WO2015122611A1 - Wireless charging apparatus - Google Patents

Abstract

Disclosed is a wireless charging apparatus. The wireless charging apparatus according to an embodiment of the present invention comprises: a portable device housing unit for receiving a portable device; and a wireless charging unit for wirelessly charging a portable device, wherein at least one surface of the portable device housing unit includes an electromagnetic wave shielding means or is made from an electromagnetic wave shielding material, thereby preventing an electromagnetic wave generated in the wireless charging unit from going outside.

Description

Wireless charging device

Embodiments of the present invention relate to charging technology, and more particularly to a wireless charging device.

Recently, a variety of portable devices, such as smart phones, portable multimedia players (PMPs), digital cameras, notebook computers, tablet PCs, etc., satisfying user's demands for mobility and portability have been used. In general, mobile devices have a built-in battery and recharge the battery when the battery is discharged. Here, a technology for wirelessly charging a battery has been developed to maximize the convenience of battery charging. However, since the wireless charging technology charges the battery by transmitting electromagnetic waves (or electromagnetic waves) into the air, the human body may be exposed to the electromagnetic waves.

In addition, the wireless charging method may be largely classified into a magnetic induction method, a magnetic resonance method, and an electromagnetic wave method. In this case, there is a problem in that a plurality of wireless charging devices should be provided according to the wireless charging method applied to the portable device.

In addition, when the mobile device is wirelessly charged, wireless charging is determined according to whether or not the mobile device is located within a predetermined range in the wireless charging device. The distance from the wireless charging device to the portable device varies according to the type and size. On the other hand, in the conventional wireless charging device, since the charging module is fixed at a specific position to charge the mobile device, the mobile device may not be wirelessly charged properly according to the type and size of the mobile device. In addition, there is no means for fixing the mobile device to a predetermined position during wireless charging, when the external shock occurs or shake occurs, the mobile device is out of position, the wireless charging is not or the wireless charging efficiency is inferior.

[Preceding technical literature]

[Patent Documents]

Korean Patent Publication No. 10-2007-0031002 (2007.03.19)

Korean Utility Model Publication No. 20-2012-0005886 (2012.08.21)

Korea Patent Publication No. 10-2013-0058826 (2013.06.05)

An embodiment of the present invention is to provide a wireless charging device having an electromagnetic shielding function. An embodiment of the present invention is to provide a wireless charging device that can replace the wireless charging module according to the wireless charging method of the portable device. Embodiments of the present invention can correspond to the position of the wireless charging unit and the location of the portable device. To provide a wireless charging device.

An embodiment of the present invention is to provide a wireless charging device that can block the outgoing electromagnetic waves generated from the wireless charging unit and a vehicle having the same. An embodiment of the present invention is to provide a wireless charging device capable of emitting heat generated from the wireless charging unit to the outside and a vehicle having the same. An embodiment of the present invention is to provide a transponder and a base station, a communication method thereof, and a vehicle using the same, so that an operation error does not occur by another communication system. Embodiments of the present invention can improve wireless charging efficiency. A wireless charging module, a wireless charging module deck, and a wireless charging device are provided. Embodiments of the present invention provide a portable device storage device capable of discharging foreign substances introduced into a storage space of a portable device to the outside.

Wireless charging device according to an embodiment of the present invention, the portable device housing for accommodating the portable device; And a wireless charging unit configured to wirelessly charge the portable device, wherein at least one surface of the housing of the portable device includes an electromagnetic shielding means or is made of an electromagnetic shielding material so that electromagnetic waves generated from the wireless charging unit go out. Block it.

Wireless charging device according to an embodiment of the present invention, the housing portion is provided with a space for inserting the portable device therein; A wireless charging unit provided in the housing unit to wirelessly charge the portable device; An electromagnetic shielding shield for shielding electromagnetic waves generated from the wireless charging unit; And a mounting guide unit in which the electromagnetic shielding unit is replaceably mounted according to a wireless power frequency of the wireless charging unit.

A base station according to an embodiment of the present invention includes a base station mounted to a vehicle, the first transmitting unit capable of transmitting a first wakeup signal; A second transmitter capable of transmitting a second wakeup signal; And a controller controlling the first transmitter and the second transmitter to transmit at least one of the first wakeup signal and the second wakeup signal.

According to an embodiment of the present invention, a transponder includes: a transponder for wireless communication with a base station mounted on a vehicle, the transponder comprising: a first receiver configured to receive a first wakeup signal transmitted from the base station; A second receiver configured to receive a second wake-up signal transmitted from the base station; And a transmitter configured to transmit a response signal to the first wakeup signal or the second wakeup signal.

A communication method of a base station according to an embodiment of the present invention includes a communication method of a base station mounted in a vehicle and communicating with a transponder, the base station checking whether a signal transmission event occurs; And when the signal transmission event occurs, transmitting, by the base station, at least one of a first wakeup signal and a second wakeup signal to the transponder according to whether an interference target signal exists.

Wireless charging device according to an embodiment of the present invention, the inlet is provided on one side, the housing portion having a space for accommodating the portable device therein; A wireless charging unit provided in the housing unit, the wireless charging unit configured to wirelessly charge the portable device, and having one surface facing the portable device; And a metal case provided outside the housing and dissipating heat generated from the wireless charging unit.

Wireless charging device according to an embodiment of the present invention, the wireless charging unit for wirelessly charging the portable device by transmitting a wireless power of a predetermined frequency; And a charging control unit controlling a wireless charging operation of the wireless charging unit, wherein the charging control unit restricts the wireless charging operation of the wireless charging unit according to whether an interference target signal is present.

According to an aspect of the present invention, there is provided a wireless charging method comprising: charging a portable device by wirelessly transmitting a wireless power of a predetermined frequency by a wireless charger; Checking, by the charging controller, whether an interference target signal is present; And limiting a wireless charging operation of the wireless charging unit by the charging control unit when the interference target signal exists.

Wireless charger according to an embodiment of the present invention includes a transmission coil for generating a magnetic field; Attenuating device disposed to face the transmitting coil to generate a magnetic field to attenuate the magnetic field exiting the transmitting coil; And a control unit controlling a current supplied to the transmission coil and the damping device.

Wireless charger according to another embodiment of the present invention is a transmission coil for generating a magnetic field; And a damping member disposed to face the transmitting coil to attenuate a magnetic field generated in the transmitting coil, wherein the attenuating member includes a core, a protrusion protruding from the core, and an exhaust coil wound around the protrusion.

A wireless charging device according to an embodiment of the present invention, a wireless charging device mounted in a vehicle, the first accommodating unit for receiving a first portable device; A second accommodating unit accommodating a second portable device; A wireless charging module configured to wirelessly charge the second portable device by transmitting wireless power of a predetermined frequency; And an accommodation detector configured to detect whether the first portable device is stored, and wherein the wireless charging device transmits from the vehicle to the first portable device when the first portable device is stored in the first housing part. Limit the generation of the signal.

According to another aspect of the present invention, there is provided a wireless charging device, which is a wireless charging device mounted on a vehicle to which a smart key system including a smart key and a base station is applied, and includes: a housing unit accommodating the smart key; A wireless charging module for wirelessly charging a portable device by transmitting wireless power of a predetermined frequency; A storage detecting unit detecting whether the smart key is stored; And a charging controller configured to operate the wireless charging module in a charging normal mode or a charging limit mode according to whether the smart key is stored.

The wireless charging device according to an embodiment of the present invention is a wireless charging device mounted on a vehicle to which a smart key system including a transponder and a base station is applied, and wirelessly charges a portable device by transmitting wireless power of a predetermined frequency. Wireless charging module; A signal detector detecting a first wakeup signal transmitted from the base station; And a signal generator for generating a second wakeup signal by modulating the detected first wakeup signal and transmitting the second wakeup signal to the transponder.

The wireless charging method according to an embodiment of the present invention is a wireless charging method of a wireless charging apparatus mounted on a vehicle to which a smart key system including a transponder and a base station is applied, and the first wake-up transmitted by the base station Detecting a signal; And modulating the detected first wakeup signal to generate a second wakeup signal and transmit the second wakeup signal to the transponder.

A wireless charging method according to another embodiment of the present invention is a wireless charging method of a wireless charging apparatus mounted on a vehicle, the wireless charging method of obtaining at least one of the transmission information of the first low frequency signal and the first low frequency signal transmitted from the vehicle step; And generating and transmitting a second low frequency signal having at least one of a signal strength and a frequency band different from the first low frequency signal.

Wireless charging device according to an embodiment of the present invention, the wireless charging module for wireless charging the portable device; And a wireless charging module deck that accommodates the wireless charging module and to which the wireless charging module is detachably coupled.

In a wireless charging module according to an embodiment of the present invention, in a wireless charging module for wirelessly charging a portable device, the wireless charging module is accommodated in a wireless charging module deck and detachably coupled to the wireless charging module deck.

Wireless charging module deck according to an embodiment of the present invention, the base unit having a receiving groove for receiving the wireless charging module for wireless charging the portable device; And a connector part formed at one side of the receiving groove in the base part and to which the wireless charging module is detachably coupled.

According to an aspect of the present invention, there is provided a portable device housing apparatus comprising: a portable device housing unit in which a portable device is inserted and stored; A wireless charging module formed in the portable device housing and configured to wirelessly charge the portable device; And an opening formed by opening an inner portion of the portable device housing part.

According to an embodiment of the present invention, by providing an electromagnetic shielding function in the wireless charging device that is stored and wirelessly charged by the portable device, it prevents the electromagnetic wave generated in the wireless charging unit from going out of the wireless charging device to affect the human body. You can do it. Further, while charging the portable device, ultraviolet rays or ions are generated inside the portable device housing to sterilize and purify the mobile device. In addition, when the portable device is inserted, the mobile device is fixed to a predetermined position in the portable device housing through the position fixing unit, so that the portable device does not depart from the predetermined position even when there is an external shock or vibration. In addition, by guiding the portable device to the position of the wireless charging unit when the portable device is inserted, it is possible to wirelessly charge the portable devices of various sizes and models through one wireless charging unit, it is possible to maintain a constant level of wireless charging efficiency . In addition, the through-hole structure in communication with the outside inside the mobile device housing unit, by discharging the foreign matter introduced into the inside of the mobile device housing to the outside to prevent the accumulation of foreign matter inside the mobile device housing unit, generated in the wireless charging unit It becomes possible to dissipate heat. In addition, by detachably attaching the wireless charging module to the wireless charging module deck, it is possible to replace the wireless charging module of the wireless charging method corresponding to the wireless charging module deck according to the wireless charging method of the portable device. In this case, various wireless charging portable devices can be charged through one wireless charging device.

1 is a view showing a wireless charging device according to a first embodiment of the present invention, Figure 2 is a view showing a state in which the wireless charging device according to the first embodiment of the present invention mounted on a structure, Figure 3 is In the wireless charging device according to the first embodiment, an opening is formed in the rear end of the wireless charging device

4 is a view illustrating a state in which a mobile device is fixed through a position fixing unit formed in an entrance cover in the wireless charging device according to the first embodiment of the present invention, and FIG. 5 is a wireless charging according to the first embodiment of the present invention. 6 is a side cross-sectional view showing a wireless charging device according to a second embodiment of the present invention.

7 is a plan view showing a wireless charging device according to a second embodiment of the present invention, Figure 8 is a front view showing a wireless charging device according to a second embodiment of the present invention, Figure 9 is a second embodiment of the present invention In the wireless charging device, any one of a plurality of wireless charging module is a view showing a state mounted to the wireless charging module deck

10 is a view showing a state in which a portable device guide unit is formed in the wireless charging device according to the second embodiment of the present invention, and FIG. 11 is a wireless charging module wirelessly charging in the wireless charging device according to the second embodiment of the present invention. 12 is a view illustrating a state of being moved within a module deck, FIG. 12 is a view illustrating a state where an insertion depth of a wireless charging module is adjusted in a wireless charging device according to a second embodiment of the present invention.

FIG. 13 is a view illustrating a state in which an electrical connection between a wireless charging module and a wireless charging module deck is maintained in the wireless charging device according to the second embodiment of the present invention. FIG. 14 is a wireless charging according to the second embodiment of the present invention. FIG. 15 is a view illustrating another embodiment in which an electrical connection is maintained between a wireless charging module and a wireless charging module deck. FIG. 15 illustrates a state in which a plurality of power transmitters are formed in the wireless charging device according to the second embodiment of the present invention. Drawing shown

FIG. 16 is a diagram illustrating a state in which a portable device is guided and fixed to a plurality of power transmitters in a wireless charging apparatus according to a second embodiment of the present invention, and FIG. 17 illustrates a wireless charging apparatus according to an embodiment of the present invention. 18 is a diagram illustrating a wireless charging device according to another embodiment of the present invention.

19 is a perspective view showing a wireless charging device according to an embodiment of the present invention, Figure 20 is a view showing a state in which the electromagnetic shield is mounted on the mounting case according to an embodiment of the present invention, Figure 21 is another embodiment of the present invention Drawing showing the electromagnetic shield is mounted on the mounting case according to the

22 is a view showing a smart key system according to an embodiment of the present invention, FIG. 23 is a diagram schematically showing a base station according to an embodiment of the present invention, Figure 24 is a smart key according to an embodiment of the present invention Flowchart showing communication method of system

FIG. 25 is a view illustrating a state in which a wireless charging device is mounted on a structure according to another embodiment of the present invention. FIG. 26 is a view illustrating an inner pocket in a housing part of the wireless charging device according to an embodiment of the present invention. 27 is a perspective view illustrating a wireless charging device according to an embodiment of the present invention.

28 is a view showing the configuration of a wireless charging apparatus according to an embodiment of the present invention, FIG. 29 is a flowchart showing a wireless charging method according to an embodiment of the present invention, and FIG. 30 is a wireless diagram according to an embodiment of the present invention. Schematic drawing of a charging device

FIG. 31 is a schematic block diagram of a wireless charging device according to an embodiment of the present invention, FIG. 32 is a perspective view schematically showing a connection relationship between attenuation coil and a transmission coil, and FIG. 33 is a diagram of a transmission coil, a reception coil, and a damping coil. Side view schematically showing positional relationships

34 is a perspective view of the damping member, FIG. 35 is a view illustrating a state in which a wireless charging device is mounted in a vehicle, and FIG. 36 is a view illustrating a configuration of a wireless charging device according to an embodiment of the present invention. Block diagram

37 is a view illustrating a state in which any one of a plurality of wireless charging modules is mounted to a wireless charging device in the wireless charging device according to an embodiment of the present invention, and FIG. 38 is a wireless charging method according to an embodiment of the present invention. 39 is a flowchart illustrating a smart key system to which a wireless charging device is applied according to an embodiment of the present invention.

40 is a view showing the configuration of a wireless charging device according to an embodiment of the present invention, FIG. 41 is a flowchart showing a wireless charging method according to an embodiment of the present invention, and FIG. 42 is a wireless view according to the first embodiment of the present invention. Side cross section showing charging device

43 is a plan view showing a wireless charging device according to a first embodiment of the present invention, Figure 44 is a front view showing a wireless charging device according to a first embodiment of the present invention, Figure 45 is a wireless according to an embodiment of the present invention Drawing showing a state where the portable device guide portion is formed in the charging device

46 is a view showing a state in which the wireless charging module is moved within the wireless charging module deck in the wireless charging device according to an embodiment of the present invention, Figure 47 is a wireless charging in the wireless charging device according to an embodiment of the present invention, 48 is a view illustrating a state in which an insertion depth of a module is adjusted. FIG. 48 is a view illustrating a state in which an electrical connection between a wireless charging module and a wireless charging module deck is maintained in a wireless charging device according to an embodiment of the present invention.

49 is a view showing another embodiment in which an electrical connection between a wireless charging module and a wireless charging module deck is maintained in a wireless charging device according to an embodiment of the present invention. FIG. 50 is a view illustrating a mobile device storage according to an embodiment of the present invention. Fig. 51 is a view showing a device, and Fig. 51 is a view showing a state in which an internal pocket is drawn out of a portable device storage device according to an embodiment of the present invention.

52 is a view showing another embodiment of the stopper unit in the mobile device accommodating device according to an embodiment of the present invention; FIG. 53 is a perspective view showing the mobile device accommodating device according to an embodiment of the present invention; FIG. A diagram showing a mobile device accommodating device according to another embodiment

Hereinafter, a wireless charging device of the present invention will be described in detail with reference to the accompanying drawings. However, this is only an exemplary embodiment and the present invention is not limited thereto.

In the following description of the present invention, terms to be described below are defined in consideration of functions in the present invention, which may vary according to intention or custom of a user or an operator. The definition should be made based on the contents throughout the specification.

FIG. 1A is a view showing a state before the portable device is stored, and FIG. 1B is a view showing the state where the portable device is accommodated. The wireless charging device 100 is a portable device housing unit 102. ), An electromagnetic wave shielding unit 104, a wireless charging unit 106, an ion generator 108, an ultraviolet irradiation unit 110, an inlet cover 112, a position fixing unit 114, and an opening 116.

The portable device housing unit 102 includes a storage space S for storing the portable device 50 therein. The portable device 50 may be, for example, a smart phone, a mobile phone, a personal digital assistant (PDA), an MP3, a tablet PC, a portable multimedia player (PMP), or the like, but is not limited thereto. The portable device housing unit 102 may accommodate the whole or a part of the portable device 50. The portable device housing unit 102 serves as a case forming the external shape of the wireless charging device 100. The portable device housing unit 102 may be formed in a hexahedral shape corresponding to the portable device 50, but is not limited thereto. The front end of the portable device housing 102 is open, one side of the portable device housing 102 may be opened to provide an inlet for the portable device 50 is inserted.

A protective pad 118 may be formed on the bottom surface (mounting surface of the mobile device 50) in the portable device housing unit 102. The protective pad 118 serves to protect the portable device 50 from impact and to prevent noise when the portable device 50 is inserted into the portable device housing unit 102 and received therein. The protective pad 118 may serve to prevent the mobile device 50 from sliding in the mobile device housing 102. The protection pad 118 may be formed in an area of the bottom surface of the portable device housing unit 102 except for an area in which the wireless charging unit 106 is formed. When the wireless charging unit 106 is formed on the bottom surface of the portable device housing unit 102, the protection pad 118 is disposed in an area except for the area where the wireless charging unit 106 is formed in order to prevent the wireless charging efficiency from deteriorating. Can be formed. The protective pad 118 or the protrusion may be made of a rubber member or a material such as urethane or silicone.

In the mobile device housing 102, a locking portion 109 may protrude from the bottom surface of the mobile device housing 102. The catching part 104 may protrude to the bottom surface of the portable device housing part 102 at a point spaced apart from the rear end of the portable device housing part 102 by a predetermined distance. When the portable device 50 is inserted into the portable device housing unit 102, the rear end of the portable device 50 may be seated while being caught by the locking unit 109.

