coil and the transmission antenna; and a transmission control unit that, when the wireless power receiving device is an induced power receiving device, operates the transmission coil and controls the first variable capacitor block for induced main impedance matching; and when the wireless power receiving device is a magnetic resonance receiving device, operates the transmission antenna and controls the first variable capacitor block for resonance main impedance matching. The wireless power receiving device is comprises: a receiving block that can receive at least one from among the resonance power signal and the induced power signal; a second variable capacitor block connected to the receiving block; and a receiving control unit that controls the second variable capacitor block for an auxiliary impedance matching with the wireless transmission device.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonance power signal,

The present invention relates to a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonance power signal.

With the development of wireless communication technology, it becomes a ubiquitous information environment that can exchange all information desired by anyone at any time and anywhere. However, the communication information devices mostly depend on the battery, and the use of the communication information device is limited due to the power supply by the wired power cord.

Therefore, the wireless information network environment can not be truly freed without solving the problem with the terminal power source.

In order to solve this problem, many methods for wirelessly transmitting electric power have been developed, such as a radio wave reception method using a microwave, a magnetic induction method using a magnetic field, or a magnetic resonance method using energy conversion between a magnetic field and an electric field This is representative.

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

In addition, the magnetic induction system has advantages of high power transmission efficiency by using a transmission coil as a transmitter and a magnetic energy coupling using primary and secondary coils using a secondary coil as a receiver, The primary and secondary coils must be adjacent to each other by a short distance of about several millimeters and there is a disadvantage that the power transmission efficiency is rapidly changed according to the alignment of the primary and secondary coils.

Therefore, a magnetic resonance system that is similar to a magnetic induction system but transmits energy in a form of magnetic energy by concentrating energy at a specific resonance frequency by a coil type inductor L and a capacitor C is being developed. Such a magnetic resonance method has the advantage of transmitting a relatively large energy up to a few meters, but it requires a high quality factor. That is, the magnetic resonance method has a disadvantage in that the efficiency is rapidly changed depending on the impedance matching and the resonance frequency coincidence.

In addition, in order to achieve such impedance matching, a large number of capacitors are required, which increases the number of parts and complicates the control program.

In the impedance matching of a wireless power transmission system, the wireless power receiving apparatus is provided with a part thereof so as to improve the control efficiency and simplify the configuration. The present invention can be applied to a wireless communication system capable of transmitting and receiving an inductive power signal and a resonant power signal Power transmission system.

A hybrid radio power transmission device capable of oscillating an inductive power signal and a resonant power signal in order to solve the above problems and a wireless power receiving device capable of receiving a power signal from the hybrid radio power transmission device The hybrid radio power transmission apparatus comprising: a transmission coil configured to oscillate the inductive power signal; A transmission antenna configured to oscillate the resonant power signal; A first variable capacitor block connected to the transmission coil and the transmission antenna; And controlling the first variable capacitor block to perform an inductive main impedance matching when the wireless power receiving apparatus is an inductive power receiving apparatus, wherein the wireless coherent receiving apparatus is a magnetic resonance receiving apparatus And a transmission control unit for controlling the first variable capacitor block to perform a resonance main impedance matching when the transmission antenna is operated, wherein the wireless power reception apparatus further includes: a resonance power signal and an inductive power signal, A receiving block capable of receiving one; A second variable capacitor block connected to the receiving block; And a reception controller for controlling the second variable capacitor block to perform auxiliary impedance matching with the wireless transmission apparatus.

The first variable capacitor block may include: a first main capacitor block connected to the transmission coil; A second main capacitor block connected to the transmission antenna; And a main switching unit for selecting one of the first main capacitor block and the second main capacitor block under the control of the transmission control unit.

Here, the first main capacitor block includes a plurality of main inductive capacitors, an inductive transfer switch connected between the main inductive capacitors and the main inductive capacitors, and the inductive transfer switch being connected between the main inductive capacitors, The transmission switch can be turned on and off to achieve the inductive main impedance matching.

Here, the second main capacitor block may include a plurality of main resonance capacitors, the main resonance capacitors connected in series and in parallel, and a resonance transfer switch disposed between the main resonance capacitors, The transmission switch can be turned on and off to achieve the resonance main impedance matching.

