WO2013159548A1 - 无线充电装置、功率接收装置及无线平板充电系统 - Google Patents

无线充电装置、功率接收装置及无线平板充电系统 Download PDF

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Publication number
WO2013159548A1
WO2013159548A1 PCT/CN2012/087063 CN2012087063W WO2013159548A1 WO 2013159548 A1 WO2013159548 A1 WO 2013159548A1 CN 2012087063 W CN2012087063 W CN 2012087063W WO 2013159548 A1 WO2013159548 A1 WO 2013159548A1
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Prior art keywords
electrodes
electrode
wireless charging
circuit
charging device
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PCT/CN2012/087063
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English (en)
French (fr)
Inventor
麦华彬
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深圳市非凡创新实业有限公司
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Application filed by 深圳市非凡创新实业有限公司 filed Critical 深圳市非凡创新实业有限公司
Priority to US14/396,587 priority Critical patent/US20150091512A1/en
Publication of WO2013159548A1 publication Critical patent/WO2013159548A1/zh

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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02JCIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
    • H02J7/00Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
    • H02J7/02Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries for charging batteries from ac mains by converters
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02JCIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
    • H02J7/00Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
    • H02J7/0029Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries with safety or protection devices or circuits
    • H02J7/00304Overcurrent protection

Definitions

  • the present invention relates to a charging device, and more particularly to a wireless charging device, a power receiving device, and a wireless tablet charging system.
  • the technical problem to be solved by the present invention is to provide a wireless charging device that is convenient to use and has good versatility.
  • Another technical problem to be solved by the present invention is to provide a power receiving device that can be used on the wireless charging device.
  • Another technical problem to be solved by the present invention is to provide a wireless tablet charging system that is convenient to use and versatile.
  • a wireless charging device includes a supporting body, at least two electrodes are disposed on a surface of the supporting body, and an insulating gap is formed between the electrodes; each of the electrodes is respectively connected to a charging power source; the shape of the electrode is a rule Shape or irregular shape.
  • the electrode includes a first electrode and a second electrode, and the second electrode surrounds the periphery of the first electrode.
  • the distance between the first electrode and the second electrode is equal, and the periphery of the second electrode is further provided with a limiting flange.
  • the support body is a flat body; the electrodes include two or more, and the electrodes are arranged equidistantly or unequally on the flat body.
  • the charging power source includes a power supply circuit electrically connected to the electrode; the power supply circuit is disposed on the support body or separately from the support body.
  • the power supply circuit includes a detection circuit, a switch circuit, a control circuit, and a power supply circuit connected to the detection circuit, the switch circuit, and the control circuit;
  • the detecting circuit is electrically connected to each of the electrodes for detecting whether the electrode has a conductive contact of the power receiving device in contact with the electrode;
  • the switch circuit is electrically connected to each of the electrodes for turning on or off power supply of the electrodes;
  • the control circuit is connected to the detecting circuit and the switch circuit, and is configured to send a control signal to the switch circuit according to whether each of the electrodes detected by the detecting circuit has a conductive contact in contact with the switch circuit, and control each device The electrode is turned on or off from the power circuit.
  • the switching circuit includes a positive switching circuit and a negative switching circuit that are simultaneously connected to each of the electrodes;
  • the detecting circuit includes a plurality of detecting units, and each of the detecting units is electrically connected to one of the electrodes;
  • the positive switch circuit includes a plurality of positive switch units, and each of the positive switch units is electrically connected to one of the electrodes;
  • the negative switch circuit includes a plurality of negative switch units, and each of the negative switch units is electrically connected to one of the electrodes;
