KR20190030820A - Wireless power transmission device - Google Patents

Abstract

Provided are a wireless power transmission system which minimizes an increase in a vehicle weight by wirelessly supplying power to auxiliary devices installed in a vehicle, and prevents a foreign substance from being introduced. The wireless power transmission system comprises: a wireless power transmission device mounted in a first rear lamp, and wirelessly transmitting power; and a wireless power receiving device mounted in a second rear lamp, and receiving wireless power transmitted from the wireless power transmission device. The wireless power transmission device and the wireless power receiving device transmit and receive private wireless power with a transmission coil and a receiving coil.

Description

[0001] WIRELESS POWER TRANSMISSION DEVICE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless power transmission system, and more particularly, to a wireless power transmission system installed in a vehicle for wirelessly supplying power to a lighting apparatus.

Various auxiliary devices such as a lighting device, a mirror device, and the like are mounted outside the vehicle to assist the vehicle.

The lighting device is a device for securing the visibility of the driver and informing the surrounding drivers of the presence and condition of the vehicle. Typical lighting devices include a head lamp for securing the front view of the driver, and a rear lamp for informing the presence and the state of the vehicle behind.

The mirror device is a device for allowing the driver to grasp the surrounding situation without a large movement of the visual field. A typical mirror device is a side mirror.

The auxiliary devices installed in the vehicle are connected to the battery through a plurality of connectors and electric wires, and operate by supplying electric power through wires. A number of wiring and fastening members are mounted on the vehicle to supply power to the auxiliary devices by wire.

The vehicle has a problem in that the weight of the vehicle increases due to the mounting of wiring and fastening members for supplying power to the auxiliary devices.

In addition, the vehicle has a problem in that the space in the vehicle becomes narrow due to the mounting of a large number of wiring and fastening members, thereby deteriorating productivity in manufacturing.

In addition, since the auxiliary devices of the wired electric power supply system are mounted on the vehicle, holes for inserting or extending the electric wire are formed, and foreign matter such as dust, worms, Or the performance is deteriorated.

In particular, the auxiliary device may cause corrosion, short-circuit, fire or the like when water is introduced through the holes formed in the vehicle, and therefore sealing (waterproofing) work must be further carried out when mounting the vehicle.

Korean Patent No. 10-1734564

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above problems of the related art, and provides a wireless power transmission system for wirelessly supplying electric power to auxiliary devices installed in a vehicle, minimizing an increase in car weight, .

According to an aspect of the present invention, there is provided a wireless power transmission system including: a wireless power transmission apparatus mounted on a first rear lamp and transmitting wireless power; And a wireless power receiving device mounted on the second rear lamp and receiving the wireless power transmitted from the wireless power transmission device, wherein the wireless power transmission device and the wireless power receiving device are connected to a transmission coil and a reception coil, Lt; / RTI >

According to an aspect of the present invention, there is provided a wireless power transmission apparatus including an auxiliary power module to be charged through power applied when a first rear lamp is turned on, An inverter for wirelessly transmitting power, a transmission control module for driving power to the inverter when power is supplied from the auxiliary power module, detecting a lighting signal of the first rear lamp, and a lighting signal detected by the transmission control module to a wireless power receiving device And a communication module for transmitting the data.

According to an aspect of the present invention, there is provided a wireless power receiving apparatus including a rectifying module for rectifying power transmitted from a wireless power transmission apparatus through a receiving coil, an auxiliary power module A communication module for receiving a lighting signal from the wireless power transmission device, a converter module for converting power rectified by the rectification module and supplying power to the second rear lamp, and a communication module and a converter module when power is supplied from the auxiliary power module And a reception control module for controlling the second rear lamp based on the lighting signal received by the communication module.

According to the present invention, a wireless power transmission system can supply power to a plurality of lamps by using one wireless power transmission circuit.

Also, since the wireless power transmission system uses one wireless power transmission circuit, the wireless power transmission system has only one wireless power transmission coil, thereby minimizing the transmission area.

In addition, the wireless power transmission system can supply power to a plurality of lamps by using a single coil, thereby minimizing the manufacturing cost, the assembling process and the weight.

In addition, the wireless power transmission system minimizes the generation of the delay time by supplying power to the transmission control module and the reception control module in the auxiliary power module, thereby minimizing the difference in the lighting speed between the first rear lamp and the second rear lamp have.