The receiving block includes: a receiving coil for receiving the inductive power signal; And a receiving antenna for receiving the resonant power signal.

Here, the second variable capacitor block may include: a first auxiliary capacitor block connected to the receiving coil; A second auxiliary capacitor block connected to the reception antenna; And an auxiliary switching unit for selecting one of the first auxiliary capacitor block and the second auxiliary capacitor block under the control of the reception control unit.

Here, the first auxiliary capacitor block may include a plurality of auxiliary inductive capacitors and the auxiliary inductive capacitors, which are connected in series and in parallel with each other, and arranged between the auxiliary inductive capacitors, The receiving switch can be turned on and off to achieve the induction auxiliary impedance matching.

Here, the second auxiliary capacitor block includes a plurality of auxiliary resonance capacitors, the auxiliary resonance capacitors connected in series and in parallel, and a resonance receiving switch disposed between the auxiliary resonance capacitors, The reception switch can be turned on and off so that resonance auxiliary impedance matching can be achieved.

In a wireless power transmission system including a wireless power transmission apparatus and a wireless power reception apparatus, which is another embodiment of the present invention, the wireless power transmission apparatus includes: a transmission block for transmitting a wireless power signal; A first variable capacitor block coupled to the transmission block; And a transmission control unit for controlling the first variable capacitor block for main impedance matching when the wireless power receiving apparatus is in a charging position, the wireless network receiving apparatus comprising: a receiving block for receiving the wireless power signal; A second variable capacitor block coupled to the receive block; And a reception controller for controlling the second variable capacitor block to match the transmission block with an auxiliary impedance.

The first variable capacitor block includes a plurality of main capacitors and a transfer switch connected between the main capacitors and the main capacitors in parallel and the transfer control unit switches the transfer switch on and off So that the main impedance matching can be performed.

Here, the second variable capacitor block may include a plurality of auxiliary capacitors, the auxiliary capacitors connected in series and in parallel, and a receiving switch disposed between the auxiliary capacitors, So that the auxiliary impedance matching can be performed.

According to an embodiment of the present invention having the above-described structure, in the impedance matching, the role of the wireless power transmission apparatus and the wireless power receiving apparatus are divided so that the control efficiency for impedance matching can be increased.

Further, by simply combining the capacitance change for impedance matching with the series-parallel circuit and the switch, it is possible to set the capacitance value of various values with a smaller number of capacitors and switches.

1 is a block diagram illustrating an electronic configuration of a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonance power signal, which is one embodiment of the present invention.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonance power signal, which is an embodiment of the present invention, and is a block diagram for explaining an electronic configuration of a hybrid reception apparatus.
3 is a block diagram illustrating an electronic configuration of a first variable capacitor block of a hybrid wireless power transmission apparatus in a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonant power signal according to an embodiment of the present invention.
4 is a block diagram illustrating an electronic configuration of a second variable capacitance block of a hybrid reception apparatus in a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonance power signal according to an embodiment of the present invention.
5 is a circuit diagram of a variable capacitor block of a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonant power signal according to an embodiment of the present invention.

Hereinafter, a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonant power signal according to the present invention will be described in detail with reference to the drawings.

FIG. 1 is a block diagram illustrating an electronic configuration of a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonant power signal, which is one embodiment of the present invention. 1, the wireless power system according to the present invention may be configured with a wireless power transmission apparatus 100 and a wireless power reception apparatus 200. [

The hybrid wireless power transmission apparatus 100 according to the present invention may include a transmission coil 110 and a transmission antenna 120, a first variable capacitor block 130, and a transmission control unit 140, The apparatus 200 may be an inductive power receiving apparatus 201, a magnetic resonance receiving apparatus 202, and a hybrid receiving apparatus 203.

More specifically, the transmission coil 110 is for oscillating an inductive power signal by electromagnetic induction, and the transmission antenna 120 is for oscillating a resonance power signal which is a radio power signal by magnetic resonance will be.

The first variable capacitor block 130 connected to the transmission coil 110 and the transmission antenna 120 may be configured such that the wireless power reception device 200 is connected to the charging position (in the case of an inductive power reception device) (In the case of a resonance receiving apparatus), it is a component for performing an inductive main impedance matching or a resonance main impedance matching for impedance matching with these.