The electromagnetic shielding part 104 may be formed in the portable device housing part 102. The electromagnetic shielding unit 104 serves to block the electromagnetic waves generated from the wireless charging unit 106 from going out of the wireless charging device 100. The electromagnetic shielding unit 104 may be provided in the form of an electromagnetic shielding sheet. The electromagnetic shielding part 104 may be embedded in the bottom surface of the portable device housing part 102 (the seating surface of the mobile device 50). The electromagnetic shielding unit 104 may be formed under the wireless charging unit 106 in the bottom surface of the portable device housing unit 102. The electromagnetic shielding part 104 may be embedded in the upper surface of the portable device housing part 102 (the surface facing the seating surface of the mobile device 50).

The electromagnetic shield 104 may also be formed on the side and the rear of the portable device housing 102. An electromagnetic shielding portion 104 in the form of an electromagnetic shielding sheet may be formed on the surface of the portable device housing portion 102 (ie, the outer surface and the inner surface of the portable device housing portion 102). The electromagnetic shielding part 104 may be formed by coating the surface of the portable device housing part 102. The electromagnetic shielding part 104 may be provided in the form of an electromagnetic shielding film on the surface of the portable device housing part 102. For example, an electromagnetic shielding material may be printed on the surface of the portable device housing portion 102.

All or a part of the portable device housing 102 may be made of an electromagnetic shielding material without a separate configuration called the electromagnetic shielding 104. The portable device housing unit 102 itself may be made of an electromagnetic shielding material. The entirety of the portable device housing part 102 may be made of an electromagnetic shielding material, or only a part of the portable device housing part 102 may be made of an electromagnetic shielding material. The portable device housing unit 102 may be made of a resin containing an electromagnetic shielding material. The portable device housing unit 102 may be made of a resin containing an electromagnetic wave shielding fiber or an electromagnetic wave shielding powder. The electromagnetic shielding material may be included in the entire area of the portable device housing part 102 or may be included only in some areas. The wireless charging device 100 may be provided with an electromagnetic shielding case (not shown) on the outside of the portable device housing 102. Electromagnetic shielding case (not shown) may be made in whole or in part of the electromagnetic shielding material or may include an electromagnetic shielding material. The electromagnetic shielding part 104 may be provided in a plurality of layered structures inside the portable device housing part 102.

The wireless charging unit 106 is formed in the portable device housing unit 102. The wireless charging unit 106 may be formed on the bottom surface of the portable device housing unit 102. The wireless charging unit 106 may be formed by being exposed to the bottom surface of the portable device housing unit 102 or embedded in the bottom surface. The wireless charging unit 106 may be formed on the upper surface of the portable device housing unit 102. The electromagnetic shielding unit 104 or the electromagnetic shielding material is not interposed between the wireless charging unit 106 and the portable device 50. In the exemplary embodiment of the present invention, the electromagnetic shielding function prevents electromagnetic waves generated from the wireless charging unit 106 from going out of the wireless charging device 100 while preventing the charging of the mobile device 50 from the wireless charging unit 106. To be prepared. For example, when the mobile device 50 is located on one side of the wireless charging unit 106, the electromagnetic shielding unit 104 may be formed on the other side of the wireless charging unit 106 in the portable device housing unit 102. have. A plurality of electromagnetic shields 104 are stacked on a predetermined surface of the portable device housing unit 102 (for example, a surface opposite to a seating surface of the portable device 50 or a mounting surface of the portable device 50). The plurality of electromagnetic shields 104 may be provided spaced apart from each other vertically.

The wireless charging unit 106 may wirelessly transfer energy to charge the battery of the portable device 50. The wireless charging unit 106 includes a power transmitter for radiating wireless power into the air to charge the battery of the portable device 50. As the power transmitter, for example, a charging coil or a radiator may be used. The wireless charging unit 106 may include a charging control unit for controlling the power transmission unit.

The ion generator 108 may be formed inside the other side of the portable device housing unit 102 (ie, the rear end of the portable device housing unit 102). The formation position of the ion generator 108 is not limited to this. Ion generator 108 may generate at least one of an anion and a cation. The ion generator 108 may include a blowing fan (not shown) for blowing the generated ions to the portable device 50 side. The ions generated by the ion generator 108 are discharged into the portable device housing 102 through the air hole 120. The air hole 120 is formed in communication with the storage space S on the other inner wall of the portable device housing 102. Anions and cations generated by the ion generator 108 sterilize and deodorize various bacteria and fungi in the portable device housing 102 to purify the air in the portable device housing 102. Negative ions and positive ions can sterilize the mobile device 50 stored in the mobile device housing unit 102.

The ultraviolet irradiation unit 110 may be formed in the portable device housing unit 102. The ultraviolet irradiation unit 110 serves to sterilize the portable device 50 by irradiating ultraviolet rays into the portable device housing unit 102. The ultraviolet irradiation unit 110 may be formed of, for example, an ultraviolet LED or an ultraviolet lamp. The ultraviolet irradiation unit 110 may operate together with the wireless charging unit 106. While the battery of the portable device 50 is being charged, the portable device 50 can be sterilized. The ultraviolet irradiation unit 110 may operate separately from the wireless charging unit 106.

A photocatalyst (eg, titanium dioxide, zinc oxide, cadmium sulfide, tungsten oxide, etc.) may be coated on the inner surface of the portable device housing 102. When the ultraviolet irradiation unit 110 irradiates ultraviolet rays into the portable device housing unit 102, the photocatalytic material reacts with the ultraviolet rays to generate hydroxy radicals and super oxides having strong oxidizing power. Hydroxy radicals and super oxides oxidize and decompose contaminants in the portable device housing part 102 to sterilize the interior of the portable device housing part 102.

The inlet cover 112 is formed at the inlet of the portable device housing portion 102 (ie, the open front end of the portable device housing portion 102). The inlet cover 112 is formed so that the inlet of the portable device housing part 102 can be opened and closed. The inlet cover 112 may be formed above the inlet of the portable device housing portion 102. However, the present invention is not limited thereto, and the inlet cover 112 may be formed at one side or both sides at the inlet of the portable device housing 102. The inlet cover 112 may be rotatably formed in the portable device housing portion 102 via the hinge 136. Hinge 136 may be a torsion spring used. The hinge 136 may provide an elastic force to the inlet cover 112 in the direction in which the portable device 50 is drawn out. When the portable device 50 is inserted into the portable device housing part 102, the inlet cover 112 may be rotated into the portable device housing part 102 while being pushed by the portable device 50. When the portable device 50 is withdrawn from the portable device housing part 102, the inlet cover 112 is rotated to the inlet side of the portable device housing part 102 to close the inlet of the portable device housing part 102.

 The entirety of the portable device 50 may be inserted into and accommodated in the portable device housing unit 102. The inlet of the portable device housing portion 102 can be closed by the inlet cover 112. An electromagnetic shield 104 may be formed in the inlet cover 112. The electromagnetic waves generated by the wireless charging unit 106 can be prevented from going out of the entrance of the portable device housing unit 102. The inlet cover 112 may have an electromagnetic shielding sheet or an electromagnetic shielding film. Alternatively, the inlet cover 112 may be made of an electromagnetic shielding material or a resin containing an electromagnetic shielding material. The inlet cover 112 may open or close the inlet of the portable device housing unit 102 in a sliding manner.

The position fixing part 114 may be formed in the inlet cover 112. The position fixing part 114 may be formed on a surface of the inlet cover 112 that is exposed to the outside. The position fixing part 114 may be formed at the distal end of the inlet cover 112. When the mobile device 50 is accommodated in the mobile device housing unit 102, the position fixing unit 114 may press the mobile device 50 to fix the mobile device 50. When the portable device 50 is inserted into the portable device housing part 102, the inlet cover 112 is pushed by the portable device 50 and rotates into the portable device housing part 102. The position fixing unit 114 presses the upper surface of the mobile device 50 to fix the mobile device 50 at a predetermined position. The position fixing unit 114 may press the upper surface of the portable device 50 by the elastic force provided by the hinge 136. In order to prevent scratches or the like from occurring in the portable device 50, the position fixing unit 114 may be made of an elastic material (eg, a rubber member or a urethane or sponge). In this way, the inlet cover 112 can function not only to open and close the inlet of the portable device housing part 102 but also to fix the portable device 50 at a predetermined position.

The opening 116 may be formed by opening a portion of the inside of the portable device housing 102. The portable device housing unit 102 may be formed by opening a portion of the inside of the portable device 50 in addition to the inlet through which the portable device 50 is inserted. For example, the opening 116 may be formed by opening a portion of the bottom surface, a portion of the side surface, or a portion of the rear surface of the other side of the portable device housing 102. The formation position of the opening 116 is not limited to this. The opening 116 may serve to discharge foreign substances introduced into the portable device housing unit 102 to the outside. By opening and forming a portion of the inside of the portable device housing part 102, foreign substances introduced into the portable device housing part 102 can be discharged to the outside. When the wireless charging unit 106 is operated, heat is generated in the power transmitter of the wireless charging unit 106. By providing a through structure communicating with the outside through the opening 116, the outside air is introduced into the portable device housing 102 to dissipate heat generated by the wireless charging unit 106. That is, outside air is introduced into the opening 116 to be heat exchanged with the wireless charging unit 106. On the other hand, the wireless charging device 100 may be provided with a separate blowing fan (not shown) for dissipating heat generated by the wireless charging unit 106. The blowing fan (not shown) may cool the heat generated by the wireless charging unit 106 by generating wind into the portable device housing unit 102. Furthermore, an ion generator may be included in the portable device housing to generate ions.

2 is a view showing a state in which the wireless charging device according to the first embodiment of the present invention is mounted on the structure. The wireless charging device 100 may be mounted inside the structure 10. The structure 10 may be a center fascia, console box, glove box, armrest, front door, rear door, dashboard, seat seat cushion bottom, front seat seat back, and the like of the vehicle. The wireless charging device 100 may be mounted on a structure having various other types and forms. For example, the wireless charging device 100 may be mounted on an indoor wall or furniture or an electronic product (eg, a television, a refrigerator, an audio, a washing machine, or the like).

The wireless charging device 100 may be mounted to be inclined downward in the structure 10. The portable device 50 can be prevented from escaping out of the portable device housing part 102. The wireless charging device 100 may be mounted horizontally or vertically in the structure 10. The wireless charging device 100 may be detachably formed in the structure 10. Only the power transmitter of the wireless charging unit 106 may be formed in the portable device housing unit 102, and the charging control unit of the wireless charging unit 106 may be formed in the structure 10.

The foreign substance accommodating part 124 may be formed in the lower portion of the wireless charging device 100 in the structure 10. The foreign substance accommodating part 124 serves to receive the foreign substance discharged from the opening 116. The communication part 122 is formed between the wireless charging device 100 and the foreign matter accommodating part 124. The communication unit 122 is formed while communicating the space in the opening 116 of the wireless charging device 100 and the foreign matter accommodating unit 124. The foreign material accommodating part 124 may be formed to be withdrawn and withdrawn from the structure 10. When the foreign matter storage unit 124 is filled with foreign matter, the foreign matter storage unit 124 may be pulled out and the foreign matter storage unit 124 may be introduced after collecting the foreign matter.

The structure notification unit 126 may be formed in the structure 10. The status notification unit 126 may be formed near the entrance of the wireless charging device 100. The status notification unit 126 may inform at least one of an operating state of the wireless charging device 100 and an incoming state of the portable device 50. The operating state of the wireless charging device 100 may be, for example, a power state of the wireless charging device 100, an operating state of the wireless charging unit 106 (that is, a charging state of the mobile device 50), and the ion generator 108. The operating state, and the operating state of the ultraviolet irradiation unit 110 may be included. The operating state of the wireless charging device 100 is the ON (ON) or OFF (OFF) state of each configuration (for example, the wireless charging unit 106, ion generator 108, ultraviolet irradiation unit 110, etc.) Rather, the operation duration and the progress of the respective components (for example, the charging time and the progress of charging of the portable device 50 through the wireless charging unit 106, the operating time of the ion generator 108, the ultraviolet irradiation unit 110 Sterilization time, etc.). The reception state of the mobile device 50 may be, for example, receiving an incoming signal (ie, when a call is received), receiving a text, receiving an email, and receiving an SNS message (eg, KakaoTalk, Kakao Story, Facebook, etc.). It may include at least one of. The status notification unit 126 may notify at least one of an operation state of the wireless charging apparatus 100 and an incoming state of the portable device 50 by at least one of a screen display and a voice output.

The wireless charging device 100 detects an incoming state of the mobile device 50 (for example, receiving an incoming signal, receiving a text, receiving an email, receiving an SNS message, etc.) and detecting an incoming state which is delivered to the status notification unit 126. It may further include a portion (not shown). An incoming state detection unit (not shown) may detect a radio wave generated when the portable device 50 receives an incoming signal, a text message, an email, an SNS message, or the like, and detect the incoming state of the portable device 50. In this case, the incoming state detection unit (not shown) may be implemented as an antenna for receiving the radio wave. The antenna may receive radio waves in the 800 MHz or 1800 MHz band in the case of 2G communication, and may receive radio waves in the 2100 MHz band in the case of 3G communication. In addition, the antenna may be implemented to receive radio waves in a frequency band (for example, Wi-Fi (2.4 GHz), etc.) used when the mobile device 50 receives an incoming signal, a text, an email, an SNS message, or the like. The incoming state detecting unit (not shown) may be formed in the form of an antenna on the main board of the wireless charging device 100.

In addition, when the wireless charging device 100 is mounted in the vehicle, the wireless charging device 100 notifies the user of whether the portable device 50 is stored when the vehicle is turned off (not shown). It may further include. It is possible to prevent the user from leaving the portable device 50 in the vehicle. The storage state notification unit (not shown) may know whether the portable device 50 is stored through the wireless charging unit 106. The power transmitter of the wireless charging unit 106 transmits a signal to the portable device 50 and determines whether the wireless charging is possible according to the magnitude of the response signal fed back from the portable device 50. The storage state notifying unit (not shown) may know whether the portable device 50 is stored through the response signal of the portable device 50 received by the power transmitter of the wireless charging unit 106. The storage state notification unit (not shown) may know whether the portable device 50 is stored through a separate sensor.

3 is a view illustrating a case in which an opening is formed at a rear end of the wireless charging device in the wireless charging device according to the first embodiment of the present invention. An inlet through which the portable device 50 is inserted may be formed at a front end of the portable device housing part 102, and an opening 116 may be formed at a rear end of the portable device housing part 102.

Both ends of the wireless charging device 100 may be open. An inlet cover 112 may be formed at one end (front end) of the wireless charging device 100, and an opening 116 may be formed at the other end (back end) of the wireless charging device 100. At least one support rib 128 is formed at a rear end of the wireless charging device 100. The support ribs 128 may be formed by connecting the top and bottom surfaces of the wireless charging device 100. The support ribs 128 may be formed by connecting both side surfaces of the wireless charging device 100. The support rib 128 prevents the portable device 50 from falling into the rear end of the wireless charging device 100. The support ribs 128 may be adjusted in consideration of the width of the portable device 50 and the width of the wireless charging device 100. The locking portion 109 may not be formed in the portable device housing 102. A portion of the rear end (back side) of the wireless charging device 100 may be opened to form the opening 116.

The wireless charging device 100 may further include a wired connection unit 130. The wired connection unit 130 may be electrically connected to the main board of the wireless charging device 100. The wired connection unit 130 may be wired to the portable device 50 through a cable (eg, a data cable, a charging cable, a data and charging cable, etc.). The portable device 50 may be wired charged through the wired connection unit 130. The wireless charging device 100 may charge the battery of the portable device 50 by performing wired charging and wireless charging.

4 is a view illustrating a state in which the mobile device is fixed through a position fixing part formed in the inlet cover in the wireless charging device according to the first embodiment of the present invention. 112 may be formed. The inlet cover 112 includes a first inlet cover 112-1 and a second inlet cover 112-2. The first inlet cover 112-1 may be rotatably formed on one side of the front end of the portable device housing 102 through the first hinge 136-1. The second inlet cover 112-2 may be rotatably formed at the other end of the front end of the portable device housing 102 through the second hinge 136-2. The first position fixing part 114-1 may be formed on a surface exposed to the outside of the first inlet cover 112-1. The first position fixing part 114-1 may be formed at the distal end of the first inlet cover 112-1. The second position fixing part 114-2 may be formed on a surface exposed to the outside of the second inlet cover 112-2. The second position fixing part 114-2 may be formed at the distal end of the second inlet cover 112-2. An opening 116 may be formed at the rear end of the portable device housing 102.

When the mobile device 50 is inserted into the mobile device housing 102, the first inlet cover 112-1 and the second inlet cover 112-2 are pushed by the mobile device 50, respectively. The inner portion of the housing 102 is rotated. The first position fixing part 114-1 and the second position fixing part 114-2 press the both sides of the portable device 50 to fix the portable device 50. The first position fixing part 114-1 and the second position fixing part 114-2 are each connected to the portable device 50 by the elastic force provided by the first hinge 136-1 and the second hinge 136-2. You can press on both sides. When the first position fixing part 114-1 and the second position fixing part 114-2 are made of an elastic material, the first position fixing part 114-1 and the second position fixing part 114-2 itself. Both sides of the portable device 50 can be pressed by the elastic force of the.

The inlet cover 112 performs a function of opening and closing the inlet of the portable device housing unit 102 and a function of guiding and fixing the portable device 50 to a predetermined position (or a function of fixing the predetermined position). The function of guiding and fixing 50 to a predetermined position may be performed through a separate configuration from the inlet cover 112. Hereinafter, another structure for fixing the portable device 50 while guiding it to a predetermined position is referred to as a portable device guide unit.

5 is a view illustrating a state where a portable device guide part is formed in the wireless charging device according to the first embodiment of the present invention. The first portable device guide part 132 and the second portable device guide part 134 may be formed in the portable device housing part 102. The first portable device guide part 132 is formed on one inner wall of the portable device housing part 102, and the second portable device guide part 134 is a portable device housing part facing the first portable device guide part 132. It may be formed on the other inner wall of the (102). The first portable device guide part 132 may include a first elastic member 132-1 and a first pressing member 132-2 hinged to the first elastic member 132-1. The second portable device guide unit 134 may include a second elastic member 134-1 and a second pressing member 134-2 hinged to the second elastic member 134-1. The first elastic member 132-1 and the second elastic member 134-1 may be torsion springs.