In addition, the wireless power transmission system minimizes the occurrence of a delay time to minimize the difference in lighting speed between the first rear lamp and the second rear lamp, thereby preventing a vehicle accident that may occur due to the rear lamp.

FIG. 1 and FIG. 2 illustrate a wireless power transmission system according to a first embodiment of the present invention; FIG.
3 to 5 are diagrams for explaining a wireless power transmission system according to a second embodiment of the present invention;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to facilitate a person skilled in the art to easily carry out the technical idea of the present invention. . In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The wireless power transmission system according to the first embodiment of the present invention supplies driving power to an auxiliary device such as a lighting device and a mirror device installed in a vehicle through wireless power transmission. A wireless power transmission system includes a wireless power transmission device and a wireless power reception device.

Referring to FIG. 1, a wireless power transmission system according to a first embodiment of the present invention supplies power through a wireless power transmission between a first rear lamp 120 and a second rear lamp 140 installed in a vehicle.

The first rear lamp 120 is installed at the rear of the vehicle body. The first rear lamp 120 is mounted with a wireless power transmission device 220. The wireless power transmission device 220 is connected to the vehicle battery by wire or wirelessly to receive power. The wireless power transmission apparatus 220 wirelessly transmits power in the direction of the second rear lamp 140 while supplying electric power to the first rear lamp 120 and lighting it.

The second rear lamp 140 is installed in the trunk of the vehicle. A wireless power receiving apparatus 240 is mounted on the second rear lamp 140. The wireless power receiving apparatus 240 wirelessly receives the power transmitted from the wireless power transmission apparatus 220 and supplies power to the second rear lamp 140. The second rear lamp 140 is turned on through the power supplied from the wireless power receiving apparatus 240.

Referring to FIG. 2, a wireless power transmission system includes a wireless power transmission device 220 and a wireless power reception device 240.

The wireless power transmission device 220 is mounted on the first rear lamp 120. The wireless power transmission device 220 is mounted at a position close to the second rear lamp 140. The wireless power transmission device 220 is connected to the vehicle's battery either wired or wirelessly. The wireless power transmission apparatus 220 wirelessly transmits the power supplied through the battery to the second rear lamp 140.

The wireless power transmission device 220 includes a power combining module 222, a power transmitting module 224, a transmitting coil 226 and a first communication module 228.

The power combining module 222 is connected to a plurality of first lamps constituting the first rear lamp 120. The power coupling module 222 detects whether the first rear lamp 120 is powered on. When power supply is detected in at least one of the plurality of first lamps, the power combining module 222 combines (sum) the powers applied to the plurality of first lamps. The power combining module 222 transmits the combined power to the power transmitting module 224.

The power transmission module 224 transmits the power received from the power coupling module 222 to the wireless power receiving device 240. The power transmission module 224 transmits power through one transmission coil 226.

The power transmitting module 224 senses a lighting signal for a plurality of first lamps at the front end of the power combining module 222. [ The power transmission module 224 transmits the sensed light signal to the first communication module 228.

The first communication module 228 transmits a light signal received from the power transmission module 224 to the wireless power receiving device 240.

The wireless power receiving apparatus 240 is mounted on the second rear lamp 140. The wireless power receiving apparatus 240 is mounted at a position close to the first rear lamp 120. The wireless power receiving apparatus 240 receives the wirelessly transmitted power from the wireless power transmission apparatus 220. The wireless power receiving apparatus 240 lights up the second rear lamp 140. [

The wireless power receiving device 240 includes a power receiving module 242, a second communication module 246, and a lamp driver module 248.

The power receiving module 242 receives wireless power from the wireless power transmission device 220. The power receiving module 242 receives the wirelessly transmitted power from the power transmission module 224 of the wireless power transmission device 220. The power receiving module 242 receives the wirelessly transmitted power from the power transmitting module 224 via one receiving coil 244. The power receiving module 242 does not transmit the received power to the lamp driver module 248 but keeps it in the standby state.

The power receiving module 242 controls the lamp driver based on the lighting signal transmitted from the second communication module 246. The power receiving module 242 analyzes the lighting signal and detects the lighting object.

The power receiving module 242 controls the switching of the lamp driver module 248 based on the object to be lit. The power receiving module 242 generates and transmits a switching control signal to the lamp driver module 248 to supply power to the object to be lit.