When the inductive power receiving apparatus is placed at the charging position, the transmission control unit 140 operates the transmission coil 110 to control the first variable capacitor block 130 to be the induction main impedance matching, When the magnetic resonance receiver is located at the charging distance, the transmission antenna 120 is operated and the first variable capacitor block 130 is controlled to perform the resonance main impedance matching.

Here, the main impedance matching is a meaning corresponding to the auxiliary impedance matching performed in the wireless power receiving apparatus 200, which means that a relatively large capacitance is changed in the impedance matching. The auxiliary impedance matching also means that a relatively small capacitance change in the impedance matching with the transmission block A of the wireless power transmission apparatus 100 in the second variable crawler block 230 of the wireless power receiving apparatus 200 it means.

As described above, when the wireless power receiving apparatus 200 is the inductive power receiving apparatus 201, the wireless power transmitting apparatus 100 is configured to perform the inductive main impedance matching in the first variable capacitor block 130, When the wireless power receiving apparatus 200 is a magnetic resonance receiving apparatus 202, resonance main impedance matching is performed in the first variable capacitor block 130.

According to an embodiment of the present invention having the above-described configuration, not only the receiving apparatus can be charged regardless of whether it is a resonance type or an induction type. Since the impedance matching operation with the receiving apparatus is performed together with the transmitting apparatus and the receiving apparatus, it is possible to reduce the burden on the impedance matching operation on the transmitting apparatus side.

Hereinafter, an electronic configuration of a hybrid receiving apparatus in a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonant power signal, which is one embodiment of the present invention, will be described with reference to FIG.

2 is a block diagram illustrating an electronic configuration of a hybrid receiving apparatus in a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonant power signal according to an embodiment of the present invention. As shown in FIG. 2, the hybrid receiving apparatus 203 may include a receiving block B, a second variable coughpasser block 230, and a receiving control unit 240.

The receiving block B may include a receiving coil 210 and a receiving antenna 220. The reception coil 210 is a component for generating an AC power by an electromagnetic induction method by receiving an inductive power signal as a low frequency signal. The reception antenna 220 receives a resonance power signal as a high frequency signal and receives an AC power signal .

The second variable capacitor block 230 is a component for performing the auxiliary impedance matching. That is, in the impedance matching between the transmission coil 110 of the transmission block A or the transmission antenna 120 and the reception coil 210 or the reception antenna 220, the capacitance is changed for auxiliary impedance matching. Under the control of the reception control unit 240, the capacitance value of the second variable cough suppressor block 230 is changed to a small size (meaning a smaller size than the first variable capacitor block 130) .

Here, the hybrid receiving apparatus 203 will be mainly described, but it should be understood that the present invention is not limited to this and can also be used in an inductive power receiving apparatus and a magnetic resonance receiving apparatus. 2, the receiving coil 210 and the receiving antenna 220 correspond to the inductive power receiving apparatus 201 or the magnetic resonance receiving apparatus 202 when one of the receiving coil 210 and the receiving antenna 220 is removed. In this case, The capacitance of the second variable capacitor block 230 is changed to a small value for impedance matching.

3 and 4 show electronic configurations of the first variable capacitor block 130 of the hybrid radio power transmission apparatus 100 and the second variable crawler block 230 of the radio power reception apparatus 200, .

3 is a block diagram for explaining an electronic configuration of a first variable capacitor block of a hybrid wireless power transmission apparatus in a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonant power signal according to an embodiment of the present invention, 4 is a block diagram illustrating an electronic configuration of a second variable capacitance block of a hybrid reception apparatus in a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonance power signal according to an embodiment of the present invention.

Referring to FIG. 3, the first variable capacitor block 130 may include a first main capacitor block 131, a second main capacitor block 133, and a main switching unit 135. have.

The first main capacitor block 131 is connected to the transmission coil 110 so that a capacitance value is transmitted to the transmission control unit 140 in order to perform an induction main impedance matching, which is an impedance matching between the transmission coil 110 and the reception coil 210. [ As shown in Fig.

The second main capacitor block 133 is connected to the transmission antenna 120 and transmits a capacitance value (relatively large value) in order to achieve resonance main impedance matching, which is an impedance matching between the transmission antenna 120 and the reception antenna 220. [ And is changed under the control of the control unit 140.