  • the control circuit controls the positive switch unit and the negative switch unit connected to the same electrode to be selectively turned on or off at the same time.
  • the present invention also provides a power receiving device that can be used in combination with any of the wireless charging devices described above, including at least two conductive contacts;
  • a shortest distance of an edge of the single conductive contact is greater than a size of an insulating gap between electrodes of the wireless charging device; and a minimum distance between edges of adjacent conductive contacts is greater than a maximum of edges of a single of the electrodes distance.
  • the power receiving device further includes a power module electrically connected to the conductive contact, the power module including a toy, a game device, a mobile phone, a battery, a charger, a handheld device, and a power tool , power connector, electric cup, music player, camera, calculator, remote control, video recorder, video player, fax machine, PDA beauty equipment, electric shaver, electric toothbrush, hair clipper, TV, refrigerator One or more of them.
  • a power module electrically connected to the conductive contact
  • the power module including a toy, a game device, a mobile phone, a battery, a charger, a handheld device, and a power tool , power connector, electric cup, music player, camera, calculator, remote control, video recorder, video player, fax machine, PDA beauty equipment, electric shaver, electric toothbrush, hair clipper, TV, refrigerator One or more of them.
  • the power receiving device further includes a housing, the conductive contact is disposed on the housing, and the housing is further provided with an interface module electrically connected to the conductive contact .
  • the present invention also provides a wireless charging system, comprising the wireless charging device of any one of the above, and the power receiving device of any of the above; the power receiving device is placed on the wireless charging device, and The two conductive contacts of the power receiving device are in conductive contact with at least two electrodes of the wireless charging device, respectively, and the wireless receiving device supplies power to the power receiving device.
  • the invention has the following beneficial effects: the power receiving device is placed on the wireless charging device, the conductive contact of the power receiving device is in contact with the electrode of the wireless charging device, and the electrode is directly used to supply the conductive contact, thereby avoiding the need in the prior art.
  • the inconvenience caused by the power plug has the advantages of convenient use and good versatility.
  • the shortest distance of the edge of the single conductive contact is set to be larger than the size of the insulating gap between the electrodes of the wireless charging device; and the distance between the edges of the adjacent conductive contacts is greater than the maximum distance of the edge of the single electrode, so that the power receiving device can Arbitrarily placed on the support body of the wireless charging device, the electrical connection between the conductive contacts and the electrodes can be realized, which makes the use more convenient and convenient.
  • a plurality of power receiving devices can be simultaneously placed on the wireless charging device, thereby realizing the function of simultaneously supplying power to the plurality of power receiving devices, thereby avoiding the trouble of using multiple power adapters in the prior art.
  • FIG. 1 is a schematic diagram of an embodiment of a wireless charging device of the present invention
  • FIG. 2 is a schematic view showing the electrode of the wireless charging device of the present invention having a circular shape
  • FIG. 3 is a schematic view showing the electrode of the wireless charging device of the present invention being rectangular;
  • FIG. 4 is a schematic view showing that the electrodes of the wireless charging device of the present invention are circular and staggered;
  • Figure 5 is a schematic block diagram of a power supply circuit of the wireless charging device and the charging power source of the present invention
  • Figure 6 is a schematic diagram of an embodiment of a power receiving device of the present invention.
  • Figure 7 is a schematic diagram showing a state in which the power receiving device of the present invention is placed on the wireless charging device
  • Figure 8 is a schematic view showing another state in which the power receiving device of the present invention is placed on the wireless charging device;
  • Figure 9 is a schematic view showing the operation of the power receiving device of the present invention.
  • FIG. 10 is a schematic view showing another embodiment of the wireless charging device of the present invention in which the electrodes are circular;