The second communication module 246 receives a light signal from the wireless power transmission device 220. The second communication module 246 transmits the received light signal to the power receiving module 242. [

The lamp driver module 248 supplies power to the second rear lamp 140 under the control of the power receiving module 242. The lamp driver module 248 is constituted by a switching circuit. The lamp driver module 248 is connected to a plurality of second lamps constituting the second rear lamp 140.

The lamp driver module 248 receives the switching control signal from the power receiving module 242. The lamp driver module 248 performs switching operation based on the switching control signal to supply power to at least one of the plurality of second lamps to be lit. The lamp driver module 248 supplies the power supplied from the power receiving module 242 to the second lamp.

As described above, the wireless power transmission system has an effect of supplying power to a plurality of lamps by using one wireless power transmission circuit.

In addition, since the wireless power transmission system uses one wireless power transmission circuit, it is constituted by only one wireless power transmission coil 226, thereby minimizing the transmission area.

In addition, the wireless power transmission system can supply power to a plurality of lamps by using a single coil, thereby minimizing the manufacturing cost, the assembling process and the weight.

1 and 2, the wireless power transmission system is applied to a rear lamp. However, the present invention is not limited to this, and it is applicable to an auxiliary apparatus mounted on a vehicle that requires power supply.

In one example, a wireless power transmission system provides power to a side mirror of a vehicle via wireless power transmission.

The vehicle is mounted with the wireless power transmission device 220 on the side where the side mirrors are mounted. The wireless power transmission device 220 is connected to the vehicle battery by wire or wirelessly to receive power. The wireless power transmission device 220 wirelessly transmits power in the side mirror direction.

The side mirrors are installed on the side of the driver's seat of the vehicle and the side of the auxiliary seat. The side mirror can be provided with a motor for driving and an auxiliary turn signal lamp. The wireless power receiving apparatus 240 is mounted on the side mirror. The wireless power receiving apparatus 240 receives the power transmitted from the wireless power transmission apparatus 220 and selectively supplies power to the motor, the auxiliary turn signal lamp.

Generally, a wireless power transmission system performs a status check of a wireless power transmission device and a wireless power reception device during wireless power transmission. The wireless power transmission system performs a status check such as foreign matter detection (FOD) for a time of about 0.5 seconds to 1 second.

The wireless power transmission system does not have a large problem in a delay time of about one second for checking the status of the battery when it is used as a charging load of the battery and a load of the wireless power receiving apparatus.

However, a wireless power transmission system can cause a car accident even with a delay of about one second when applied to a device requiring a transmission rate (i.e., fast operation) such as a rear ramp. For example, when a delay time of about one second is generated in the wireless power transmission system, there may occur a lighting speed difference between the first rear lamp and the second rear lamp, and a lighting speed delay such as a brake.

Accordingly, a second embodiment of the present invention proposes a wireless power transmission system for minimizing a delay time between a wireless power transmission apparatus and a wireless power reception apparatus.

The operation of a general wireless power transmission system will be described with reference to FIG.

The wireless power transmission device 320 includes a transmission control module 322, an inverter module 324, a transmission coil 326, and a first communication module 328.

The transmission control module 322 is driven by power when the rear lamp is turned on. The transmission control module 322 drives the inverter module 324 together with the drive.

The inverter module 324 is driven by the transmission control module 322 to wirelessly transmit power applied from the battery for lighting the rear lamp. The inverter module 324 wirelessly transmits power to the wireless power receiving apparatus 340 through the transmission coil 326. [

At the same time, the transmission control module 322 drives the first communication module 328. The transmission control module 322 transmits a lighting signal of the rear lamp to the first communication module 328. [

The first communication module 328 transmits a light signal received from the transmission control module 322 to the second communication module 344. [ The first communication module 328 repeatedly transmits the lighting signal until it receives the response signal from the second communication module 344. [

The wireless power receiving apparatus 340 includes a receiving coil 341, a rectifying module 342, a receiving control module 343, a second communication module 344, a converter module 345 and a lamp driver module 346 .

The receiving coil 341 receives the wireless power transmitted through the transmitting coil. The rectifying module 342 rectifies the received radio power through the receiving coil 341 and supplies it to the receiving control module 343 and the converter module 345.

The reception control module 343 is driven by the power supplied through the rectification module 342. [ The reception control module 343 drives the second communication module 344 together with the driving.

The second communication module 344 receives a lighting signal from the first communication module 328. The second communication module 344 transmits the received light signal to the reception control module 343. The second communication module 344 transmits a response signal to the first communication module 328 in response to the lighting signal.