Referring to FIG. 5B, when the portable device 50 is inserted into the portable device housing part 102, the first portable device guide part 132 and the second portable device guide part 134 may be Both sides of the portable device 50 are pressed to fix the portable device 50 while guiding it to a predetermined position. The position where the portable device 50 is fixed may correspond to the position of the wireless charging unit 106.

The portable device guide part may be formed on one of the inner wall and the other inner wall of the portable device housing 102. A plurality of portable device guide units may be formed on at least one of one inner wall and the other inner wall of the portable device housing 102. The portable device guide may be made of leaf springs.

6 is a side cross-sectional view showing a wireless charging device according to a second embodiment of the present invention, Figure 7 is a plan view showing a wireless charging device according to a second embodiment of the present invention, Figure 8 is a second embodiment of the present invention. The front view which showed the wireless charging device. The wireless charging device 200 includes a wireless charging module 201, a portable device housing 202, and a wireless charging module deck 203. The wireless charging device 200 may be mounted in a vehicle structure. The wireless charging device 200 may be mounted in an indoor structure (eg, furniture, walls, electronic devices, etc.). The wireless charging device 200 may be used independently without being mounted on a separate structure.

The wireless charging module 201 serves to wirelessly charge the portable device 50. The wireless charging module 201 may be stored in the wireless charging module deck 203. The wireless charging module 201 may be detachably coupled with the wireless charging module deck 203. According to the wireless charging method of the portable device 50, the wireless charging module 201 of the wireless charging method corresponding thereto may be exchanged and mounted on the wireless charging module deck 203. For example, when the wireless charging method of the wireless charging module 201 mounted in the wireless charging module deck 203 is a magnetic induction method, and the wireless charging method of the mobile device 50 to be wirelessly charged is a magnetic resonance method. After removing the magnetic induction type wireless charging module 201 from the wireless charging module deck 203, the magnetic resonance type wireless charging module 201 may be interchangeably mounted to the wireless charging module deck 203. In addition, the wireless charging method of the wireless charging module 201 mounted in the wireless charging module deck 203 is a wireless power consortium (WPC) method among magnetic induction methods, and the wireless charging method of the mobile device 50 to be wirelessly charged. Among the magnetic induction methods, in the case of the PMA method, the wireless charging module 201 of the WPC method is detached from the wireless charging module deck 203, and then the wireless charging module 201 of the PMA method is connected to the wireless charging module. The deck 203 can be interchangeably mounted. The wireless charging method of the wireless charging module 201 may be any one of a magnetic induction method (WPC method and PMA method), a magnetic resonance method, and an electromagnetic wave method. The wireless charging scheme of the wireless charging module 201 may be various wireless charging schemes (including wireless charging schemes to be developed in the future).

The wireless charging unit 206 is provided inside the wireless charging module 201. The wireless charging unit 206 may be formed in the charging unit accommodating unit 217 in the module housing unit 211. The wireless charger 206 may include a power transmitter 206-1 and a support 206-2. The power transmitter 206-1 is formed on the support 206-2. The power transmitter 206-1 radiates wireless power to charge the battery of the portable device 50. As the power transmitter 206-1, for example, a charging coil may be used. The power transmitter 206-1 may be formed by winding a charging coil several times. The charging coil may be formed by winding in the shape of an oval or a square. An antenna may be used as the power transmitter 206-1. The supporting unit 206-2 serves to support the power transmitter 206-1. The wireless charging unit 206 may be formed to be movable in at least one of a width direction of the module housing part 211 and a length direction of the module housing part 211. By moving the wireless charging unit 206 according to the size of the mobile device 50 or the position of the mobile device 50 to correspond to the positions of the wireless charging unit 206 and the mobile device 50, the wireless of the mobile device 50 The charging can be performed efficiently.

The module housing part 211 serves as a case of the wireless charging module 201. Depending on the storage space in the wireless charging module deck 203 may be formed in a variety of other shapes. The module housing part 211 may be accommodated in the wireless charging module deck 203. The module housing part 211 may be accommodated by being slide-inserted into the wireless charging module deck 203 from one side of the wireless charging module deck 203. The module housing part 211 may be seated and accommodated in the wireless charging module deck 203 at the upper or lower portion of the wireless charging module deck 203.

The charging unit accommodating part 217 accommodates the wireless charging part 206 in the module housing part 211. The charging unit accommodating unit 217 has an accommodation space in which the wireless charging unit 206 can be stored. The wireless charging unit 206 may be fixedly accommodated in the charging unit accommodation unit 217. The charging unit accommodating part 217 may be formed to be movable in at least one of a width direction of the module housing part 211 and a length direction of the module housing part 211. The wireless charging unit 206 moves together with the charging unit accommodation unit 217. The wireless charging unit 206 may be moved by moving the charging unit accommodation unit 217 in the module housing unit 211.

The charging controller 215 may be formed in the module housing 211. The charging control unit 215 controls the operation of the wireless charging unit 206. The charging controller 215 may be electrically connected to the power transmitter 206-1 through the flexible cable 227. Even if the wireless charging unit 206 moves within the module housing 211, the charging control unit 215 and the power transmission unit 206-1 can be stably connected. The wireless charging module 201 includes a movement adjusting unit 219, The first connector 221, the first guide part 223, and the second guide part 225 may be included.

The movement adjusting part 219 may be coupled to the charging part accommodating part 217 through the front surface of the module housing part 211. The coupling part 217-a may protrude from a side of the charging part accommodating part 217 facing the movement adjusting part 219. One side of the movement adjusting unit 219 may protrude from the front surface of the module housing unit 211 (that is, one side of the module housing unit 211). The other side of the movement adjusting unit 219 may be coupled to the coupling unit 217-a. The other side of the movement adjusting unit 219 may be coupled to the coupling unit 217-a while passing through the coupling unit 217-a. A screw portion 219-a may be formed on the outer circumferential surface of the movement adjusting unit 219. A screw thread corresponding to the screw portion 219-a is formed in the coupling portion 217-a so that the movement adjusting unit 219 and the coupling portion 217-a may be screwed together.

When the user rotates one side of the movement adjusting unit 219 protruding from the front surface of the module housing 211, the engaging portion 217-a of the charging unit accommodating portion 217 is the screw portion 219-a of the movement adjusting unit 219. ) (Ie, along the longitudinal direction of the module housing portion 211). Since the wireless charging unit 206 is accommodated in the charging unit accommodating part 217, the wireless charging unit 206 moves along the longitudinal direction of the module housing part 211 together with the charging part accommodating part 217. The charging unit accommodating part 217 moves back and forth along the rotation direction of one side of the movement adjusting part 219. In the front of the module housing 211, a description of how much and in which direction the movement adjusting unit 219 should be rotated may be displayed according to the type or size of the portable device 50. On one side of the movement adjusting unit 219 protruding from the front surface of the module housing portion 211 and the front surface of the module housing portion 211, reference lines may be displayed so as to check the number of rotations (or the degree of rotation) of the movement adjusting portion 219. Can be.

A movement limiter 219-b may be formed at the end of the movement adjuster 219. When the engaging portion 217-a of the charging portion accommodating portion 217 moves in the rearward direction along the screw portion 219-a, the movement in the rearward direction is restricted by the movement limiting portion 219-b. . The length of the screw portion 219-a is a distance that the charging unit accommodating portion 217 can move in the longitudinal direction of the module housing portion 211. The movement limiting portion 219-b also serves to prevent the coupling portion 217-a from escaping from the screw portion 219-a by restricting the movement in the rearward direction of the coupling portion 217-a. .

The wireless charging unit 206 may be stored in the charging unit accommodating unit 217, and the movement adjusting unit 219 may be directly coupled to the wireless charging unit 206 without the charging unit accommodating unit 217. The screw 219-a of the movement adjusting unit 219 may be screwed with the support 206-2 of the wireless charging unit 206. An insertion hole (not shown) may be formed in the supporting portion 206-2, and an insertion hole (not shown) into which the screw portion 219-a is inserted may be formed, and a thread corresponding to the screw portion 219-a may be formed in the insertion hole (not shown). have. In this case, the wireless charging unit 206 is directly moved by the movement adjusting unit 219.

A guide slit 229 may be formed on the front surface of the module housing 211 along the width direction of the module housing 211. The movement adjuster 219 may move along the guide slit 229 in the width direction of the module housing 211. The charging part accommodating part 217 (and the wireless charging part 206) move together with the movement adjusting part 219 in the width direction of the module housing part 211. On the front surface of the module housing 211, a scale according to the movement distance of the movement adjusting unit 219 is displayed, for example, in cm or mm units, or an identifier according to the type or size of the portable device 50 (that is, the portable device). Identifier indicating how much to move the movement adjustment unit 219 in the width direction according to the model or size of 50) can be displayed. The moving part accommodating part 217 may be moved in the longitudinal direction and the width direction of the module housing part 211 through the movement adjusting part 219, so that the wireless charging part 206 may move the module in the module housing part 211. The housing part 211 can be moved in the longitudinal direction and the width direction. According to the type or size of the mobile device 50, the wireless charging unit 206 is moved to a position where the wireless charging efficiency is maximum (or a position where wireless charging is possible) (that is, a position corresponding to the power receiver of the mobile device 50). You can move it.

The movement adjuster 219 may be operated electronically. For example, the wireless charging unit 206 is automatically moved in the longitudinal direction and the width direction of the module housing part 211 by rotating the movement adjusting part 219 or moving along the guide slit 229 using a motor, a gear, or the like. You can also move it.

The wireless charging device 100 may further include a charging unit location determiner (not shown) capable of confirming the location of the wireless charging unit 206. The charging unit positioning unit (not shown) serves to inform the user of the position of the wireless charging unit 206 in conjunction with the movement operation of the wireless charging unit 206. The charging unit positioning unit (not shown) may include, for example, an illumination (or indicator) formed at the center of the wireless charging unit 206. The module housing part 211 and the base part 241 may be made of a material capable of confirming light generated from the illumination (the light is not visually recognized but the light generated from the illumination is visually recognized). The module housing part 211 and the base part 241 of the portion corresponding to the area where the wireless charging unit 206 is moved are formed and implemented to allow the user to directly check the position of the wireless charging unit 206 with the naked eye. You can also implement The charging unit positioning unit (not shown) may include a protrusion extending upward from the support unit 206-2.

The first connector 221 may be formed on the other side of the module housing 211. The first connector 221 is a portion electrically connected to the wireless charging module deck 203. In the wireless charging module 201, the first connector 221 may be formed at the same position in all of the magnetic induction method, the magnetic resonance method, and the electromagnetic wave method. According to the wireless charging method of the portable device 50, the wireless charging module 201 of the wireless charging method corresponding thereto may be mounted on the wireless charging module deck 203.

The first guide part 223 is formed in the module housing part 211 along the longitudinal direction of the module housing part 211. The first guide part 223 may be formed at both sides of the charging part accommodating part 217. The first guide part 223 may be formed at one side of the charging part accommodating part 217. The first guide part 223 serves to guide the charging part accommodating part 217 to move in the longitudinal direction of the module housing part 211. The charging unit accommodating part 217 moves along the first guide part 223 in the longitudinal direction of the module housing part 211 when the movement adjusting part 219 rotates. The first guide part 223 may be slide coupled to the side surface of the charging part accommodating part 217. The first guide part 223 may be formed to simply support the side surface of the charging part accommodating part 217.

The second guide part 225 is formed along the width direction of the module housing part 211 in the module housing part 211. The second guide part 225 may be formed under the charging part accommodating part 217. The second guide part 225 serves to guide the charging part accommodating part 217 to move in the width direction of the module housing part 211. That is, the charging unit accommodating part 217 moves in the width direction of the module housing part 211 along the second guide part 225 when the movement adjusting part 219 moves along the guide slit 229. The second guide part 225 may be slide-coupled with the lower surface of the charging part accommodating part 217. However, the present invention is not limited thereto, and the second guide part 225 may be formed to simply support the lower surface of the charging part accommodating part 217.

The portable device housing portion 202 is formed on the wireless charging module deck 203. The portable device housing unit 202 has a storage space for storing the portable device 50 therein. The portable device housing unit 202 may accommodate all or a portion of the portable device 50. The portable device housing unit 202 may be formed in a hexahedral shape corresponding to the portable device 50, but is not limited thereto. In addition, the portable device housing unit 202 may be formed in various shapes to accommodate the portable device 50. The front end of the portable device housing portion 102 may be open. In this case, the portable device 50 may be inserted into and received at an open front end of the portable device housing unit 102. A protective pad 218 may be formed on an inner surface of the portable device housing 202.

An inlet cover 212 may be formed at an open front end of the portable device housing 202. The inlet cover 212 may be rotatably formed at the front end of the portable device housing portion 202. The inlet cover 212 may be provided with a position fixing part 214 for pressing and fixing the portable device 50 when the portable device 50 is inserted. The ultraviolet irradiation part 210 may be formed in the portable device housing part 202. An electromagnetic shield 204 may be formed on the top, side, or rear surface of the portable device housing 202. An opening (not shown) may be formed in a portion of the inside of the portable device housing 202. The portable device housing unit 202 has a through structure communicating with the outside through an opening (not shown). In addition, the wired connection unit 230 and the status notification unit 226 may be formed in the portable device housing unit 202. The wired connection unit 230 and the status notification unit 226 may be formed in the wireless charging module deck 203.

The status notification unit 226 may include a display notification unit 226-1 and a voice output notification unit 226-2. The display notification unit 226-1 may display at least one of an operating state of the wireless charging device 100 and an incoming state of the portable device 50 in a visual form. The display notification unit 226-1 may designate and display the operation state of the wireless charging device 100 and the incoming state of the portable device 50. The display notification unit 226-1 includes operations of the power state display unit ⓐ of the wireless charging device 100, the charge state display unit ⓑ (wireless charging and wired charging) of the mobile device 50, and the ultraviolet irradiation unit 210. The status display unit ⓒ and the incoming state display unit ⓓ of the portable device 50 may be designed and formed. The display notification unit 226-1 is in an operating state of the wireless charging device 100 by lighting on a patterned part corresponding to the operating state of the wireless charging device 100 and the incoming state of the portable device 50. And the incoming state of the portable device 50 can be visually displayed. The voice output notifying unit 226-2 may output at least one of an operating state of the wireless charging apparatus 100 and an incoming state of the portable device 50 as voice. The status notification unit 226 may be configured to display an operation state of the wireless charging device 100 and an incoming state of the mobile device 50 through at least one of the display notification unit 226-1 and the voice output notification unit 226-2. You can let them know.

The wireless charging module deck 203 houses the wireless charging module 201. The portable device housing unit 202 and the wireless charging module deck 203 form the overall appearance of the wireless charging device 100. The wireless charging module deck 203 includes a base portion 241. The base part 241 forms a body of the wireless charging module deck 203. The base portion 241 may be formed in a plate shape having a predetermined thickness. The base portion 241 may be formed in the form of a hexahedron such as the portable device 50.

In the base 241, a receiving groove 243 in which the wireless charging module 201 is accommodated is formed. An accommodating groove 243 may be formed in a shape in which the lower portion of the base portion 241 is opened, such that the wireless charging module 201 may be seated in the accommodating groove 243 under the base portion 241. The upper surface of the base portion 241 and the lower surface of the portable device housing portion 202 may be integrally formed.

An electromagnetic shielding portion 204 may be formed on the bottom surface of the base portion 241. The electromagnetic shielding portion 204 may be formed in the form of an electromagnetic shielding sheet and may be embedded in the lower surface of the base portion 241 or formed on the lower surface of the base portion 241. The electromagnetic shield 204 may be formed on the lower surface of the base 241 in the form of an electromagnetic shielding film. The electromagnetic shielding part 204 may be formed on at least one surface of a lower surface, a side surface, and a rear surface of the base portion 241. A portion of the base portion 241 may be made of an electromagnetic shielding material. For example, the remaining portion except for the upper surface of the base portion 241 (that is, the surface existing between the wireless charging unit 206 and the portable device 50) may be made of an electromagnetic shielding material. A portion of the base portion 241 may be made of a resin containing an electromagnetic shielding material. The remaining portion except the upper surface of the base portion 241 may be made of a resin containing an electromagnetic wave shielding fiber or an electromagnetic wave shielding powder.

The second connector 245 may be formed at the other inner side of the base part 241. The second connector 245 is electrically connected to the first connector 221 of the wireless charging module 201. As the wireless charging module 201 is inserted into the receiving groove 243, the first connector 221 and the second connector 245 may be connected. The second connector 245 may be electrically connected to the power supply 261 formed in the base 241. The power supply unit 261 serves to supply power to the wireless charging device 100.

According to the exemplary embodiment of the present invention, the wireless charging module 201 is detachably coupled to the wireless charging module deck 203 so that the wireless charging of the wireless charging method corresponding thereto according to the wireless charging method of the portable device 50 is possible. The module 201 can be interchangeably mounted to the wireless charging module deck 203.

9 is a view showing a state in which any one of the plurality of wireless charging module is mounted on the wireless charging module deck in the wireless charging device according to a second embodiment of the present invention. It is assumed that the first wireless charging module 201-1 is a magnetic induction method, the second wireless charging module 201-2 is a magnetic resonance method, and the third wireless charging module 201-3 is an electromagnetic wave method. The first wireless charging module 201-1 to the third wireless charging module 201-3 become a group of wireless charging module sets that can be mounted to the wireless charging module deck 203. Here, the magnetic induction method is a method using an electromagnetic induction principle in which electricity is induced in the power receiver of the portable device when a magnetic field is generated in the power transmitter of the wireless charging module.

According to the wireless charging method of the portable device 50, any one of the first wireless charging module 201-1, the second wireless charging module 201-2, and the third wireless charging module 201-3 wirelessly charges the wireless charging module. It is inserted into the receiving groove 243 of the module deck 203 is mounted. Any wireless charging is provided by forming the first connector 221 of the first wireless charging module 201-1, the second wireless charging module 201-2, and the third wireless charging module 201-3 in the same position. Although selected, the module may be electrically connected to the wireless charging module deck 203. Each of the first connectors 221 of the first wireless charging module 201-1 to the third wireless charging module 201-3 may have the same size and size.

10 is a view illustrating a state where a portable device guide part is formed in the wireless charging device according to the second embodiment of the present invention. The portable device housing unit 202 may be formed on the wireless charging module deck 203. The portable device housing unit 202 may be formed in a form in which a portion of the portable device 50 is inserted. The first portable device guide part 232 may be formed on one inner wall of the portable device housing part 202, and the second portable device guide part 234 may be formed on the other inner wall of the mobile device housing part 202. The first portable device guide part 232 may include a first elastic member 232-1 and a first pressing member 232-2 hinged to the first elastic member 232-1. The second portable device guide part 234 may include a second elastic member 234-1 and a second pressing member 234-2 hinged to the second elastic member 234-1.