The main switching unit 135 transmits an external object detection signal through the transmission block A to the transmission control unit 140 and detects a signal from the corresponding wireless power receiving apparatus 200, It selects one of the first main capacitor block 131 and the second main capacitor block 133 according to the type of the receiving device. That is, the transmission control unit 140 confirms whether the external object is the inductive power receiving apparatus 201 or the magnetic resonance receiving apparatus 202 by using the external object detection signal generated in the transmission block A, The switching unit 235 operates to select a main capacitor block corresponding thereto and transmit the wireless power signal.

Then, in the selected main caretaker block, the capacitance value is changed based on the ID signal of the receiving apparatus for main impedance matching

4, the second variable capacitor block 230 of the hybrid receiving apparatus 203 includes a first auxiliary capacitor block 231, a second auxiliary capacitor block 233, (235).

The first auxiliary capacitor block 231 is connected to the receiving coil 210 and is connected to the receiving control unit 240 in order to achieve an inductive auxiliary impedance matching that is an impedance matching between the transmitting coil 110 and the receiving coil 210. [ As shown in Fig.

The second auxiliary capacitor block 233 is connected to the reception antenna 220 and generates a capacitance value (relatively small value) to achieve a resonance auxiliary impedance matching, which is an impedance matching between the transmission antenna 120 and the reception antenna 220. [ Is changed under the control of the reception control section (240).

When the reception control unit 240 detects an external object detection signal through the transmission block A and identifies the type of the wireless power transmission apparatus 100 according to the detection result, the auxiliary switching unit 235 switches the transmission apparatus 100, And selects one of the first auxiliary capacitor block 231 and the second auxiliary capacitor block 233 according to the type of the first auxiliary capacitor block 231 and the second auxiliary capacitor block 233. That is, the reception control unit 240 confirms whether the transmission apparatus 100 is an inductive power transmission apparatus or a magnetic resonance transmission apparatus by using an external object detection signal generated in the transmission block A, 235 are operated to select an auxiliary capacitor block corresponding thereto, and impedance matching is performed, thereby receiving an optimal wireless power signal.

Hereinafter, the circuit configuration of the variable capacitor block will be described with reference to FIG. 5 is an example that can be applied to the first and second main capacitor blocks, the first and second auxiliary capacitor blocks described in Figs. 1 to 4, and the first and second auxiliary capacitor blocks. In the claims, the capacitor is referred to as a "main capacitor, a main inductive capacitor, a main resonant capacitor, an auxiliary capacitor, an auxiliary inductive capacitor, an auxiliary resonant capacitor" depending on where the variable capacitor block of FIG. 5 is used, , An inductive transmission switch, a resonance transmission switch, a reception switch, an inductive reception switch, a resonance reception switch ".

5 is a circuit diagram of a variable capacitor block of a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonant power signal according to an embodiment of the present invention. 5, a variable capacitor block of a wireless power transmission system capable of transmitting and receiving an inductive power signal and a resonance power signal, which is one embodiment of the present invention, includes a plurality of capacitors C1 to C4 connected in series and And switches S1 and S2 disposed between the capacitors. By configuring as described above, it is possible to combine capacitances of various values with a smaller number of capacitors. As a result, the number of parts is reduced, which contributes to weight reduction and thinning of the product.

According to an embodiment of the present invention having the above-described structure, in the impedance matching, the role of the wireless power transmission apparatus and the wireless power receiving apparatus are divided so that the control efficiency for impedance matching can be increased.

Further, by simply combining the capacitance change for impedance matching with the series-parallel circuit and the switch, it is possible to set the capacitance value of various values with a smaller number of capacitors and switches.

100: Wireless power transmission device (hybrid type)
110: Transfer coil
120: Transmission antenna
A: Transport block
130: first variable capacitor block
131: first main capacitor block
133: second main capacitor block
135: main switching unit
140:
200: Wireless power receiving device
201: Inductive power receiving device
202: magnetic resonance receiver
203: Hybrid receiving device
210: Receive coil
220: receiving antenna
230: second variable capacitor block
231: first auxiliary capacitor block
233: second auxiliary capacitor block
235: auxiliary switching unit
240:
C1, C2, C3, C4: Capacitors
S1, S2: Switch

Claims (11)