The reception control module 343 drives the converter module 345 and the lamp driver module 346 based on the lighting signal received from the second communication module 344. [

Converter module 345 converts the voltage of the rectified power (i.e., DC power) in rectifier module 342 and supplies it to lamp driver module 346.

The lamp driver module 346 supplies the power supplied from the converter module 345 to the rear lamp. The lamp driver module 346 switches at least one of a plurality of lamps (for example, Stop, TURN, TAIL, B / UP) constituting a rear lamp by switching on the basis of the lighting signal received from the reception control module 343 Power is supplied to light up.

As described above, the wireless power transmission system performs the wireless power transmission after the wireless power receiving apparatus 340 is driven by the power supplied from the wireless power transmission apparatus 320.

In the wireless power transmission system, a delay time occurs until the converter module 345 and the lamp driver circuit are driven after the reception control module 343 is driven in the wireless power receiving apparatus 340. [

In addition, in the wireless power transmission system, when applied to a turn signal lamp, a delay occurs between the first rear lamp 120 and the second rear lamp 140 at each blinking, resulting in a difference in lighting speed.

The wireless power transmission system according to the second embodiment of the present invention is configured such that the transmission control module 322 of the wireless power transmission apparatus 320 and the reception of the wireless power reception apparatus 340 An auxiliary power module (for example, a condenser, a supercap, etc.) is connected to the control module 343.

Referring to FIGS. 4 and 5, the wireless power transmission system according to the second embodiment of the present invention includes a wireless power transmission apparatus 320 including an auxiliary power module and a wireless power receiving apparatus 340.

The wireless power transmission device 320 includes a first auxiliary power module 329, a transmission control module 322, an inverter module 324, a transmission coil 326 and a first communication module 328.

The first auxiliary power module 329 is charged by the power applied when the first rear lamp 120 is turned on. The first auxiliary power module 329 is composed of a capacitor or a supercap capable of supplying power to the transmission control module 322 for a time of about 350 ms.

The first auxiliary power module 329 supplies the charged power to the transmission control module 322. The first auxiliary power module 329 maintains the transmission control module 322 in a driving state for a period of time during which the first rear lamp 120 is repeatedly blinked.

The transmission control module 322 is driven by power when the first rear lamp 120 is turned on. And is driven by the power supplied from the first auxiliary power module 329. The transmission control module 322 drives the inverter module 324 together with the drive.

The inverter module 324 is driven by the transmission control module 322 to wirelessly transmit power applied from the battery for lighting the first rear lamp 120. [ The inverter module 324 wirelessly transmits power to the wireless power receiving apparatus 340 through the transmission coil 326. [

At the same time, the transmission control module 322 drives the first communication module 328. The transmission control module 322 transmits a lighting signal of the rear lamp to the first communication module 328. [

The first communication module 328 transmits a light signal received from the transmission control module 322 to the second communication module 344. [ The first communication module 328 repeatedly transmits the lighting signal until it receives the response signal from the second communication module 344. [

The wireless power receiving apparatus 340 includes a receiving coil 341, a rectifying module 342, a second auxiliary power module 347, a receiving control module 343, a second communication module 344, a converter module 345, And a lamp driver module 346.

The receiving coil 341 receives the wireless power transmitted through the transmitting coil. The rectifying module 342 rectifies the received radio power through the receiving coil 341 and supplies it to the receiving control module 343 and the converter module 345.

The second auxiliary power module 347 is charged by the power supplied through the rectifying module 342. [ The second auxiliary power module 347 is constituted by a capacitor or a supercap capable of supplying power to the reception control module 343 for a time of approximately 350 ms.

And the second auxiliary power module 347 supplies the charged power to the reception control module 343. [ The second auxiliary power module 347 keeps the reception control module 343 in a driving state for a period of time in which the blinking of the rear lamp is repeated.

The reception control module 343 is driven by the power supplied through the second auxiliary power module 347. [ The reception control module 343 drives the second communication module 344 together with the driving.

The second communication module 344 receives a lighting signal from the first communication module 328. The second communication module 344 transmits the received light signal to the reception control module 343. The second communication module 344 transmits a response signal to the first communication module 328 in response to the lighting signal.