11 is a view showing a state in which the wireless charging module is moved within the wireless charging module deck in the wireless charging device according to a second embodiment of the present invention. The protrusion 281 may be formed in the wireless charging module 201. An uneven portion 285 may be formed in the wireless charging module deck 203 along the insertion direction of the wireless charging module 201. The uneven portion 285 may be formed by protruding a plurality of protrusions in the inner direction of the receiving groove 243. As the wireless charging module 201 is inserted into the wireless charging module deck 203, the protrusion 281 may be engaged with any protrusion of the uneven portion 285. The depth to which the wireless charging module 201 is inserted can be adjusted according to the pressure applied to the wireless charging module 201.

12 is a view showing a state in which the insertion depth of the wireless charging module is adjusted in the wireless charging device according to the second embodiment of the present invention. The uneven portion 285 may be formed at one side or both sides inside the receiving groove 243. A plurality of protrusions 285a may be formed at one side of the uneven portion 285 to protrude inwardly of the receiving groove 243 along the insertion direction of the wireless charging module 201. One end of the protrusion 285a may have a pointed shape, and for example, may be formed of an elastic material. The protrusion 281 is engaged with the uneven portion 285 when the wireless charging module 201 is inserted into the wireless charging module deck 203 to fix the wireless charging module 201, or the uneven portion 285 of the protrusion 281. The wireless charging module 201 is moved while riding over the protrusion 285a.

 The protrusion 281 may include a support member 281a, a protrusion member 281b, an elastic member 281c, and a locking portion 281d. The support member 281a is a body of the protrusion 281, and one end thereof is coupled to one side of the wireless charging module 201. One end of the support member 281a may be hinged (not shown) to one side of the wireless charging module 201 to move in the width direction of the accommodation groove 243 (ie, a↔b direction) (that is, rotate). At the other end of the support member 281a, a protruding member 281b may protrude toward the uneven portion 285. The locking portion 281d may protrude from the other end of the supporting member 281a. An elastic member 281c may be fixed to one side of the support member 281a. One end of the elastic member 281c may be fixed to one side of the support member 281a, and the other end thereof may be fixed to the wireless charging module 201.

The protruding member 281b protrudes toward the uneven portion 285 from the other end of the supporting member 281a. The protruding member 281b may be formed to have a pointed end so as to be engaged with the uneven portion 285. The protruding member 281b may be made of an elastic material.

One end of the uneven portion 285 may be formed to be inclined at a predetermined angle in a direction opposite to the direction in which the protrusion 285a is formed. The protruding portion 281 is positioned at a by the elastic force of the elastic member 281c before the protruding member 281b contacts the protrusion 285a of the uneven portion 285. Thereafter, as the wireless charging module 201 moves in the insertion direction, the protruding member 281b is engaged with the protrusion 285a of the uneven portion 285 or is released from the protrusion 285a by the elastic member 281c. Repeat the process.

In the state where the protruding member 281b is fixed at the g position, when the wireless charging module 201 is subjected to a pressure of a predetermined size or more again, the protruding member 281b leaves the uneven portion 285 and the guide rail 281e. Will move along. The locking portion 281d may penetrate the other end of the supporting member 281a to protrude toward the guide rail 281e. The locking portion 281d may be, for example, a cylindrical shape, but is not limited thereto. Meanwhile, in FIG. 12, the protrusion 281 is spaced apart from the uneven portion 285 by a predetermined distance to move in the inserting direction of the wireless charging module 201. However, this is for convenience of description and the protrusion 281 as described above. Projecting member 281b is actually c, d, e, f... Note that it is fixed while moving to the g position sequentially (the uneven portion 285 is located on the left side than shown).

The guide rail 281e may protrude from the inner wall of the accommodation groove 243 and provide a movement path of the locking portion 281d. The guide rail 281e is formed in the withdrawal direction of the wireless charging module 201. The guide rail 281e may have a width that is several mm wider than the diameter of the locking portion 281d. In a state where the protruding member 281b is fixed at the g position, when the wireless charging module 201 is subjected to a pressure of a predetermined size or more again, the protruding member 281b leaves the uneven portion 285, and the engaging portion 281d ) Enters the inlet of the guide rail 281e, that is, the h position, and then moves along the guide rail 281e in the withdrawal direction of the wireless charging module 201. As shown, the guide rail 281e is formed to be spaced apart from the uneven portion 285 by a predetermined distance, so that when the locking portion 281d moves along the guide rail 281e, it is elastically fixed to one side of the protrusion 281. The member 281c is extended by a predetermined distance. Subsequently, when the locking portion 281d exits the guide rail 281e through the exit of the guide rail 281e, that is, the i position, the protrusion 281 is again at the b position by the elastic force of the elastic member 281c. Return to position As such, when the protrusion 281 returns to the a position, one side of the wireless charging module 201 is exposed to the outside from the wireless charging module deck 203.

12 and 13, the first connector 221 is formed on the other side of the wireless charging module 201. The first connector 221 may be formed to be movable along the guide groove 267 in the guide groove 267 formed in the module housing 211. The guide groove 267 may be formed in the longitudinal direction of the module housing part 211 (that is, the insertion direction of the wireless charging module 201). One side of the first connector 221 may be located in the guide groove 267, and the other side of the first connector 221 may protrude in the direction of the second connector 245 from the wireless charging module 201. One side of the first connector 221 is electrically connected to the charging control unit 215 through the flexible cable 269. An elastic member (not shown) connecting the wireless charging module 201 and the first connector 221 may be formed in the guide groove 267. In this case, the elastic member (not shown) may provide an elastic force to the first connector 221 in the direction of the second connector 245.

When the wireless charging module 201 receives continuous pressure in the insertion direction of the wireless charging module 201, the protruding member 281b moves along the uneven portion 285 to reach the end of the uneven portion 285. Then, the first connector 221 is connected while being inserted into the second connector 245 (Fig. 13 (a)). That is, the first connector 221 may be made of a male connector, and the second connector 245 may be made of a female connector. However, the present invention is not limited thereto and may be formed in reverse. The second connector 245 may be fixed and formed in the wireless charging module deck 203. At this time, the protruding member 281b may be fixed at the g position of the uneven portion 285. In the state where the first connector 221 and the second connector 245 are connected in this way, when the wireless charging module 201 is again subjected to pressure of a predetermined size or more, the protruding member 281b moves along the guide rail 281e. To return to position a. In this case, as the flexible cable 269 is extended, the wireless charging module 201 is drawn out, and one side of the wireless charging module 201 is exposed to the outside from the wireless charging module deck 203 (FIG. 13B). ).

As such, while one side of the wireless charging module 201 is drawn out of the wireless charging module deck 203, the power transmitter of the wireless charging module 201 is adjusted by adjusting the insertion depth of the wireless charging module 201. 206-1) may correspond to the power receiver of the mobile device 50. The charging control unit 215 and the first connector 221 may be integrally formed.

14 is a view showing another embodiment in which the wireless connection between the wireless charging module and the wireless charging module deck is maintained in the wireless charging device according to the second embodiment of the present invention. The first connector 221 is formed at the other side of the wireless charging module 201. The first connector 221 is electrically connected to the charging control unit 215 and may be integrally formed with the charging control unit 215. The connection pattern 221-1 may be formed on the upper side of the first connector 221. The second connector 245 is fixedly formed in the wireless charging module deck 203. An insertion groove 245-1 through which the first connector 221 is inserted is formed in the second connector 245. The connection member 251 may be formed in the second connector 245. The connection member 251 includes a connection support part 251-1 and a contact part 251-2. The connection support part 251-1 may be formed in one direction (that is, the direction in which the wireless charging module 201 is drawn out) from the other side of the second connector 245. The other side of the connection support part 251-1 may be fixed to the other side of the second connector 245. The contact part 251-2 may protrude downward from an end of the connection support part 251-1 (that is, one side of the connection support part 251-1). The contact part 251-2 is a part in contact with the connection pattern 221-1 of the first connector 221.

When the wireless charging module 201 receives continuous pressure in the insertion direction of the wireless charging module 201, the protruding member 281b moves along the uneven portion 285 to reach the end of the uneven portion 285. Then, the first connector 221 is inserted into the insertion groove 245-1 of the second connector 245 and is electrically connected to the second connector 245 through the connection member 251 (FIG. 14 ( a)). The contact part 251-2 is connected to the connection pattern 221-1 from the other side to the one side of the connection pattern 221-1 as the first connector 221 is inserted into the insertion groove 245-1. (221-1). In the state where the first connector 221 and the second connector 245 are connected in this way, when the wireless charging module 201 is again subjected to pressure of a predetermined size or more, the protruding member 281b moves along the guide rail 281e. To return to position a. In this case, the wireless charging module 201 is drawn out, and one side of the wireless charging module 201 is exposed to the outside from the wireless charging module deck 203 (FIG. 14B). The contact part 251-2 is connected to the connection pattern 221-1 from one side to the other side of the connection pattern 221-1 as the first connector 221 is drawn out of the insertion groove 245-1. (221-1). The wireless charging module 201 may be drawn out as long as the other side of the first connector 221 does not leave the insertion groove 245-1.

With one side of the wireless charging module 201 drawn out of the wireless charging module deck 203, the power transmission unit 206-1 of the wireless charging module 201 is adjusted by adjusting the insertion depth of the wireless charging module 201. ) May correspond to the power receiver of the mobile device 50. As the wireless charging module 201 is inserted into the wireless charging module deck 203 (that is, as the first connector 221 is inserted into the insertion groove 245-1), the contact portion 251-2 Since the continuous contact with the connection pattern 221-1 from the other side to one side of the connection pattern 221-1, the wireless charging module 201 (more specifically, the charging control unit 215) and the wireless charging module deck ( The electrical connection between 203 can be maintained as it is.

15 is a diagram illustrating a state in which a plurality of power transmitters are formed in the wireless charging apparatus according to the second embodiment of the present invention. A plurality of power transmitters 206-1 may be formed on the support unit 206-2 of the wireless charging module 201. The first power transmitter 296, the second power transmitter 297, and the third power transmitter 298 may extend in the longitudinal direction of the wireless charging module 201 (or the wireless charging module deck 203) (ie, a portable device ( 50) can be arranged in the direction of insertion). A part of the first power transmitter 296 and the second power transmitter 297 may be formed to overlap each other. A portion of the second power transmitter 297 and the third power transmitter 298 may be formed to overlap each other. The first power transmitter 296, the second power transmitter 297, and the third power transmitter 298 may be electrically connected to the charging controller 215, respectively. Although the first power transmitter 296, the second power transmitter 297, and the third power transmitter 298 are arranged in the longitudinal direction of the wireless charging module 201, the mobile device 50 is not limited thereto. ) May be arranged in the width direction of the wireless charging module 201 according to the direction in which is inserted. Various numbers of power transmitters may be arranged.

When the portable device 50 is mounted on the wireless charging device 100, the first power transmitter 296, the second power transmitter 297, and the third power transmitter 298 each wirelessly transmit from the portable device 50. Receive a feedback signal associated with charging. In this case, the wireless charging apparatus 100 may wirelessly charge the portable device 50 through a power transmitter that receives a feedback signal having the largest signal strength. The wireless charging device 100 supplies the same power to the first power transmitter 296, the second power transmitter 297, and the third power transmitter 298 at the initial stage of the wireless charging operation, thereby providing a feedback signal from the portable device 50. After receiving each of the, power can be intensively supplied to the power transmitter for receiving the feedback signal having the largest signal strength, and the power supply to the remaining power transmitter can be reduced. The wireless charging device 100 may block the power supply to the remaining power transmitter except for the power transmitter that receives the feedback signal having the largest signal strength.

Referring to FIG. 15B, four power transmitters 296, 297, 298, and 299 may be formed on the support unit 206-2 of the wireless charging module 201. Here, the first power transmitter 296 and the fourth power transmitter 299 are arranged in the longitudinal direction of the wireless charging module 201, and the second power transmitter 297 and the third power transmitter 298 are wireless. The charging module 201 may be arranged in the width direction. In this case, the first power transmitter 296 and the fourth power transmitter 299 may be formed to cross the second power transmitter 297 and the third power transmitter 298. The plurality of power transmitters may be arranged in various other forms.

16 is a diagram illustrating a state in which a portable device is guided and fixed to a plurality of power transmitters in a wireless charging device according to a second embodiment of the present invention. The first inlet cover 212-1 is rotatably formed at one end of the portable device housing 202, and the second inlet cover 212-2 is provided at the other end of the mobile device housing 202. It can be formed rotatably. A first position fixing part 214-1 is formed on the surface exposed to the outside of the first inlet cover 212-1, and a second position lock is formed on the surface exposed to the outside of the second inlet cover 212-2. Government 214-2 may be formed. The first power transmitter 296, the second power transmitter 297, and the third power transmitter 298 may be arranged in a line along the insertion direction of the portable device 50. The first power transmitter 296, the second power transmitter 297, and the third power transmitter 298 may be arranged along the insertion direction of the portable device 50 on the central axis of the wireless charging module 201.

The first position fixing unit 214-1 and the second position fixing unit 214-2 guide the portable device 50 to the plurality of power transmitters 296, 297, and 298, respectively, to both sides of the portable device 50. By pressing, the portable device 50 is fixed to a position corresponding to the plurality of power transmitters 296, 297, and 298. The first position fixing part 214-1 and the second position fixing part 214-2 may be formed of the portable device 50 by an elastic force provided by the first hinge 236-1 and the second hinge 236-2, respectively. You can press on both sides. When the first position fixing portion 214-1 and the second position fixing portion 214-2 are made of an elastic material, the first position fixing portion 214-1 and the second position fixing portion 214-2 itself Both sides of the portable device 50 can be pressed by the elastic force of the.

Referring to FIG. 16B, the first power transmitter 296 and the fourth power transmitter 299 may extend in the longitudinal direction of the wireless charging module 201 (in FIG. 16, the insertion direction of the portable device 50). The second power transmitter 297 and the third power transmitter 298 may be arranged in the width direction of the wireless charging module 201. When the portable device 50 is inserted into the portable device housing unit 202, the portable device 50 includes a plurality of power transmitters by the first inlet cover 212-1 and the second inlet cover 212-1. It is fixed while being guided to the (296, 297, 298, 299) side.

17 is a view showing a wireless charging device according to an embodiment of the present invention. FIG. 17A illustrates a state before the portable device is stored, and FIG. 17B illustrates a state where the portable device is stored. The wireless charging device 100Z includes a housing portion 102Z, a wireless charging portion 104Z, a case 106Z, a fan 108Z, a sterilization portion 110Z, a protection member 112Z, an inlet cover 114Z, and a position height. May include government 116Z. The wireless charging device 100Z may be mounted on the structure. Components other than the case 106Z may constitute the wireless charging module.

The housing portion 102Z is a portion constituting the body (body) of the wireless charging module. The front end of the housing part 102Z is provided with an inlet in which the portable device 50Z is inserted. Inside the housing 102Z, a storage space S capable of storing the portable device 50Z is provided. The whole or a part of the portable device 50Z may be inserted and accommodated in the housing part 102Z. The housing portion 102Z may be made of a plastic material.

A locking protrusion 121Z may protrude from a surface (inner bottom surface of the housing 102Z in FIG. 17) on which the portable device 50Z is seated in the housing 102Z.

The first through part 123Z and the second through part 125Z may be provided on an inner bottom surface of the housing part 102Z. The first through part 123Z and the second through part 125Z are provided through the housing part 102Z. The wireless charging unit 104Z is provided in the housing unit 102Z. The wireless charging unit 104Z includes a power transmitter 104aZ that radiates wireless power into the air to charge the battery of the portable device 50Z. The wireless charging unit 104Z may include a charging control unit 104bZ that controls the power transmitter 104aZ.

The power transmitter 104aZ may be inserted into and fixed to the first through part 123Z. One surface of the power transmitter 104aZ faces the portable device 50Z on the inner surface of the housing 102Z. The other surface of the power transmitter 104aZ is exposed to the outside. The first locking part 127Z may extend to both sides of the other surface of the power transmitter 104aZ. The first locking portion 127Z is locked to the outer surface of the housing portion 102Z.

The charging control unit 104bZ may be provided on the main board 130Z of the wireless charging device 100Z. The power transmitter 104aZ and the charge controller 104bZ are electrically connected to each other. The main board 130Z may be inserted into and fixed to the second through part 125Z. One surface of the main board 130Z faces the portable device 50Z on the inner surface of the housing portion 102Z. The other surface of the main board 130Z is exposed to the outside. The second locking portion 129Z may extend to both sides of the other surface of the main board 130Z. The second locking portion 129Z is locked to the outer surface of the housing portion 102Z.

The case 106Z is provided outside the housing portion 102Z. The case 106Z may be provided in close contact with the outer surface of the housing portion 102Z. The case 106Z serves to discharge heat generated from the power transmitter 104aZ and the main board 130Z to the outside. The case 106Z may be provided in contact with the other surface of the power transmitter 104aZ exposed to the outside and the other surface of the main board 130Z.

The case 106Z may be coupled to the housing portion 102Z through the coupling member 121Z. The coupling member 121Z may couple the case 106Z and the housing portion 102Z to an upper side of the housing portion 102Z and a lower side of the housing portion 102Z, respectively. The coupling member 121Z may couple the case 106Z and the housing portion 102Z at positions adjacent to the power transmitter 104aZ and the main board 130Z below the housing portion 102Z. Since the power transmitter 104aZ and the main board 130Z are locked to the outer surface of the housing portion 102Z by the first locking portion 127Z and the second locking portion 129Z, respectively, the power transmission portion 104aZ. When the case 106Z and the housing portion 102Z are coupled to each other through the coupling member 121Z at a position adjacent to the main board 130Z, the other side of the power transmission unit 104aZ and the other side of the main board 130Z may be connected to the case 106Z. ) Can be in close contact with. In addition, the power transmitter 104aZ and the main board 130Z can be firmly fixed to the housing portion 102Z without a separate fixing means (or coupling means). The coupling member 121Z may be provided at both sides of the power transmitter 104aZ and the main board 130Z.

The main board 130Z may be formed of a metal printed circuit board (PCB). The main board 130Z may include a metal base, an insulating layer provided on an upper surface of the base, and a circuit pattern provided on the insulating layer. The lower surface of the metal base may be the other surface of the main board 130Z. The lower surface of the metal base is in contact with the case 106Z.

The fan 108Z may be provided inside the housing portion 102Z. The fan 108Z may operate in conjunction with the operation of the wireless charging unit 104Z. The sterilization unit 110Z may be an ultraviolet irradiation unit that irradiates ultraviolet rays to sterilize the portable device 50Z stored in the housing unit 102Z.