  • FIG 11 is a schematic view showing another embodiment of the wireless charging device of the present invention in which the electrodes are square.
  • an embodiment of the wireless charging device 100 of the present invention can be used to provide a power supply platform for the power receiving device to facilitate use of the power receiving device.
  • the wireless charging device 100 includes a support body 110 having a plurality of electrodes 111 disposed on a surface of the support body 110 and an insulating slit 112 between the electrodes 111 to separate the plurality of electrodes 111.
  • Each of the electrodes 111 can be respectively connected to a charging power source to be powered by the power source.
  • the support body 110 of the present embodiment is a flat body, and the shape and size of the flat body can be adjusted as needed.
  • the electrodes 111 are square and are arranged equidistantly on the support body 110 in a matrix form. It can be understood that the shape of the electrode 111 can also be set to other shapes as needed, such as a circular shape (as shown in FIG. 2), a rectangular shape (as shown in FIG. 3), a prismatic shape, a trapezoidal shape, an irregular shape, and the like.
  • the electrodes 111 are generally arranged in a regular equidistant manner. Of course, in some cases where special design is required, the electrodes 111 may also be arranged in an unequal or irregular arrangement. As shown in FIG. 4, it is a schematic diagram in which the electrodes 111 are arranged in a staggered manner.
  • the number of the electrodes 111 may be designed as needed, as long as two or more are included.
  • the support body 110 is an insulating flat body; the electrode 111 is directly attached to the surface of the support body 110, and the insulating slit 112 is naturally formed between the electrodes 111; of course, the support body 110 may be provided with a groove.
  • the card 111 is embedded and fixed to the support body 110. Further, an insulating paste or the like may be potted between the electrodes 111 to prevent shorting between the electrodes 111.
  • the electrode 111 of the wireless charging device 100 is connected to a charging power source.
  • the charging power source includes a power supply circuit electrically connected to the electrode 111.
  • the power supply circuit can be directly disposed in the support body 110, or the power supply circuit can be disposed in a separate outer casing, and then electrically connected to the electrode 111 through wires, wires, contacts, and the like.
  • the power supply circuit includes a detection circuit 120, a switch circuit 130, a control circuit 140, and a power supply circuit connected to the detection circuit 120, the switch circuit 130, and the control circuit 140 for supplying power.
  • the detecting circuit 120 is electrically connected to each of the electrodes 111 for detecting whether the electrode 111 has the conductive contact 151 in contact therewith.
  • a plurality of detecting units 121 each of which is electrically connected to one of the electrodes 111.
  • the micro voltage is applied to the electrode 111 through the detecting unit 121, so that each electrode 111 is in a state to be detected to detect whether the conductive contact 151 is in contact; and when the conductive contact 151 is in contact, a trigger signal is generated to the control circuit. 140, the judgment setting is made.
  • the switch circuit 130 is electrically connected to each of the electrodes 111 for turning on or off the power supply of the electrodes 111.
  • the switch circuit 130 includes a positive switch circuit and a negative switch circuit that are simultaneously connected to each of the electrodes 111.
  • the control circuit 140 selects the positive switch circuit or the negative switch circuit to operate, and turns on the corresponding electrode 111.
  • the positive switch circuit includes a plurality of positive switch units 131, each positive switch unit 131 is electrically connected to one electrode 111;
  • the negative switch circuit includes a plurality of negative switch units 132, and each negative switch unit 132 and one
  • the electrodes 111 are electrically connected.
  • Each of the electrodes 111 is connected to one positive switch unit 131 and one negative switch unit 132 one by one, thereby achieving arbitrary setting of the polarity of the electrode 111.
  • the control circuit 140 is connected to the detection circuit 120 and the switch circuit 130 for issuing a control signal to the switch circuit 130 according to whether each electrode 111 detected by the detection circuit 120 has a conductive contact 151 in contact with it, and controls each electrode 111 to The power circuit is turned on or off.
  • the control circuit 140 can be set to be turned on or off at the same time by controlling the positive switch unit 131 and the negative switch unit 132 connected to the same electrode 111, so that the polarity of the electrode 111 can be set.