The reception control module 343 drives the converter module 345 and the lamp driver module 346 based on the lighting signal received from the second communication module 344. [

Converter module 345 converts the voltage of the rectified power (i.e., DC power) in rectifier module 342 and supplies it to lamp driver module 346.

The lamp driver module 346 supplies the power supplied from the converter module 345 to the second rear lamp 140. The lamp driver module 346 switches a plurality of lamps (for example, Stop, TURN, TAIL, B / W) constituting the second rear lamp 140 based on the lighting signal received from the reception control module 343, UP) to turn on the power.

As described above, in the wireless power transmission system, by supplying power to the transmission control module and the reception control module in the auxiliary power module, the occurrence of the delay time can be minimized to minimize the difference in the lighting speed between the first rear lamp and the second rear lamp have.

In addition, the wireless power transmission system minimizes the occurrence of a delay time and minimizes the difference in lighting speed between the first rear lamp and the second rear lamp, thereby preventing a vehicle accident that may occur due to the rear lamp.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but many variations and modifications may be made without departing from the scope of the present invention. It will be understood that the invention may be practiced.

120: first rear lamp 140: second rear lamp
220: wireless power transmission device 222: power coupling module
224: power transmission module 226: transmission coil
228: first communication module 240: wireless power receiving device
242: power receiving module 244: receiving coil
246: second communication module 248: lamp driver module
320: wireless power transmission device 322: transmission control module
324: inverter module 326: transfer coil
328: first communication module 329: first auxiliary power module
340: wireless power receiving device 341: receiving coil
342: rectification module 343: reception control module
344: second communication module 345: converter module
346: Lamp driver module 347 ': Second auxiliary power module

Claims (9)

1. A wireless power transmission system installed in a vehicle having a first rear lamp and a second rear lamp,
A wireless power transmission device mounted on the first rear lamp and transmitting wireless power; And
And a wireless power receiving device mounted on the second rear lamp and receiving wireless power transmitted from the wireless power transmission device,
Wherein the wireless power transmission device and the wireless power reception device transmit and receive private wireless power to and from one transmission coil and a reception coil. The method according to claim 1,
The wireless power transmission apparatus includes:
A power coupling module for detecting whether power is supplied to the first rear lamp, and for coupling power supplied to the first rear lamp;
A power transmission module for wirelessly transmitting the combined power from the power coupling module via one transmission coil and detecting a lighting signal of the first rear lamp; And
And a first communication module for transmitting a light signal detected by the power transmission module to the wireless power receiving device. The method according to claim 1,
The wireless power receiving apparatus includes:
A power receiving module receiving the wireless power transmitted from the wireless power transmission apparatus through one receiving coil; And
And a second communication module for receiving a lighting signal from the wireless power transmission device,
And the power receiving module supplies the wireless power received through the receiving coil to the second rear lamp upon receiving the turn-on signal from the second communication module. A wireless power transmission apparatus for wirelessly transmitting power to a wireless power receiving apparatus installed in a first rear lamp and installed in a second rear lamp,
An auxiliary power module to be charged through electric power applied when the first rear lamp is turned on;
An inverter for wirelessly transmitting power applied when the first rear lamp is turned on through a transmission coil;
A transmission control module that drives power to the inverter when power is supplied from the auxiliary power module and detects a lighting signal of the first rear lamp; And
And a communication module for transmitting the light signal detected by the transmission control module to the wireless power receiving device. 5. The method of claim 4,
Wherein the auxiliary power module maintains the transmission control module in a driving state for a period of time during which the blinking of the first rear lamp is repeated, 5. The method of claim 4,
The auxiliary power module includes a capacitor A wireless power receiving apparatus for receiving wirelessly transmitted power from a wireless power transmission apparatus installed in a second rear lamp and installed in a first rear lamp,
A rectification module for rectifying the power transmitted from the wireless power transmission device through the reception coil;
An auxiliary power module that is charged by the rectified power in the rectifying module;
A communication module for receiving a lighting signal from the wireless power transmission device;
A converter module for converting power rectified by the rectifier module and supplying power to the second rear lamp; And
And a reception control module for driving the communication module and the converter module when electric power is supplied from the auxiliary power module, and for controlling the second rear lamp based on a lighting signal received by the communication module. 8. The method of claim 7,
Wherein the auxiliary power module maintains the reception control module in a driving state for a period of time during which the second rear lamp repeatedly flashes. 8. The method of claim 7,
Wherein the auxiliary power module is a capacitor.

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