A hybrid wireless power transmission system comprising a hybrid wireless power transmission device capable of oscillating an inductive power signal and a resonant power signal, and a wireless power receiving device capable of receiving a power signal from the hybrid wireless power transmission device,
The hybrid radio power transmission apparatus includes:
A transmission coil configured to oscillate the inductive power signal;
A transmission antenna configured to oscillate the resonant power signal;
A first variable capacitor block connected to the transmission coil and the transmission antenna;
Wherein when the wireless power receiving apparatus is an inductive power receiving apparatus, the transmitting coil is operated and the first variable capacitor block is controlled to be an inductive main impedance matching, and when the wireless power receiving apparatus is a magnetic resonance receiving apparatus And a transmission control unit for operating the transmission antenna and controlling the first variable capacitor block to achieve a resonance main impedance matching,
The wireless power receiving apparatus includes:
A receiving block capable of receiving at least one of a resonance power signal and an inductive power signal;
A second variable capacitor block connected to the receiving block; And
And a reception control section for controlling the second variable capacitor block to perform an auxiliary impedance matching with the radio transmission apparatus.
The method according to claim 1,
Wherein the first variable capacitor block comprises:
A first main capacitor block connected to the transmission coil;
A second main capacitor block connected to the transmission antenna; And
And a main switching unit for selecting one of the first main capacitor block and the second main capacitor block under the control of the transmission control unit.
3. The method of claim 2,
Wherein the first main capacitor block comprises:
A plurality of main inductive capacitors, the main inductive capacitors being connected in parallel with each other,
And an inductive transfer switch disposed between the main inductive capacitors,
The transmission control unit,
And turns the inductive transfer switch on and off to achieve the inductive main impedance match.
3. The method of claim 2,
Wherein the second main capacitor block comprises:
A plurality of main resonance capacitors, the main resonance capacitors being connected in parallel with each other,
And a resonance transfer switch disposed between the main resonance capacitors,
The transmission control unit,
And the resonance transfer switch is turned on and off to achieve the resonance main impedance matching.
The method according to claim 1,
The receiving block includes:
A receiving coil for receiving the inductive power signal; And
And a receiving antenna for receiving the resonant power signal.
6. The method of claim 5,
Wherein the second variable capacitor block comprises:
A first auxiliary capacitor block connected to the receiving coil;
A second auxiliary capacitor block connected to the reception antenna; And
And an auxiliary switching unit for selecting one of the first auxiliary capacitor block and the second auxiliary capacitor block under the control of the reception control unit.
The method according to claim 6,
The first auxiliary capacitor block includes:
A plurality of auxiliary induction capacitors, the auxiliary induction capacitors being connected in series and in parallel,
And an inductive receiving switch disposed between the auxiliary inductive capacitors,
The reception control unit,
And turns on and off the inductive receive switch to provide an inductive auxiliary impedance match.
The method according to claim 6,
Wherein the second auxiliary capacitor block comprises:
A plurality of auxiliary resonance capacitors, the auxiliary resonance capacitors being connected in parallel to one another,
And a resonance receiving switch disposed between the auxiliary resonance capacitors,
The reception control unit,
And the resonance receiving switch is turned on and off so that the resonance assistant impedance matching is achieved.
A wireless power transmission system comprising a wireless power transmission device and a wireless power reception device,
The wireless power transmission apparatus includes:
A transmission block for transmitting a wireless power signal;
A first variable capacitor block coupled to the transmission block; And
And a transmission control unit for controlling the first variable capacitor block for main impedance matching when the wireless power receiving apparatus is in a charging position,
The wireless power receiving apparatus includes:
A receiving block for receiving the wireless power signal;
A second variable capacitor block coupled to the receive block; And
And a reception control section that controls the second variable capacitor block to match the transmission block with an auxiliary impedance.
10. The method of claim 9,
Wherein the first variable capacitor block comprises:
A plurality of main capacitors, and the main capacitors are connected in series and in parallel,
And a transfer switch disposed between the main capacitors,
And the transmission control unit turns the transmission switch on and off to achieve the main impedance matching.
10. The method of claim 9,
Wherein the second variable capacitor block comprises:
A plurality of auxiliary capacitors, the auxiliary capacitors are connected in parallel to one another,
And a receiving switch disposed between the auxiliary capacitors,
The reception control unit,
And turns the receiving switch on and off to achieve the auxiliary impedance matching.

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