  • the control circuit 140 includes a detection setting module 141 and a control module 142.
  • the detection setting module 141 is connected to the detection circuit 120 for scanning the other electrodes 111 based on the trigger signal input from the detection circuit 120, and using one of the electrodes 111 with the conductive contacts 151 in contact, and using the same as the reference.
  • the electrode 111 short-circuited by the electrode 111 is set to the same polarity, and the electrode 111 which is not further short-circuited to the electrode 111 as a reference is set to the other polarity.
  • the control module 142 is connected to the switch circuit 130 and the detection setting module 141. According to the result set by the detection setting module 141, the switch control signal is output to the switch circuit 130, and the switch circuit 130 controls the turn-on polarity of the corresponding electrode 111 or Disconnected, etc.
  • the polarity of the conductive contact that is in contact with the electrode can be detected by the detecting unit of the corresponding power supply circuit.
  • the polarity of the input end of the power module when it is detected as the positive pole, controls the corresponding positive switch unit to turn on the connection of the electrode and the positive output end of the power circuit; when it is detected that the negative pole is detected, the corresponding negative switch unit is turned on.
  • the power supply circuit may not detect the polarity of the conductive contact that is in contact with the electrode, and the control circuit arbitrarily designates the electrode to be connected to the positive output terminal or the negative output terminal of the power supply circuit, and detects the conductive contact between the power receiving device and the power receiving device.
  • the polarity of the contacted electrode ie the polarity of the output of the power supply circuit connected to the electrode
  • the two outputs of the power supply circuit are connected to the two inputs of the power module.
  • the wireless charging device 100 may further include a security protection circuit, an overcurrent protection circuit, and a power sensing circuit to ensure the security and stability of the wireless charging device 100.
  • the power receiving device 150 includes two conductive contacts 151 that are in contact with the electrodes 111 of the wireless charging device 100, and the power source is connected to provide power to the power receiving device 150.
  • the power receiving device 150 includes two conductive contacts 151 that are in contact with the electrodes 111 of the wireless charging device 100, and the power source is connected to provide power to the power receiving device 150.
  • more than two conductive contacts 151 can be provided as needed for ease of use.
  • the two conductive contacts 151 need to be used in conjunction with the electrode 111 of the wireless charging device 100.
  • the shortest distance D of the edge of the single conductive contact 151 is greater than the size X of the insulating gap 112 between the electrodes 111, thereby avoiding The conductive contact 151 entirely falls into the insulating slit 112, ensuring that the conductive contact 151 is always in conductive contact with the electrode 111 when the power receiving device 150 is placed on the support body 110.
  • the minimum distance C between the edges of the adjacent conductive contacts 151 is greater than the maximum distance L of the edges of the individual electrodes 111, thereby ensuring that the adjacent conductive contacts 151 are not in conductive contact with the same electrode 111 at the same time, that is, It is ensured that the adjacent two conductive contacts 151 are always in conductive contact with two different electrodes 111, thereby ensuring that the two electrodes 111 can be set with different polarities to form a power supply loop.
  • the power receiving device 150 further includes a power module coupled to the conductive contact 151, the power module including a toy, a gaming device, a mobile phone, a battery, a charger, a handheld device, a power tool, a power connector, a hot cup, a music player, One or more of a camera, a calculator, a remote controller, a video recorder, a video player, a fax machine, a PDA beauty device, an electric shaver, an electric toothbrush, a hair clipper, a television, and a refrigerator. Power is supplied to the power modules directly through the conductive contacts 151.
  • the power receiving device 150 can include a housing with a conductive contact 151 disposed on the back or other location of the housing, while an interface module electrically coupled to the conductive contacts 151 is disposed within the housing.
  • the housing matches the shape of the electronic device (eg, cell phone, PDA, tablet, etc.), and the interface module matches the charging interface of the electronic device.