Referring to FIG. 18, a heat transfer member 132Z may be provided between the wireless charging unit 104Z and the case 106Z. The wireless charging unit 104Z may be a main board 130Z on which the power transmitter 104aZ or the charging control unit 104bZ is mounted. The heat transfer member 132Z may be in close contact with the wireless charging unit 104Z and the case 106Z, respectively, between the wireless charging unit 104Z and the case 106Z.

19 is a perspective view showing a wireless charging device according to an embodiment of the present invention. The wireless charging device 100Z may include a wireless charging module 101Z and a case 106Z. The wireless charging module 101Z may be inserted into and inserted into the case 106Z. Inlet covers 114Z may be provided at both sides of the inlet of the housing 102Z, respectively. A position fixing part 116Z may be provided at an end portion of each inlet cover 114Z. The inlet cover 114Z may be provided with a scratch prevention coating layer.

An illumination unit 118Z may be provided at the front end of the housing unit 102Z. The lighting unit 118Z may be configured in the form of a line along the inlet edge of the housing unit 102Z to indicate the inlet position of the housing unit 102Z.

The lighting unit 118Z may change at least one of a brightness level, a color temperature level, and a color according to a change in the state of charge of the portable device 50Z.

The lighting unit 118Z may operate in conjunction with motion detection of the user. When the user's motion is detected in a dark place, the lighting unit 118Z may be turned on to inform the location of the wireless charging device 100Z. The wireless charging device 100Z may also serve as lighting through the lighting unit 118Z.

When the wireless charging device 100Z is mounted inside the vehicle, the lighting unit 118Z may display whether the portable device 50Z is accommodated when the door of the vehicle is opened or the vehicle is turned off. The lighting unit 118Z may check whether the portable device 50Z is accommodated through the wireless charging unit 104Z. The lighting unit 118Z may check whether the portable device 50Z is stored through a separate sensor.

The housing part 102Z may be provided with a status notification part 120Z and a wired connection part 122Z. The wired connection unit 122Z may be wired connected to the mobile device 50Z through a cable. The portable device 50Z may be wired charged through the wired connection 122Z.

The case 106Z may include an upper case 106-1Z and a lower case 106-2Z. The upper case 106-1Z and the lower case 106-2Z may be provided symmetrically. The upper case 106-1Z and the lower case 106-2Z may be coupled to each other. Coupling pieces 136Z for coupling the upper case 106-1Z and the lower case 106-2Z may be provided at both sides of the upper case 106-1Z and the lower case 106-2Z, respectively. The upper case 106-1Z and the lower case 106-2Z may be bonded through the coupling piece 136Z, but are not limited thereto, and a coupling member (not shown) may be connected to the coupling piece 136Z. When the upper case 106-1Z and the lower case 106-2Z are coupled to each other, a space in which the wireless charging module 101Z is inserted and accommodated is provided inside the case 106Z.

An electromagnetic shielding part 134Z may be provided outside the lower case 106-2Z. The electromagnetic shielding unit 134Z may be provided to shield a frequency band of wireless power generated by the wireless charging unit 104Z. The electromagnetic shield 134Z may be provided on the surface of the case 106Z through at least one method of printing, deposition, spraying, plating, or coating. For example, a first electromagnetic wave shielding material (or component) is first surface-treated on the surface of the case 106Z, and a second electromagnetic wave shielding material (or component) is formed on the surface of the case 106Z on a second surface. Can be processed.

The shielding frequency band of the electromagnetic shielding unit 134Z may be several tens of KHz to several hundred KHz. The electromagnetic shielding unit 134Z may include a soft magnetic material to shield electromagnetic waves of the low frequency band.

As the soft magnetic material, an amorphous alloy such as Mn-Zn ferrite or Metglas or a nanocrystalline alloy such as Finemet may be used. Specifically, an amorphous alloy such as Mn-Zn ferrite or Metglas may be used in the frequency band of several tens to 300 KHz, and a nanocrystalline alloy such as Finemet may be used in the frequency band of 300 KHz to 1 MHz. Here, the nanocrystalline alloy may be a nanocrystalline alloy of a soft magnetic material. In addition, the electromagnetic shield 134Z may include at least one of silver (Ag), copper (Cu), nickel (Ni), carbon, and the like to shield electromagnetic waves in a low frequency band.

The wireless charging device 100Z may include a mounting case for mounting the electromagnetic shielding portion 134Z on the outside of the wireless charging module 101Z. The mounting case may include a housing part inserted therein, and the long case may be a metal case that radiates heat generated from the wireless charging unit.

20 is a view showing a state in which the electromagnetic shield is mounted on the mounting case according to an embodiment of the present invention. The mounting case 140Z may include a first surface 140aZ, a second surface 140bZ spaced apart from the first surface 140aZ at a lower portion of the first surface 140aZ, and provided to face the first surface 140aZ. A third surface 140cZ connecting the first surface 140aZ and the second surface 140bZ at one end of the first surface 140aZ and the second surface 140bZ, and the first surface 140aZ and the second surface ( The other side of the 140bZ may include a fourth surface 140dZ connecting the first surface 140aZ and the second surface 140bZ. The first surface 140aZ and the second surface 140bZ may form an upper surface and a lower surface of the mounting case 140Z, respectively, and the third surface 140cZ and the fourth surface 140dZ may have both side surfaces of the mounting case 140Z. Can be achieved. The mounting case 140Z may have an open front portion and a closed rear portion. A space in which the wireless charging module 101Z may be inserted is provided inside the mounting case 140Z. The mounting case 140Z may be provided outside the wireless charging module 101Z.

Each corner of the mounting case 140Z may be provided with a mounting guide portion 142Z for mounting and detaching the electromagnetic shield 134Z. The mounting guide portion 142Z includes the first guide groove 144Z and the electromagnetic shielding portion which restrict the movement of the electromagnetic shielding portion 134Z in the height direction (that is, the direction of the mounting case 140Z in FIG. 20). The second guide groove 146Z may be configured to restrict movement in the width direction of the 134Z (that is, the direction of the mounting case 140Z in FIG. 20). The first guide groove 144Z and the second guide groove 146Z may be provided continuously or intermittently along the length direction of the mounting case 140Z (that is, the ground direction in FIG. 20).

The first guide groove 144Z may be provided by a width direction extension protrusion 148Z protruding in the width direction of the mounting case 140Z to restrain the movement of the electromagnetic shield 134Z in the height direction. The width direction extension protrusion 148Z may protrude to the left or the right side according to the position where the mounting guide part 142Z is provided in the mounting case 140Z. For example, when the mounting guide portion 142Z is provided at the upper left (or lower left) corner of the mounting case 140Z, the width direction extending protrusion 148Z may protrude to the right from the mounting guide portion 142Z. have. In addition, when the mounting guide part 142Z is provided at the upper right (or lower right) corner of the mounting case 140Z, the width direction extending protrusion 148Z may protrude to the left side from the mounting guide part 142Z.

The second guide groove 146Z may be provided by a height direction extension protrusion 150Z protruding in the height direction of the mounting case 140Z to restrain the movement of the electromagnetic shielding portion 134Z in the width direction. The height extension protrusion 150Z may protrude upward or downward, depending on a position at which the mounting guide part 142Z is provided in the mounting case 140Z.

When the mounting guide portion 142Z is provided at each of four corners (ie, upper left, upper right, lower left, and lower right) of the mounting case 140Z, the first guide groove 144Z and the second guide groove ( The electromagnetic shielding portion 134Z may be mounted to face the first surface 140aZ to the fourth surface 140dZ of the mounting case 140Z through 146Z. The second electromagnetic shielding portion 134-2Z facing the second surface 140bZ of the mounting case 140Z may include a first portion of the mounting guide portion 142Z provided at the lower left and lower right portions of the mounting case 140Z, respectively. The guide groove 144Z may be slide coupled to be mounted. The third electromagnetic shielding portion 134-3Z facing the third surface 140cZ of the mounting case 140Z may include a second portion of the mounting guide portion 142Z provided at the upper left and lower left portions of the mounting case 140Z, respectively. The guide groove 146Z may be slide coupled to be mounted. The fourth electromagnetic wave shielding portions 134-4Z facing the fourth surface 140dZ of the mounting case 140Z are respectively disposed in the second upper side of the upper right side and the lower right side of the mounting case 140Z. The guide groove 146Z may be slide coupled to be mounted.

In the mounting guide part 142Z, a plurality of first guide grooves 144Z and second guide grooves 146Z may be provided. The seventh electromagnetic shield 134-7Z and the eighth electromagnetic shield 134-8Z are mounted outside the third electromagnetic shield 134-3Z and the fourth electromagnetic shield 134-4Z, respectively. Two guide grooves 146Z may be further provided.

Since the electromagnetic shield 134Z is coupled to the first guide groove 144Z and the second guide groove 146Z in a slide manner, the electromagnetic shield 134Z is easy to install and detach, and a position to mount the electromagnetic shield 134Z as necessary. And the number can be adjusted. According to the position where the wireless charging unit 104Z is mounted, the position and the number of mounting the electromagnetic shielding unit 134Z may be adjusted. A plurality of electromagnetic shielding portions 134Z may also be provided on the third surface 140cZ and the fourth surface 140dZ.

The mounting case 140Z may be a metal case that radiates heat generated from the wireless charging unit 104Z. The mounting case 140Z may have a structure that radiates heat generated from the wireless charging unit 104Z as illustrated in FIG. 17.

21 is a view showing a state in which the electromagnetic shield is mounted on the mounting case according to another embodiment of the present invention. The mounting guides 142Z may be provided at lower ends of both sides of the mounting case 140Z, respectively. The first electromagnetic shield 134-1Z may be slide-coupled to the first guide grooves 144Z of the mounting guides 142Z respectively provided at the lower edges of both sides of the mounting case 140Z. The second electromagnetic shield 134-2Z may be slidably mounted to the first guide groove 144Z to the outside of the first electromagnetic shield 134-1Z. The first electromagnetic shield 134-1Z and the second electromagnetic shield 134-2Z are mounted to face the second surface 140bZ of the mounting case 140Z. The first electromagnetic shield 134-1Z and the second electromagnetic shield 134-2Z may have a flat plate shape.

The third electromagnetic shield 134-3Z may be mounted on the second guide grooves 146Z of the mounting guides 142Z respectively provided at the lower edges of both sides of the mounting case 140Z. The third electromagnetic shield 134-3Z may be slide coupled to the second guide groove 146Z or may be fitted to the third guide groove 146Z. The third electromagnetic shield 134-3Z may be mounted to surround the upper surface (first surface 140aZ) and both sides 140cZ and 140dZ of the mounting case 140Z. The third electromagnetic shielding part 134-3Z may have a cross-section having a “c” shape. A fourth electromagnetic shield 134-4Z may be coupled to the second guide groove 146Z to the outside of the third electromagnetic shield 134-3Z.

The electromagnetic shield 134Z may also be provided in a structure capable of simultaneously shielding multiple surfaces. The electromagnetic shielding part 134Z may be formed in a "-" shape to surround the upper surface (first surface 140aZ) and one side 140cZ or 140dZ of the mounting case 140Z. The mounting guide portion 142Z may have a different position provided in the mounting case 140Z according to the shape of the electromagnetic shielding portion 134Z.

22 illustrates a smart key system according to an embodiment of the present invention. An example of a communication system in which interference with a wireless charging device is described is a smart key system, but other communication systems (for example, tire pneumatic systems, air cleaning systems, and audio systems) may cause interference with the wireless charging device. Etc.) may also be applied to a base station, a transponder, and the like.

The smart key system 10Y includes a base station 20Y and a transponder 30Y. The base station 20Y is mounted in the vehicle. The transponder 30Y is provided to be portable by the user of the vehicle.

The base station 20Y transmits a first wake-up signal when a preset event (for example, an event such as a vehicle door handle is pulled or a door open / close signal is generated in the transponder 30Y) occurs. The transponder 30Y is searched. The base station 20Y does not transmit the first wakeup signal only when a predetermined event occurs, but may periodically transmit the first wakeup signal to search for the transponder 30Y. The base station 20Y transmits a low frequency (LF) signal of 125 KHz or 134 KHz. The first wakeup signal may include unique code information (for example, a vehicle ID) of the corresponding vehicle.

When the transponder 30Y receives the first wake up signal, the transponder 30Y may check whether the first wake up signal is valid through the unique code information of the vehicle included in the first wake up signal. When the first wake-up signal is valid, the transponder 30Y transmits a response signal including the unique identification information for authentication to the base station 20Y to perform mutual communication. In this case, the transponder 30Y may transmit a high frequency signal (for example, 315 MHz, 433 MHz, 868 MHz, 915 MHz, etc.) to the base station 20Y as the response signal.

The first wake-up signal (for example, low frequency signal such as 125 KHz or 134 KHz) transmitted by the base station 20Y interferes with the wireless power of the wireless charging device 40Y mounted in the vehicle.

The wireless charging device 40Y includes a power transmitter 40-1Y for transmitting wireless power of a predetermined frequency. The portable device 50Y includes a power receiver 50-1Y that receives wireless power transmitted by the power transmitter 40-1Y.

The base station 20Y may include a transmitter 21Y, a receiver 23Y, and a controller 25Y. The transmitter 21Y may be provided to transmit the first wakeup signal and the second wakeup signal, respectively. The second wakeup signal may be different from at least one of the first wakeup signal and a signal strength and a frequency band. The transmitter 21Y may include a first transmitter 21-1Y for transmitting the first wakeup signal and a second transmitter 21-2Y for transmitting the second wakeup signal.

The first transmitter 21-1Y transmits the first wake-up signal (a low frequency signal such as 125 KHz or 134 KHz) to the transponder 30Y under the control of the controller 25Y. The second transmitter 21-2Y transmits a second wake-up signal that does not cause interference with the wireless power of the wireless charging device 40Y to the transponder 30Y. The first wakeup signal and the second wakeup signal may have different frequency bands. The transponder may comprise a multiband antenna arranged to receive a first wakeup signal and the second wakeup signal.

The transmission of the first wakeup signal and the transmission of the second wakeup signal may be synchronized. The first transmitter 21-1Y and the second transmitter 21-2Y may generate and transmit the first wakeup signal and the second wakeup signal, respectively, according to a preset event occurrence (or according to a preset period). .

The second wakeup signal may be transmitted at a time difference from the first wakeup signal. The second transmitter 21-2Y may obtain a first wakeup signal from the first transmitter 21-1Y, generate a second wakeup signal by frequency modulating the obtained first wakeup signal, and then transmit the first wakeup signal. . The second transmitter 21-2Y may generate a second wakeup signal by amplitude-modulating the obtained first wakeup signal to a level that does not cause interference with the wireless power of the wireless charging device 40Y. The second transmitter 21-2Y may amplitude modulate the first wakeup signal to generate a second wakeup signal having a greater signal strength than the first wakeup signal.

The second transmitter 21-2Y may generate a second wakeup signal having a frequency band that does not cause interference with the wireless power of the wireless charging device 40Y according to the wireless charging method of the wireless charging device 40Y.

The receiving unit 23Y serves to receive a response signal from the transponder 30Y. The receiver 23Y may be provided to receive a response signal of a high frequency signal.

The control unit 25Y serves to control the transmitter 21Y and the receiver 23Y. The controller 25Y may control the transmitter 21Y to transmit at least one of the first wakeup signal and the second wakeup signal according to a preset event occurrence (or according to a preset period). The controller 25Y may control the transmitter 21Y to transmit at least one of the first wakeup signal and the second wakeup signal according to whether or not the wireless charging device 40Y performs the wireless charging operation. The controller 25Y may obtain information on whether the wireless charging device 40Y is performing the wireless charging operation from the wireless charging device 40Y. The base station 20Y may be wired to the wireless charging device 40Y. The wireless charging device 40Y may transfer information on whether the wireless charging operation is performed to the base station 20Y by wire. The wireless charging device 40Y may wirelessly transmit information on whether the wireless charging operation is performed to the base station 20Y.

When the wireless charging device 40Y does not perform a wireless charging operation, the controller 25Y may control the transmitter 21Y to transmit only the first wake-up signal to the transponder 30Y. ) Performs the wireless charging operation, the controller 25Y may control the transmitter 21Y to transmit only the second wake-up signal to the transponder 30Y.

In order for the controller 25Y to control the transmitter 21Y according to the wireless charging operation of the wireless charging device 40Y, a configuration for acquiring information on whether the wireless charging operation is performed should be added to the base station 20Y. Bar controller 25Y may control transmitter 21Y without information on the wireless charging operation. The controller 25Y may control the transmitter 21Y to transmit both the first wakeup signal and the second wakeup signal according to a preset event occurrence.

The transponder 30Y includes a receiver 31Y and a transmitter 33Y. The receiver 31Y may be provided to receive the first wakeup signal and the second wakeup signal respectively transmitted by the base station 20Y. The receiver 31Y may include a first receiver 31-1Y that receives the first wakeup signal transmitted by the base station 20Y, and a second receiver 31-2Y that receives the second wakeup signal. have.

The first receiver 31-1Y may include a first antenna that receives a frequency band of the first wakeup signal (eg, 125 KHz or 134 KHz). The second receiver 31-2Y may include a second antenna that receives a frequency band of the second wake-up signal (for example, 300 to 400 KHz). The first and second antennas may be provided separately. The first receiver 31-1Y and the second receiver 31-2Y may be divided in hardware.

The transmitter 33Y may transmit a response signal to the base station 20Y in response to the first wakeup signal or the second wakeup signal. The transmitter 33Y may transmit a response signal to the base station 20Y in response to the second wake-up signal while the wireless charging device 40Y performs wireless charging.

23 is a diagram schematically illustrating a base station according to an embodiment of the present invention. Base station 20Y may include base module 62Y and additional module 64Y. The basic module 62Y includes a first transmitter 21-1Y for transmitting the first wakeup signal to the transponder 30Y, a receiver 23Y for receiving a response signal from the transponder 30Y, and a base station 20Y. It may include a control unit 25Y for controlling the operation of the). The basic module 62Y may be provided with a signal line 61Y electrically connected to the vehicle.

The additional module 64Y may include a second transmitter 21-2Y for transmitting the second wakeup signal to the transponder 30Y. The additional module 64Y may be provided with a receiving groove 63Y in which the basic module 62Y is accommodated. The basic module 62Y may be mechanically (physically) and electrically connected to the additional module 64Y while being accommodated in the accommodation groove 63Y. The base module 62Y can be detachably coupled with the additional module 64Y. The receiving groove 63Y may be provided with fixing means (not shown) for fixing the basic module 62Y in the storage groove 63Y. The accommodating groove 63Y may be provided with a connecting means (not shown) electrically connected to the base module 62Y. The basic module 62Y may be provided with a connector (not shown) connected to the connecting means (not shown).

The additional module 64Y may be provided with means for obtaining information on whether the wireless charging operation is performed from the wireless charging device 40Y (or the vehicle or the portable device 50Y, etc.). The additional module 64Y may transmit information on whether the wireless charging operation is acquired to the base module 62Y.

24 is a flowchart illustrating a communication method of a smart key system according to an embodiment of the present invention. The base station 20Y checks whether a signal transmission event occurs (S 101Y). The signal transmission event refers to an event for the base station 20Y to transmit a signal to the transponder 30Y in order to communicate with the transponder 30Y.

As a result of checking in step S 101Y, when a signal transmission event occurs, the base station 20Y checks whether the wireless charging device 40Y performs a wireless charging operation (S 103Y). As a result of checking in step S 103Y, when the wireless charging device 40Y does not perform the wireless charging operation, the base station 20Y transmits the first wake-up signal to the transponder 30Y (S 105Y). The transponder 30Y transmits a response signal to the base station 20Y in response to the first wakeup signal (S 107Y).

As a result of checking in step S 103Y, when the wireless charging device 40Y performs a wireless charging operation, the base station 20Y transmits a second wakeup signal to the transponder 30Y (S 109Y). The transponder 30Y transmits a response signal to the base station 20Y in response to the second wakeup signal (S111Y).

FIG. 26 is a view illustrating a state in which an internal pocket is formed to be withdrawn within a housing part in a wireless charging device according to an embodiment of the present invention. An inner pocket 152X may be provided inside the housing portion 102X. One side of the inner pocket 152X (ie, the side facing the inlet of the housing portion 102X) is provided open. The inner pocket 152X may be provided in a shape corresponding to the inner storage space of the housing portion 102X. A portion of the portable device 50X inserted into the inlet of the housing portion 102X is accommodated in the inner pocket 152X. An inside space 152X is provided with a storage space S in which a part of the portable device 50X is accommodated.

The inner pocket 152X may be provided to be pulled out toward the inlet side of the housing portion 102X. The first elastic member 154X may be provided at the other side of the inner pocket 152X in the housing portion 102X. The first elastic member 154X serves to provide elastic force to the inner pocket 152X toward the inlet side of the housing portion 102X (that is, one side direction of the inner pocket 152X).

The stopper portion 156X may be provided on an inner wall of the housing portion 102X. The stopper portion 156X may be provided to be pulled out and pulled out from the inner wall of the housing portion 102X. The stopper part 156X may include a stopper 156-1X, a second elastic member 156-2X, and a receiving groove 156-3X. The accommodation grooves 156-3X may be provided on the inner wall of the housing portion 102X.

The stopper 156-1X may be provided to be withdrawn and drawn into the housing portion 102X from the receiving groove 156-3X. The withdrawal and withdrawal direction of the stopper 156-1X may be provided to be perpendicular to the withdrawal and withdrawal direction of the inner pocket 152X. The second elastic member 156-2X may be provided at one side of the stopper 156-1X in the receiving groove 156-3X. The second elastic member 156-2X serves to provide the elastic force to the stopper 156-1X in the inner direction of the housing portion 102X (that is, the pull-out direction of the stopper 156-1X). At one end of the stopper 156-1X, a locking portion 156aX may be provided to prevent the stopper 156-1X from being separated from the receiving groove 156-3X.

When the stopper 156-1X is withdrawn from the inner wall of the housing portion 102X, one end of the inner pocket 152X (that is, the open end of the inner pocket 152X) is locked to the stopper 156-1X to be fixed. Will be. The first elastic member 154X provided on the other side of the inner pocket 152X is in a contracted state.

When a foreign matter (not shown) flows into the inner pocket 152X, the user may press the stopper 156-1X to lead the stopper 156-1X into the inner wall of the housing portion 102X. The stopper 156-1X may be provided at a position at which the user's finger can be inserted (ie, an inner wall of the housing portion 102X adjacent to the inlet of the housing portion 102X). Then, while the engagement by the stopper 156-1X is released, the inner pocket 152X is drawn out to the inlet side of the housing portion 102X by the elastic force of the first elastic member 154X. The inner pocket 152X may be drawn out so that one end thereof is exposed to the outside of the housing portion 102X. The stopper 156-1X is in a pressed state by the inner pocket 152X.

 When the user inserts the inner pocket 152X back into the housing portion 102X, the stopper 156-1X is drawn out from the inner wall of the housing portion 102X by the elastic force of the second elastic member 156-2X. One end of the inner pocket 152X is fixed again by the stopper 156-1X. Meanwhile, one end of the inner pocket 152X not caught by the stopper 156-1X may extend to the inlet side of the housing portion 102X. In this case, the user can easily retract the inner pocket 152X to the position held by the stopper 156-1X through the extended end of the inner pocket 152X.

27 is a perspective view illustrating a wireless charging device according to an embodiment of the present invention. The metal case 106X is provided outside the housing part 102X. The metal case 106X may be provided to surround the housing portion 102X except for the front end portion of the housing portion 102X.

The power transmitter 104aX of the wireless charging unit 104X transmits a signal to the portable device 50X and determines whether the wireless charging is possible according to the magnitude of the response signal fed back from the portable device 50X. The storage state notifying unit (not shown) may know whether the portable device 50X is stored through the response signal of the portable device 50X received by the power transmitter 104aX of the wireless charging unit 104X.

28 is a diagram illustrating a configuration of a wireless charging device according to an embodiment of the present invention. The wireless charging device 100W may include a wireless charging unit 102W, a signal detecting unit 104W, and a charging control unit 106W. The wireless charging unit 102W may include a power transmitter 102 that transmits wireless power of a predetermined frequency. -1W). The portable device 50W is provided with a power receiver 50-1W that receives wireless power transmitted by the power transmitter 102-1W.

The signal detector 104W may detect a low frequency signal (that is, a wake up signal) transmitted by the base station 11W and generate an interference detection signal to the charging controller 106W. In this case, the signal detector 104W may include an antenna for receiving a frequency band of the low frequency signal transmitted by the base station 11W. Here, the signal detector 104W has been described as detecting the low frequency signal transmitted by the base station 11W, but is not limited thereto, and the signal detector according to the frequency of the wireless power transmitted by the power transmitter 102-1W. The type and frequency band of the signal sensed by 104W may vary.

The charging control unit 106W controls the wireless charging operation of the wireless charging unit 102W. The charging control unit 106W may limit and normalize the operation of the wireless charging unit 102W for a preset time when the interference target signal exists. Alternatively, when the interference target signal is present, the output of the wireless power may be reduced or the power supply to the wireless charging unit 102W may be cut off. Alternatively, when the interference target signal exists, the frequency of the wireless power from the wireless charging unit 102W may be changed.

When the portable device 50W is stored (or mounted or seated) in the wireless charging device 100W, the charging control unit 106W may generate a wireless charging start signal to the wireless charging unit 102W to start wireless charging. When the charging control unit 106W has a frequency band signal (interference target signal) that may cause interference with the wireless power transmitted by the power transmitter 102-1W around the wireless charging device 100W, the wireless charging unit ( 102W) may limit the wireless charging operation. Limiting the wireless charging operation of the wireless charging unit 102W refers to a control operation of the charging control unit 106W to reduce the interference generated between the wireless power and the interference target signal or to prevent the interference from occurring.

When the interference target signal exists around the wireless charging device 100W, the charging control unit 106W may reduce the output of the wireless power of the wireless charging unit 102W. That is, the charging control unit 106W reduces the output of the wireless power of the wireless charging unit 102W to a preset range (or a predetermined value) in a normal wireless charging operation, thereby preventing the wireless power of the wireless charging unit 102W from interfering with the interference signal. You can reduce the interference that occurs or prevent it from occurring. In addition, when there is an interference target signal around the wireless charging device 100W, the charging control unit 106W cuts off the power supplied to the wireless charging unit 102W, whereby the wireless power and the interference target signal of the wireless charging unit 102W are used. The interference itself can be prevented from occurring. In addition, when there is an interference target signal around the wireless charging device 100W, the charging control unit 106W changes the frequency of the wireless power of the wireless charging unit 102W to a preset frequency to thereby wirelessly control the wireless charging unit 102W. The interference generated between the power and the signal to be interfered with may be reduced or the interference may not occur.

The charging controller 106W may include a power supply 111W and a frequency modulator 113W to limit the wireless charging operation of the wireless charger 102W. The power supply 111W serves to supply power to the wireless charging unit 102W under the control of the charging control unit 106W. The power supply 111W may cut off the power supplied to the wireless charging unit 102W under the control of the charging control unit 106W. The power supply 111W may reduce the power supplied to the wireless charging unit 102W to a preset range under the control of the charging control unit 106W. The frequency modulator 113W may change the frequency of the wireless power of the wireless charger 102W to a preset frequency under the control of the charging controller 106W.

Restricting the wireless charging operation of the wireless charging unit 102W by the charging control unit 106W may include 1) reducing the output of the wireless power of the wireless charging unit 102W, 2) cutting off the power supply to the wireless charging unit 102W, or 3 ) May be performed by changing the frequency of the wireless power of the wireless charging unit 102W. When there is an interference target signal, the charging control unit 106W may limit the wireless charging operation of the wireless charging unit 102W only for a preset time, and then normalize the wireless charging operation of the wireless charging unit 102W.

The generation information of the interference target signal may include unique code information of the corresponding vehicle. The charging control unit 106W may confirm that the interference target signal is generated in the smart key system 10W of the vehicle through the unique code information of the vehicle. The charging control unit 106W may receive information about the interference target signal from the portable device 50W or another electronic device located in the vicinity of the wireless charging device 100W to confirm the presence of the interference target signal.

29 is a flowchart illustrating a wireless charging method according to an embodiment of the present invention. The charging control unit 106W determines whether the portable device 50W is accommodated in the wireless charging device 100W (S 101W). The charging control unit 106W may check whether the portable device 50W is accommodated through separate sensing means (for example, a weight sensor, a pressure sensor, a piezoelectric sensor, etc.).

Next, when the portable device 50W is housed in the wireless charging device 100W, the charging control unit 106W controls the wireless charging unit 102W to wirelessly charge the portable device 50W (S 103W). As a result, the charging control unit 106W checks whether an interference target signal exists around the wireless charging device 100W (S 105W).

As a result of checking in step S 105, when there is an interference target signal, the charging control unit 106W restricts the wireless charging operation of the wireless charging unit 102W in a preset manner (S 107W). It is checked whether the preset charging time limit has elapsed from the time point at which the wireless charging operation of 102W is restricted (S 109W). As a result of checking in step S 109W, when the preset charging time limit has not elapsed, the charging control unit 106W continues to limit the wireless charging operation of the wireless charging unit 102W.

As a result of checking in step S 109W, when the preset charging time limit has elapsed, the charging control unit 106W releases the restriction of the wireless charging operation so that the wireless charging unit 102W wirelessly charges the mobile device 50W normally again. (S 111W). For example, when the interference target signal is a low frequency signal (ie, a wake-up signal) transmitted by the base station 11W, the base station 11W may generate a predetermined event (for example, the door may be turned on with the start-up turned on). Open, start off, etc.) and can wake up. The base station 11W may attempt to communicate with the transponder 13W by sending a wake-up signal a predetermined number of times. If the wireless charging operation of the wireless charging unit 102W is being performed while the base station 11W attempts to establish a communication connection with the transponder 13W, between the low frequency signal of the base station 11W and the wireless power of the wireless charging unit 102W. Interference occurs and no communication connection is made between the base station 11W and the transponder 13W. Therefore, when the interference target signal exists, the charging control unit 106W may limit the wireless charging operation of the wireless charging unit 102W for a preset charging time limit, so that interference with the interference target signal may not occur. The charging timeout period may be set based on the time when the base station 11W attempts a communication connection with the transponder 13W.

31 shows a schematic block diagram of a wireless charger for a vehicle according to an embodiment of the present invention. The vehicle wireless charger 10U includes, for example, a body 16U having an insertion groove 17U into which a charging object 20U, such as a smartphone, can be inserted, and a body 16U which is lower than the insertion groove 17U. 11U of the transmission coil for generating a magnetic field is disposed in the lower portion of the magnetic field, the magnetic field generated in the transmission coil 11U is disposed to face the transmission coil 11U on the upper portion of the body 16U that is above the insertion groove 17U Attenuation coil 15U for generating a magnetic field to attenuate the?

The transmitting coil 11U may receive a current from the power supply 14U through the control unit 12U to generate a magnetic field. The attenuation coil 15U may be arranged to face the transmission coil 11U such that the center of the attenuation coil 15U coincides with the center of the transmission coil 11U, and draws current from the power supply 14U through the control unit 12U. The magnetic field is generated to attenuate the magnetic field generated by the transmission coil 11U and passed through the attenuation coil 15U.

The attenuation coil 15U may receive a current supplied by a voltage signal having a phase opposite to that of the current supplied to the transmission coil 11U by the control unit 12U. Then, in the attenuation coil 15U, a magnetic field having a phase opposite to that of the magnetic field generated in the transmission coil 11U is generated so that the magnetic field generated in the attenuation coil 15U and the magnetic field generated in the transmission coil 11U cancel each other. Can be.

The attenuation coil 15U is a distance d2 between the receiving coil 21U and the transmitting coil 11U of the charging object 20U when the charging object 20U is inserted into the insertion groove 17U (see FIG. 35). Is disposed above the body 16U such that is smaller than the distance d1 (see FIG. 35) between the receiving coil 21U and the attenuation coil 15U. The magnetic field generated in the transmitting coil 11U is weakened while passing through the receiving coil 21U, and may also be weakened while passing through the distance d2 between the attenuation coil 15U and the receiving coil 11U, thereby reducing the attenuation coil ( 15U generates a weak electric field, which can attenuate the magnetic field generated by the transmission coil 11U and passing through the attenuation coil 15U. In addition, since the distance d2 is larger than the distance d1, the magnetic field generated in the attenuation coil 15U may be generated in the transmitting coil 11U and hardly affect the magnetic field passing through the receiving coil 21U. .

Referring to FIG. 32, the attenuation coil 15U may be connected in series with the transmission coil 11U. The winding direction b of the attenuation coil 15U (including the direction printed or applied to the PCB or PBA) is clockwise, for example, and the winding direction a of the transmission coil 11U is counterclockwise to each other. The opposite is true.

The attenuation coil 15U may be printed on a substrate, may be formed of a coil having a thickness different from that of the transmission coil 11U, or may be wound less than the number of turns of the transmission coil 11U.

The attenuation coil 15U may receive a smaller amount of current than the amount of current supplied to the transmission coil 11U from the control unit 12U.

The charging object 20U includes a rechargeable battery that can be charged and a receiving coil 21U in which a current is induced by a magnetic field generated by the transmitting coil 11U.

Through the insertion groove 17U of the body 16U, the charging object 20U may be disposed on the lower upper surface of the body 16U, and the transmission received at the bottom of the body 16U by a guide not shown. It can be positioned adjacent to align with the coil 11U. The material constituting the lower upper surface of the body 16U may well pass the magnetic field generated by the transmission coil 11U.

The wireless charger 10U may further include a control unit 12U. When the control unit 12U receives a signal from a detection unit (not shown) that detects that the charging target 20U is inserted into the insertion groove 17U of the wireless charger 10U, for example, the control unit 12U transmits it from the power source 14U. The current flowing through the coil 11U and the attenuation coil 15U can be controlled according to the signal from the vehicle control unit 30U or the receiver 13U. When charging the charging object 20U, the control unit 12U supplies a current to the transmitting coil 11U such that a magnetic field is generated in the transmitting coil 11U, and does not supply a current to the attenuation coil 15U. When the control unit 12U receives a signal from the receiver 13U or receives a signal from the vehicle control unit 30U, the control unit 12U may supply a current to the attenuation coil 15U.

The current supplied to the attenuation coil 15U by the control unit 12U transmits a voltage signal having a phase opposite to that of the current supplied to the transmission coil 11U, so that it has the same amplitude and the same magnetic field as that generated by the transmission coil 11U. The magnetic field generated in the transmission coil 11U and the magnetic field generated in the attenuation coil 15U are canceled out by generating a magnetic field having a frequency and an opposite phase.

The control unit 12U receives a signal from the vehicle control unit 30U for notifying that the frequency of the same band as the wireless charger 16U is used by any one of the vehicle's wireless electronics, for example, a smart key module and a tire pressure monitoring system. On receipt, the current is supplied to the attenuation coil 15U like electricity.

The wireless charger 10U may further include a receiver 13U. The receiver 13U may receive, for example, a low frequency signal transmitted from a smart key module (not shown) of the vehicle to a smart key (not shown), or is sent from the smart key module, for example a charge standby signal. It can be received by wire or wireless, in this case, the receiver 13U may send a signal informing the controller 12U. Then, the control unit 12U supplies current to the attenuation coil 15U as described above.

34 is a perspective view of a damping member used in a wireless charger according to another embodiment of the present invention. The damping member 150U includes a solid cylindrical core 151U, a protrusion 152U formed to protrude outward from the circumference of the core 151U, and an exhaust coil 153U wound around the protrusion 152U. . The attenuation member 150U may further include a light emitting diode (not shown) connected to the exhaust coil 153U.

The damping member 150U is disposed in place of the damping coil 15U in one embodiment of the present invention shown in FIG. 31. The attenuating member 150U, like the attenuating coil 15U, may be disposed on the upper portion of the body 16U to face the transmitting coil 11U and may be generated in the transmitting coil 11U to exhaust the magnetic field passing through the attenuating member 150U. have.

The core 151U of the damping member 150U may be formed in a solid polygonal column shape, but in the case of the solid cylindrical shape corresponding to the planar shape of the transmitting coil 11U, all of the magnetic fields generated in the transmitting coil 11U are all. May enter the core 151U. The protrusion 152U, which is formed to protrude outward from the periphery of the core 151U, may have a magnetic field collected through the core 151U, and the number or shape thereof may be appropriately selected, and the magnetic field collected on the protrusion 152U may be The coil 153U may be exhausted by heat or current. In this case, when a light emitting device, for example, a light emitting diode is attached to the exhaust coil, light is emitted from the light emitting device, and the user can visually confirm that the magnetic field is canceled.

In another embodiment of the present invention using the attenuating member 150U, the control unit 12U does not need to supply current to the attenuating member 150U, and a separate current is applied to attenuate the magnetic field generated by the transmitting coil 11U. You do not need to use it. Therefore, the control unit 12U does not receive signals from the receiver 13U and the vehicle control unit 30U.

The core 151U and the protrusion 152U of the damping member 150U may be formed of ferrite. The exhaust coil 152U may be formed of copper, and the number of turns of the protrusion 152U may be appropriately selected.

According to the wireless charger having the same configuration as the above-described embodiment, the magnetic field generated in the transmitting coil 11U and passing through the receiving coil 21U of the charging target 20U is the same amplitude generated in the attenuation coil 15U, Attenuation coil 15U may be attenuated by a magnetic field of the same frequency and opposite phase, where the attenuation coil 15U is a receiving coil at a distance d1U farther than the distance d2U between the transmitting coil 11U and the receiving coil 21U. Since the magnetic field generated in the attenuation coil 15U is not spaced apart from the 21U, the induction action of the receiving coil 21U may not be affected.

The attenuation coil 15U may have a smaller number of windings than the number of windings of the transmitting coil 11U, so that attenuation coil 15U may generate a weaker magnetic field than that of the transmitting coil 11U, thereby inducing the receiving coil 21U. It may not affect.

The attenuation coil 15U can generate a magnetic field weaker than the magnetic field from the transmission coil 11U by using a coil having a thickness different from that of the transmission coil 11U, so as not to affect the induction action of the reception coil 21U. You may not.

The control unit 12U supplies the current supplied to the attenuation coil 15U according to a voltage signal opposite to that supplied to the transmission coil 11U, so that a magnetic field of opposite phase can be generated in the attenuation coil 15U. The magnetic field generated by the transmission coil 11U and passing through the attenuation coil 15U can be canceled out.

The control unit 12U can supply a current to the attenuation coil 15U according to a signal from the receiver 13U that can receive the charge standby signal of the smart key module used in the vehicle, either wired or wirelessly, thereby reducing power consumption. Can be reduced.

The control unit 12U can supply current to the attenuation coil 15U according to the signal of the receiver 13U capable of detecting the low frequency signal transmitted from the smart key module used in the vehicle to the skat key, thereby reducing power consumption. have.

The control unit 12U can supply a current to the attenuation coil 15U in response to a signal from the vehicle control unit 30U indicating that a frequency in the same band as the wireless charger 10U is used in the vehicle's wireless electronics, thereby reducing power consumption. You can.

The attenuation coil 15U is connected in series with the transmission coil 11U, is wound in a direction opposite to the winding direction a of the transmission coil 11U, b, and is less than the number of turns of the transmission coil 11U. By winding up, the magnetic field generated in the transmission coil 11U can be canceled without separately supplying a current from the control unit 12U.

The attenuation member 150U may be used instead of the attenuation coil 15U, so that the magnetic field generated by the transmission coil 11U and passing through the attenuation member 150U may be exhausted without supplying the current from the controller 12U.

Instead of the attenuating coil 15U or the attenuating member 150U, a device is used in which the frequency of the electromagnetic waves generated by the transmitting coil 11U is changed so that the frequency is different from the frequency used by the wireless electronics of the vehicle, or the electromagnetic wave is far-infrared. A member made of a material that can be converted into a substrate may be printed or applied to a PCB or PBA.

35 is a view illustrating a state where a wireless charging device is mounted in a vehicle according to an embodiment of the present invention. The wireless charging device 100T may include a housing part 102T, a first accommodating part 104T, and a second accommodating part 106T. The wireless charging device 100T may be mounted in the vehicle.

The housing portion 102T may be mounted to the vehicle internal structure. The 1st accommodating part 104T is equipped with the 1st accommodating space which can accommodate the 1st portable device 13T. The user may store the smart key in the first storage unit 104T after boarding the vehicle. The first accommodating part 104T may be provided in an open shape.

The second accommodating portion 106T includes a second accommodating space capable of accommodating the second portable device 50T.

36 is a block diagram illustrating a configuration of a wireless charging device according to an embodiment of the present invention. The wireless charging device 100T may include an accommodation detector 152T, a wireless charging module 154T, a wireless charging method checker 156T, a storage status notification unit 158, and a charging controller 160T.

The storage detector 152T detects whether the first portable device 13T is stored in the first storage unit 104T. The storage detector 152T may generate the storage detection signal to the charging controller 160T when the first portable device 13T is stored in the first storage 104T. The storage detector 152T may generate the storage detachment signal to the charging controller 160T when the first portable device 13T is separated from the first storage 104T. The storage detector 152T may be formed of a pressure sensor, a weight sensor, a micro switch, a latch switch, and the like.

The wireless charging module 154T serves to wirelessly charge the second portable device 50T stored in the second accommodating part 106T. The wireless charging module 154T may be provided at one side of the second accommodating part 106T in the housing part 102T. The wireless charging module 154T includes a power transmitter 154-1T for transmitting wireless power of a predetermined frequency. The second portable device 50T includes a power receiver 50-1T that receives wireless power transmitted by the power transmitter 154-1T.

The smart key system 10T of the vehicle includes a base station 11T and a first portable device 13T (ie, a smart key or transponder). The base station 11T is a low frequency signal when a preset event (for example, an event such as a vehicle door handle being pulled or a door open / close signal is generated in the first portable device 13T) occurs. To search for the first portable device 13T. However, the present invention is not limited thereto, and the base station 11T may periodically generate a wake-up signal to search for the first portable device 13T. The low frequency signal may include unique code information (eg, vehicle ID) of the corresponding vehicle.

When the first portable device 13T receives the low frequency signal from the base station 11T, the first portable device 13T may check whether the low frequency signal is valid through the unique code information of the vehicle included in the low frequency signal. When the low frequency signal is valid, the first portable device 13T transmits unique identification information for authentication to the base station 11T to perform mutual communication. In this case, the first portable device 13T may transmit a high frequency signal (for example, 315 MHz, 433 MHz, 868 MHz, 915 MHz, etc.) to the base station 11T.

When the first portable device 13T is accommodated in the first accommodating part 104T, when the accommodating detecting part 152T detects this and generates an accommodating detection signal to the charging control part 160T, the charging control part 160T is low frequency. By transmitting the restriction signal to the base station 11T, the low frequency signal is not transmitted from the base station 11T to the first portable device 13T.

When the first portable device 13T is detached from the first accommodating part 104T, the accommodating detecting part 152T may generate an accommodating release signal to the charging controller 160T. Then, the charging control unit 160T may transmit a low frequency limit release signal to the base station 11T. Since the low frequency signal may be transmitted from the base station 11T to the first portable device 13T, the charging control unit 160T limits the wireless charging operation of the wireless charging module 154T.

The wireless charging method checking unit 156T may check the wireless charging method of the wireless charging module 154T mounted on the wireless charging device 100T and inform the charging control unit 160T. When the charging controller 160T restricts the wireless charging operation of the wireless charging module 154T, the charging control unit 160T may perform the frequency shift of the wireless power by using the information about the wireless charging method.

The storage state notifying unit 158 informs the user of at least one of storage of the first portable device 13T and storage of the second portable device 50T when the vehicle is turned off.

The storage state notification unit 158 may know whether the first portable device 13T is stored through the storage detection unit 152T. The storage state notification unit 158 may know whether the second portable device 50T is stored through the wireless charging module 154T. The storage state notification unit 158 may know whether the second portable device 50T is accommodated through the response signal of the second portable device 50T received by the wireless charging module 154T.

 The charging controller 160T may control the overall operation of the wireless charging device 100T. The charging control unit 160T prevents interference or reduces interference between the wireless power of the wireless charging module 154T and the smart key system 10T. The charging controller 160T may control the wireless charging module 154T to wirelessly charge the second portable device 50T normally. When the first portable device 13T is detached from the first storage unit 104T, the charging control unit 160T reduces the output of the wireless power of the wireless charging module 154T or is supplied to the wireless charging module 154T. The power may be cut off for a preset time or the frequency of wireless power of the wireless charging module 154T may be changed to limit the wireless charging operation of the wireless charging module 154T.

The charging control unit 160T may include a signal generator 160-1T, a power supply unit 160-2T, and a frequency shifting unit 160-3T. When the storing detection signal is transmitted from the storing detecting unit 152T, the signal generator 160-1T may generate a low frequency limit signal and transmit the generated low frequency limit signal to the base station 11T. When the storage departure signal is transmitted from the accommodation detector 152T, the signal generator 160-1T may generate a low frequency limit release signal and transmit the generated low frequency limit release signal to the base station 11T.

The power supply unit 160-2T serves to supply power to the wireless charging module 154T under the control of the charging control unit 160T. The power supply unit 160-2T may block power supplied to the wireless charging module 154T under the control of the charging control unit 160T. The power supply unit 160-2T may reduce the power supplied to the wireless charging module 154T to a preset range under the control of the charging control unit 160T.

The frequency shifting unit 160-3T may shift the frequency of the wireless power of the wireless charging module 154T under the control of the charging control unit 160T. The frequency shifting unit 160-3T may shift the frequency of the wireless power according to the wireless charging method of the wireless charging module 154T. When the wireless charging method of the wireless charging module 154T is the PMA type 2 method (about 118 to 153 KHz used (the PMA type 1 uses about 277 to 357 KHz)) among the magnetic induction methods, the frequency shifter 160- 3T) may vary the frequency of wireless power of the wireless charging module 154T, for example, from 140 to 153 KHz.

38 is a flowchart illustrating a wireless charging method according to an embodiment of the present invention. The storage detector 152T checks whether the first portable device 13T is stored in the first storage 104T (S 101T). As a result of checking in step S 101T, when the first portable device 13T is accommodated in the first accommodating part 104T, the accommodating detecting part 152T generates the accommodating detection signal to the charging control part 160T (S 103T). .

The charging control unit 160T generates the low frequency limit signal and transmits it to the base station 11T (S 105T). Transmission of the low frequency signal from the base station 11T to the first portable device 13T is restricted. The charging control unit 160T controls the wireless charging module 154T to normally wirelessly charge the second portable device 50T (S 107T).

The storage detector 152T checks whether the first portable device 13T is separated from the first storage unit 104T (S 109T). As a result of checking in step S 109T, when the first portable device 13T is detached from the first accommodating part 104T, the accommodating detecting part 152T generates an accommodating departure signal to the charging control part 160T (S 111T). .

The charging control unit 160T generates a low frequency limit cancel signal and transmits the generated low frequency limit release signal to the base station 11T (S 113T). Then, a low frequency signal is transmitted from the base station 11T to the first portable device 13T according to a preset event or a transmission period of the low frequency signal, and the first portable device 13T receives a high frequency signal in response thereto. The base station 11T.

The charging control unit 160T limits the wireless charging operation of the wireless charging module 154T (S 115T).

39 is a diagram illustrating a smart key system to which a wireless charging device is applied according to an embodiment of the present invention. The wireless charging device 100R may include a storage space in which the mobile device 50R is accommodated.

The wireless charging device 100R includes a power transmitter 102aR for transmitting wireless power of a predetermined frequency. The portable device 50R includes a power receiver 50-1R that receives wireless power transmitted by the power transmitter 102aR.

The smart key system 10R includes a base station 11R mounted in a vehicle and a transponder 13R carried by the user. The transponder 13R may be, for example, a smart key or a smart card possessed by a user.

When the preset event occurs, the base station 11R searches for the transponder 13R by transmitting a first wake-up signal. However, the base station 11R does not transmit the first wakeup signal only when a preset event occurs, but may periodically search for the transponder 13R by periodically transmitting the first wakeup signal.

When the transponder 13R receives the first wake up signal, the transponder 13R may determine whether the first wake up signal is valid through the unique code information of the vehicle included in the first wake up signal. When the first wake-up signal is valid, the transponder 13R transmits a response signal including the unique identification information for authentication to the base station 11R to perform mutual communication. The transponder 13R may transmit a high frequency signal to the base station 11R as the response signal.

The first wake-up signal transmitted by the base station 11R may cause interference with the wireless power transmitted by the wireless charging device 100R.

When the base station 11R transmits the first wakeup signal to the transponder 13R, the wireless charging device 100R generates a second wakeup signal that does not interfere with the wireless power of the power transmitter 102aR. And transmits to the transponder 13R. The second wake-up signal may include unique code information of the corresponding vehicle.

40 is a diagram illustrating a configuration of a wireless charging device according to an embodiment of the present invention.

The wireless charging device 100R includes a wireless charging module 102R, a signal detector 104R, a signal generator 106R, a wireless charging method checking unit 108R, a notification unit 110R, and a charging control unit 112R. can do.

The wireless charging module 102R includes a power transmitter 102aR. The wireless charging module 102R serves to wirelessly charge the portable device 50R by transmitting wireless power. The wireless charging module 102R may be installed to be replaced with a wireless charging method corresponding to the charging method of the portable device 50R.

The signal detector 104R detects the first wakeup signal transmitted from the base station 11R. The signal detector 104R may include an antenna 104-1R and a band pass filter 104-2R.

The signal detector 104R may detect a first wakeup signal transmitted from the base station 11R while the wireless charging module 102R wirelessly charges the portable device 50R. The signal detector 104R performs an operation of detecting a first wake-up signal while the wireless charging module 102R performs a wireless charging operation, and performs a first operation while the wireless charging module 102R does not perform a wireless charging operation. The operation for detecting the wakeup signal may not be performed.

The first wakeup signal transmitted by the base station 11R may include unique code information of the corresponding vehicle.

The signal generator 106R may generate a second wakeup signal by modulating the detected first wakeup signal. The signal generator 106R transmits the second wakeup signal to the transponder 13R.

The signal generator 106R may frequency modulate the first wakeup signal to generate a second wakeup signal.

The wireless charging method checking unit 108R may check the wireless charging method of the wireless charging module 102R mounted on the wireless charging device 100R and inform the charging control unit 112R. The wireless charging module 102R may be installed to be replaced with a wireless charging method corresponding to the wireless charging method of the portable device 50R. Since the frequency of the wireless power of the wireless charging module 102R varies according to the wireless charging method, the wireless charging method checking unit 156R may be applied to the wireless charging method of the wireless charging module 102R currently installed in the wireless charging device 100R. Information about the charging control unit 112R. When the signal generation unit 106R generates the second wakeup signal by frequency-modulating the first wakeup signal, the charging control unit 112R generates the second wakeup signal by using the information on the wireless charging method. Can be controlled.

When the first wakeup signal is detected by the signal detector 104R, the notifying unit 110R may detect the fact that the first wakeup signal is detected by a visual method (for example, lighting of a light emitting diode) and an acoustic method (for example, For example, the speaker may be informed by at least one method.

The notification unit 110R may inform the user whether the portable device 50R is stored when the vehicle is turned off. The notification unit 110R may know whether the portable device 50R is stored through the wireless charging module 102R.

The charging controller 112R may control the overall operation of the wireless charging device 100R. In detail, the charging control unit 112R may control the wireless charging module 102R to wirelessly charge the portable device 50R. The charging control unit 112R may control the signal detector 104R to detect the first wakeup signal transmitted from the base station 11R. The charging controller 112R may control the signal generator 106R to generate and transmit a second wakeup signal by modulating the first wakeup signal. The charging control unit 112R may control the wireless charging method checking unit 108R to check the wireless charging method of the wireless charging module 102R mounted on the wireless charging device 100R.

The transponder 13R includes a receiver 21R and a transmitter 23R. The receiver 21R may be provided to receive the first wakeup signal transmitted by the base station 11R and the second wakeup signal transmitted by the wireless charging device 100R, respectively. The receiver 21R is a first receiver 21-1R for receiving the first wakeup signal transmitted by the base station 11R and a second receiver for receiving the second wakeup signal transmitted by the wireless charging device 100R. (21-2R). The general transponder is provided to receive only the first wakeup signal transmitted by the base station 11R, but the transponder 13R according to the embodiment of the present invention transmits the second wakeup signal transmitted by the wireless charging device 100R. Is also provided to receive.

The first receiver 21-1R may include a first antenna that receives a frequency band of the first wakeup signal. The second receiver 21-2R may include a second antenna that receives a frequency band of the second wakeup signal. The first antenna and the second antenna may be separately provided, but are not limited thereto and may be implemented as one multi-band antenna.

Since there is no change in the base station 11R mounted on the vehicle in the smart key system 10R, the existing base station 11R can be used as it is, and only a partial configuration of the transponder 13R possessed by the user needs to be changed. .

The base station 11R may transmit the first wakeup signal transmission information to the wireless charging device 100R, and then transmit the first wakeup signal to the transponder 13R with a time difference. The wireless charging device 100R may generate a second wakeup signal and transmit the second wakeup signal to the transponder 13R. The transmission of the first wakeup signal and the transmission of the second wakeup signal may be synchronized.

The base station 11R may be wired to the wireless charging device 100R and may transmit transmission information (or the first wakeup signal) of the first wakeup signal to the wireless charging device 100R by wire.

41 is a flowchart illustrating a wireless charging method according to an embodiment of the present invention. The charging control unit 112R checks whether the wireless charging module 102R has a wireless charging operation (S 101R). As a result of checking in step S 101R, when the wireless charging module 102R performs the wireless charging operation, the signal detector 104R checks whether the first wakeup signal is detected from the base station 11R (S 103R). . As a result of checking in step S 103R, when the first wakeup signal is detected from the base station 11R, the signal generator 106R modulates the first wakeup signal to generate a second wakeup signal, and the transponder 13R. (S 105R).

Referring to FIG. 50, the portable device storage device 100N includes a housing portion 102N, an inner pocket 104N, a first elastic member 106N, a stopper portion 108N, a protection member 110N, and an entrance cover 112N. ), The position fixing unit 114N, the sterilizing unit 116N, the lighting unit 118N, and the wireless charging unit 120N. The portable device storage device 100N may be mounted on the structure.

The housing portion 102N serves as a case forming the outer shape of the portable device storage device 100N. One side of the housing portion 102N is provided with an inlet through which the portable device is inserted. Inside the housing portion 102N, a storage space for accommodating the inner pocket 104N is provided.

The inner pocket 104N is housed inside the housing portion 102N. One side of the inner pocket 104N is provided open. The inner pocket 104N may be provided in a shape corresponding to the inner storage space of the housing portion 102N. The inner pocket 104N may be provided to be pulled out toward the inlet side of the housing portion 102N.

The first elastic member 106N may be provided on the other side of the inner pocket 104N inside the housing portion 102N. The stopper portion 108N may be provided on the inner wall of the housing portion 102N. The stopper portion 108N may be provided to be pulled out and pulled out from the inner wall of the housing portion 102N. The stopper portion 108N may be provided on a surface of the inner wall of the housing portion 102N that faces the surface on which the wireless charging portion 120N is provided. The stopper portion 108N may include a stopper 108-1N, a second elastic member 108-2N, and a receiving groove 108-3N. Here, the receiving groove 108-3N may be provided on the inner wall of the housing portion 102N. The stopper 108-1N may be provided to be withdrawn and drawn into the housing portion 102N from the receiving groove 108-3N. The second elastic member 108-2N may be provided at one side of the stopper 108-1N in the receiving groove 108-3N. At one end of the stopper 108-1N, a locking portion 108aN may be provided to prevent the stopper 108-1N from being separated from the receiving groove 108-3N.

The protection member 110N may be provided on at least one surface of the inner pocket 104N. The protective member 110N may be detachably provided on the inner surface of the inner pocket 104N. The inlet cover 112N is provided at the inlet of the housing portion 102N (that is, the open end of the housing portion 102N). The inlet cover 112N may be provided to open and close the inlet of the housing portion 102N. When the position fixing part 114N is provided in the inlet cover 112N, the inlet cover 112N not only functions to open and close the inlet of the housing part 102N, but also guides and fixes the portable device 50N to a predetermined position. It will also function.

The wireless charging unit 120N wirelessly charges the portable device 50N stored in the housing unit 102N. The wireless charging unit 120N may be provided on an inner wall of the housing unit 102N. However, the present invention is not limited thereto, and the wireless charging unit 120N may be provided on an inner wall of the inner pocket 104N.

Referring to FIG. 51A, the stopper 108-1N may be withdrawn from the inner wall of the housing portion 102N. At this time, one end of the inner pocket 104N (that is, the open end of the inner pocket 104N) is locked and fixed by the stopper 108-1N.

Referring to FIG. 51B, when a foreign matter (not shown) flows into the inner pocket 104N, the user presses the stopper 108-1N to push the stopper 108-1N into the housing portion 102N. Can be introduced into the inner wall of the Here, the stopper 108-1N may be provided at a position at which the user's finger can be inserted (ie, an inner wall of the housing portion 102N adjacent to the inlet of the housing portion 102N).

The portable device accommodating device 100N may be provided with a foreign matter detection unit (not shown) (for example, a camera or a weight sensor) capable of detecting a foreign matter introduced into the interior pocket 104N. When the weight sensor is used as the foreign matter detection unit (not shown), the foreign matter detection unit (not shown) may have a preset weight change (eg, a minimum value among the mobile devices 50N) inside the housing 102N. When the weight value is less than the weight of the portable device 50N having a weight) or less, it may be determined that foreign matter other than the portable device 50N is introduced into the housing 102N. When the foreign matter detection unit (not shown) detects the foreign matter inside the internal pocket 104N, the foreign matter detection unit (not shown) may notify the user of the fact that the foreign matter is introduced by sound or lighting.

Referring to FIG. 52A, the stopper portion 108N includes a stopper 108-1N, a second elastic member 108-2N, a receiving groove 108-3N, a stopper operation portion 108-4N, and a connection portion. 108-5N, and guide portion 108-6N. The stopper portion 108N may be accommodated in the receiving groove 108-3N provided on the inner wall of the housing portion 102N.

The stopper operation portion 108-4N may be provided on the inner wall of the housing portion 102N closer to the inlet of the housing portion 102N than the stopper 108-1N. The stopper operation unit 108-4N may be provided to be pulled out and drawn in from the inner wall of the housing unit 102N according to the user's operation. The stopper operation portion 108-4N is provided adjacent to the inlet of the housing portion 102N, so that the user can easily operate it. The stopper manipulation unit 108-4N may be provided with a locking portion 108aN extending to prevent the stopper manipulation unit 108-4N from being separated from the receiving groove 108-3N.

One side of the stopper manipulation part 108-4N may be provided with a second elastic member 108-2N. The second elastic member 108-2N serves to provide an elastic force to the stopper operation portion 108-4N to the inner space side of the housing portion 102N. At this time, the second elastic member 108-2N is provided in the longitudinal direction of the stopper operation part 108-4N (ie, the extraction direction of the stopper operation part 108-4N) on both sides of the stopper operation part 108-4N. It can be stored in the part 108-6N. The guide portion 108-6N serves to guide the withdrawal operation and the withdrawal operation of the stopper operation portion 108-4N.

The connection part 108-5N is provided connecting the stopper operation part 108-4N and the stopper 108-1N. The connecting portion 108-5N may extend from the stopper operating portion 108-4N in the retraction direction of the inner pocket 104N and be connected to the stopper 108-1N. The connection part 108-5N causes the withdrawal and withdrawal operations of the stopper 108-1N to be linked to the withdrawal and withdrawal operations of the stopper manipulator 108-4N.

Referring to FIG. 52B, when a foreign matter (not shown) flows into the inner pocket 104N, the user presses the stopper operation unit 108-4N to move the stopper operation unit 108-4N to the housing unit ( It can be drawn into the inner wall of 102N). Then, the stopper 108-1N connected to the stopper operation unit 108-4N by the connecting portion 108-5N is introduced into the inner wall of the housing portion 102N together with the stopper operation unit 108-4N. Then, the inner pocket 104N is drawn out to the inlet side of the housing portion 102N by the elastic force of the first elastic member 106N while the engagement by the stopper 108-1N is released. At this time, the stopper 108-1N and the stopper operation part 108-4N are pressed by the inner pocket 104N, and remain in the inside wall of the housing part 102N. Then, the second elastic member 108-2N is in a contracted state inside the guide portion 108-6N.

Referring to FIG. 54, the mobile device accommodation apparatus 100N may include an electromagnetic shield 126N. The electromagnetic shielding unit 126N serves to block electromagnetic waves generated from the wireless charging unit 120N from going out of the portable device storage device 100N. The electromagnetic shield 126N may be provided, for example, in a sheet form. In this case, the electromagnetic shielding unit 126N may be embedded in the outer side of the wireless charging unit 120N on the inner wall of the housing unit 102N.

In addition, the electromagnetic shield 126N may be provided on an outer surface of the housing 102N. In addition, the electromagnetic shield 126N may be provided at the inlet cover 112N.

The portable device storage device 100N may include an opening 128N in which at least one portion of the housing portion 102N and the inner pocket 104N are opened. The opening 128N may be provided in a through structure communicating with the outside so that external air may flow into the housing portion 102N. Outside air introduced into the opening 128N may be heat exchanged with the wireless charging unit 120N.

Although the present invention has been described in detail with reference to exemplary embodiments above, those skilled in the art to which the present invention pertains can make various modifications without departing from the scope of the present invention with respect to the above-described embodiments. Will understand. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

[Description of the code]

100; 200; 40Y; 100X; 100 W; 100T; 100R; 100Q: Wireless Charging Device

102; 202; 102Z; 102X; 102X; 102T; 102P; 102N: Mobile Device Housing

104; 204; 134Z; 134X; 134W: electromagnetic shield

106; 206; 104Z; 104X; 102 W; 113Q; 120N: Wireless Charging Part

108; 112P; 108P: Ion Generator

109; 219-b; 281d; 156aX; 121 W; 119-bQ; 181dQ; 104P; 108aN: Hanging part

110; 210; 114 W; 151Q; 110P: UV irradiation part

112; 212; 114Z; 114X; 116 W; 112P; 112N: Entrance Cover

112-1; 212-1; 112-1P: First Entrance Cover

112-2; 212-2; 112-2P: Second Entrance Cover

114: position fixing portion 114-1: first position fixing portion

114-2: second position fixing part 116: opening part

118; 218; 123 W; 118P: Protective Pads

Claims (47)

1. A portable device housing unit for storing the portable device; And

   A wireless charging device including a wireless charging unit for wirelessly charging the portable device,

   At least one surface of the housing portion of the portable device comprises an electromagnetic shielding means or made of electromagnetic shielding material to block the electromagnetic waves generated from the wireless charging unit to go out.
2. The method according to claim 1,

   The wireless charging device,

   The wireless charging device provided on the outside of the portable device housing, further comprising an electromagnetic shielding case made in whole or in part of the electromagnetic shielding material or containing an electromagnetic shielding material.
3. The method according to claim 1,

   One side of the portable device housing portion is provided with an inlet through which the portable device is inserted, and further includes an opening formed by opening an inner portion of the portable device housing portion,

   The foreign charging device introduced into the portable device housing part is discharged to the outside through the opening, or the outside air is introduced into the portable device housing part through the opening and heat exchanged with the wireless charging unit.
4. The method according to claim 1,

   The wireless charging device further includes a mounting case into which the portable device housing part is inserted and received, wherein the long case is a metal case that radiates heat generated from the wireless charging unit.
5. The method according to claim 1,

   The wireless charging device,

   The wireless charging device further comprises a protective pad or a plurality of protrusions formed on the inner surface of the portable device housing.
6. The method according to claim 1,

   The wireless charging device,

   A wireless charging module having the wireless charging unit; And

   Further comprising a wireless charging module deck for receiving the wireless charging module,

   The wireless charging module is detachably coupled to the inside of the wireless charging module deck, wireless charging device.
7. The method according to claim 6,

   And a wireless charging module corresponding to the wireless charging method is interchangeably mounted in the wireless charging module deck according to the wireless charging method of the portable device.
8. A housing part having a space in which the portable device can be inserted;

   A wireless charging unit provided in the housing unit to wirelessly charge the portable device;

   An electromagnetic shielding shield for shielding electromagnetic waves generated from the wireless charging unit; And

   And a mounting guide unit in which the electromagnetic shielding unit is replaceably mounted according to a wireless power frequency of the wireless charging unit.
9. The method according to claim 8,

   The electromagnetic shielding portion,

   The wireless charging method of the wireless charging unit includes at least one of Mn-Zn ferrite, Metglas, silver, and carbon in a wireless charging module including a WPC (Wireless Power Consortium) method or a PMA (Power Matters Alliance) method. Is provided to include, the wireless charging device.
10. The method according to claim 8,

    The electromagnetic shielding portion,

    The wireless charging method of the wireless charging unit is provided so that the nano-crystalline alloy of a soft magnetic material is included in a wireless charging module including a wireless power consortium (WPC) method or a power matters alliance (PMA) method.
11. The method according to claim 8,

    The electromagnetic shielding portion,

    And an electromagnetic shielding component is provided on the surface of the structure in which the electromagnetic shielding is provided by at least one method of deposition, spraying, printing, plating, or coating.
12. The method according to claim 11,

    The electromagnetic shielding portion,

    And a first electromagnetic shielding component is subjected to a first surface treatment on the surface, and a second electromagnetic shielding component is provided on a second surface treatment on an upper portion of the first electromagnetic shielding component.
13. A base station mounted on a vehicle,

    A first transmitter capable of transmitting a first wakeup signal;

    A second transmitter capable of transmitting a second wakeup signal; And

    And a control unit controlling the first transmitter and the second transmitter to transmit at least one of the first wakeup signal and the second wakeup signal.
14. The method according to claim 13,

    The first wakeup signal is a signal of a frequency band that interferes with the wireless power of the wireless charging device mounted on the vehicle, and the second wakeup signal is a frequency band that does not interfere with the wireless power of the wireless charging device. Base station.
15. The method according to claim 13,

    The first wakeup signal and the second wakeup signal are transmitted with a predetermined time difference in the order of the first wakeup signal and the second wakeup signal,

    And the second wakeup signal is generated by modulating the first wakeup signal.
16. A transponder for wireless communication with a base station mounted on a vehicle,

    A first receiver configured to receive a first wakeup signal transmitted from the base station;

    A second receiver configured to receive a second wake-up signal transmitted from the base station; And

    And a transmitter configured to transmit a response signal to the first wakeup signal or the second wakeup signal.
17. The method according to claim 16,

    The first wakeup signal is a signal of a frequency band that interferes with the wireless power of the wireless charging device mounted on the vehicle,

    And said second wake-up signal is a signal in a frequency band that does not interfere with wireless power of said wireless charging device.
18. The method according to claim 16,

    The second wakeup signal is,

    At least one of a signal strength and a frequency band is different from the first wakeup signal.
19. The method according to claim 16,

    The first wakeup signal and the second wakeup signal have different frequency bands,

    The transponder,

    And a multiband antenna arranged to receive the first wakeup signal and the second wakeup signal.
20. A communication method of a base station mounted on a vehicle and communicating with a transponder,

    Confirming, by the base station, whether a signal transmission event occurs; And

    When the signal transmission event occurs, the base station transmitting at least one of a first wake-up signal and a second wake-up signal to the transponder according to whether an interference target signal is present. Communication method.
21. The method of claim 20,

    The first wakeup signal is a signal of a frequency band causing interference with the interference target signal, and the second wakeup signal is a signal of a frequency band which does not interfere with the interference target signal. .
22. A communication method of a transponder that communicates with a base station mounted on a vehicle,

    The transponder receiving at least one of a first wakeup signal and a second wakeup signal from the base station; And

    Transmitting, by the transponder, a response signal to the base station in response to the first wakeup signal or the second wakeup signal.
23. The method according to claim 22,

    Receiving at least one of the first wakeup signal and the second wakeup signal may include transceiving the first wakeup signal from the base station when the signal of interest does not exist. Method of communication of the fenders.
24. An inlet is provided at one side and a housing part having a space for accommodating the portable device therein;

    A wireless charging unit provided in the housing unit, the wireless charging unit configured to wirelessly charge the portable device, and having one surface facing the portable device; And

    And a metal case provided outside the housing and radiating heat generated by the wireless charging unit.
25. The method of claim 24,

    The wireless charging device,

    A through part provided in the housing part;

    A catching part extending from the other surface of the wireless charging part, the locking part inserted into the through part to be caught by an outer surface of the housing part when one surface of the wireless charging part faces the portable device in the housing part; And

    At least one coupling member which closely couples the wireless charging unit to the metal case while fixing the wireless charging unit to the housing by coupling the housing unit and the metal case in the vicinity of the wireless charging unit, or the wireless charging unit and the metal case Wireless charging device comprising at least one of the heat transfer member provided between.
26. The method according to any one of claims 1, 8 or 24,

    The wireless charging device,

    A motion detector provided in the housing to detect a motion of a user; And

    And a lighting unit provided in the housing and operating according to the motion detection of the user.
27. The method according to any one of claims 1, 8 or 24,

    The wireless charging device is mounted on a vehicle internal structure and receives power from a battery mounted in the vehicle,

    The wireless charging device further comprises a battery discharge preventing unit for preventing the discharge of the battery.
28. An inlet is provided at one side and a housing part having a space for accommodating the portable device therein; A wireless charging unit provided in the housing unit, the wireless charging unit configured to wirelessly charge the portable device and having one surface facing the portable device;

    The wireless charging device, the wireless charging device is mounted to the vehicle internal structure, and includes a storage state notification unit for informing whether or not the storage of the portable device when the start of the vehicle is off.
29. The method according to claim 28,

    The wireless charging device,

    And a status notification unit for notifying at least one of an operating state of the wireless charging device and an incoming state of the portable device.
30. A wireless charging unit which wirelessly charges the portable device by transmitting a wireless power of a predetermined frequency; And

    A charging control unit controlling a wireless charging operation of the wireless charging unit;

    The charging control unit limits the wireless charging operation of the wireless charging unit according to the presence of the interference target signal.
31. The method of claim 30,

    The wireless charging apparatus may further include a signal detector configured to detect the interference target signal to generate an interference detection signal, and wherein the charging control unit limits the wireless charging operation of the wireless charger when the interference detection signal is generated. Wireless charging device.
32. The method of claim 30,

    The charging control unit,

    When the interference target signal exists, the operation of the wireless charger is limited and normalized for a predetermined time, the output of the wireless power is reduced, the power supply to the wireless charger is blocked, or the wireless charger is Changing the frequency of wireless power from the wireless charging device.
33. A transmission coil for generating a magnetic field;

    An attenuating device arranged to face the transmitting coil to generate a magnetic field to attenuate the magnetic field exiting the transmitting coil;

    And a controller configured to control a current supplied to the transmission coil and the attenuation coil.
34. The method according to claim 33,

    The attenuation device is a attenuation coil, and the control unit supplies a current according to the voltage signal having a phase opposite to the current supplied to the transmission coil to the attenuation coil.
35. The method according to claim 33,

    The wireless charging device includes a body for receiving the transmission coil and the damping device,

    The body may allow a charging object charged by the wireless charger to be disposed between the transmitting coil and the attenuating device, and a first distance between the receiving coil and the transmitting coil of the charging object is the receiving coil and the The wireless charging device configured to be smaller than the second distance between the damping devices.
36. The method according to claim 33,

    And the damping device is a damping coil, and the number of turns of the transmitting coil is larger than the number of turns of the attenuation coil.
37. The method according to claim 33,

    The wireless charging device is installed in the vehicle,

    The wireless charging device further includes a receiver for detecting a low frequency signal of the smart key module used in the vehicle,

    The control unit supplies a current to the attenuation device upon receiving a signal indicating that the low frequency signal has been detected from the receiver.
38. The method according to claim 33,

    The attenuation device is a wireless charging device that is a member made of a material capable of converting electromagnetic waves into far infrared rays.
39. The method of claim 34, wherein

    The damping device is printed or applied to the PCB or PBA, wireless charging device.
40. The method according to claim 33,

    The wireless charging device further includes a second attenuation device,

    And the second damping device is arranged such that the transmitting coil is positioned between the second damping device and the damping device.
41. A wireless charging device mounted in a vehicle,

    A first accommodating unit accommodating the first portable device;

    A second accommodating unit accommodating a second portable device;

    A wireless charging module configured to wirelessly charge the second portable device by transmitting wireless power of a predetermined frequency; And

    It includes a storage detector for detecting whether the first portable device is stored,

    And the wireless charging device limits generation of a signal transmitted from the vehicle to the first portable device when the first portable device is accommodated in the first housing.
42. The method of claim 41,

    The first mobile device is a smart key,

    The wireless charging device is configured to prevent the base station of the vehicle from transmitting a low frequency signal to the smart key when the smart key is stored in the first accommodating part.
43. The method of claim 41,

    The wireless charging module,

    And wirelessly charging the second portable device normally while the base station of the vehicle does not transmit a low frequency signal to the smart key.
44. The method of claim 41,

    The wireless charging device,

    When the smart key is separated from the first accommodating part, the output of the wireless power is reduced, the power supply to the wireless charging module is cut off for a preset time, or the frequency of the wireless power is changed. Wireless charging device.
45. A wireless charging device mounted in a vehicle to which a smart key system including a smart key and a base station is applied,

    An accommodation unit for storing the smart key;

    A wireless charging module for wirelessly charging a portable device by transmitting wireless power of a predetermined frequency;

    A storage detecting unit detecting whether the smart key is stored; And

    And a charging controller configured to operate the wireless charging module in a charge normal mode or a charge limit mode according to whether the smart key is stored.
46. The method of claim 45,

    When the storage detection signal is transmitted from the storage detection unit,

    And the charging control unit generates a low frequency limit signal to the base station, and operates the wireless charging module in a charging normal mode.
47. The method of claim 45,

    When the storage departure signal is transmitted from the storage detection unit,

    And the charging control unit generates a low frequency limit cancel signal to the base station, and operates the wireless charging module in a charge limit mode.

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