  • the outer casing is sleeved on the periphery of the electronic device, and the interface module is inserted into the charging interface of the electronic device, so that the conductive contact 151 is used to access the power source, and the interface module is transmitted to the electronic device to supply power to the electronic device.
  • the wireless charging device 100 and the power receiving device 150 constitute a wireless charging system.
  • the power receiving device 150 is directly placed on the wireless charging device 100, and the two conductive contacts 151 of the power receiving device 150 and the wireless charging device are respectively At least two electrodes 111 of 100 are in conductive contact, and the power receiving device 150 is powered by the wireless charging device 100.
  • each of the detecting units 121 of the detecting circuit 120 is loaded with a micro voltage on its correspondingly connected electrode 111 such that each of the electrodes 111 is in a state to be detected.
  • the detecting electrode 111 is in contact with the conductive contact 151 of the power receiving device 150.
  • the micro voltage on the electrode 111 changes, thereby generating a trigger signal to be sent to the control circuit 140, and receiving by the control circuit 140, it can be determined whether the electrode 111 has the conductive contact 151. .
  • the detection setting module 141 of the control circuit 140 sequentially scans the other electrodes 111 based on the trigger signal of the detecting unit 121 with one of the electrodes 111 having the conductive contacts 151 in contact with each other.
  • the electrode 111 short-circuited by the reference electrode 111 is set to the same polarity, and the electrode 111 which is not further short-circuited to the electrode 111 as a reference is set to the other polarity. As shown in FIG. 7 and FIG.
  • FIG. 8 it is a schematic diagram of several cases in which the conductive contact 151 is in contact with the electrode 111.
  • the two electrodes 111 can be simply separated. It is set as one positive electrode and one negative electrode, as shown in FIG. 7; when the conductive contact 151 is in contact with the plurality of electrodes 111 at the same time, all the electrodes 111 that are simultaneously in contact can be set to the same polarity, and the plurality of electrodes 111 are simultaneously Power supply, as shown in Figure 8.
  • the power source corresponding to the polarity is turned on.
  • the control module 142 of the control circuit 140 transmits a corresponding control signal to the positive electrode during control.
  • the switch unit 131 and the negative switch unit 132 control the corresponding positive switch circuit or the negative switch circuit connected to the electrode 111 to be connected to realize the power supply circuit, and the power receiving device 150 is connected to the power source.
  • the electrode on the support body of the wireless charging device 200 includes a first electrode 211a and a second electrode 211b.
  • the second electrode 211b surrounds the periphery of the first electrode 211a, and has an insulating slit 212 between the first electrode 211a and the second electrode 211b.
  • the insulating gap 212 may be filled with an insulating material; of course, the supporting body may be left blank when it is made of an insulating material.
  • the first electrode 211a and the second electrode 211b adopt a regular shape, such as a circular shape (FIG. 10) or a square shape (FIG. 11).
  • a regular shape such as a circular shape (FIG. 10) or a square shape (FIG. 11).
  • other shapes such as an elliptical shape, a prismatic shape, and a trapezoidal shape may also be adopted. Irregular shapes, etc.
  • the distance between the insulating slits 212 between the first electrode 211a and the second electrode 211b is equal, thereby facilitating the random placement of the power receiving device.
  • the distance between the insulating slits 212 can also be adjusted to be unequal or arranged according to the need, and the distance of the conductive contacts of the power receiving device can be adjusted correspondingly.
  • a limiting flange 213 is further disposed on the periphery of the second electrode 211b, so that the power receiving device can be placed within a range defined by the limiting flange 213. Ensure conductive contact between the conductive contacts and the electrodes.

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  • Power Engineering (AREA)
  • Charge And Discharge Circuits For Batteries Or The Like (AREA)

Abstract

一种无线充电装置、功率接收装置及无线平板充电系统。该无线充电装置(100)包括支撑主体(110),在支撑主体表面设有至少两个电极(111),电极之间具有绝缘缝隙(112);每一电极分别连接至充电电源。该功率接收装置(150)包括至少两个导电触点(151),单个导电触点的边缘最短距离D大于无线充电装置的电极之间的绝缘缝隙(112)的大小X;并且,相邻导电触点边缘之间的最小距离C大于单个电极的边缘的最大距离L。功率接收装置放置在无线充电装置上,功率接收装置的导电触点与无线充电装置的电极接触,利用电极直接为导电触点供电,具有使用方便、通用性好的优点。

Description

无线充电装置、功率接收装置及无线平板充电系统 技术领域
本发明涉及充电装置,更具体地说,涉及一种无线充电装置、功率接收装置及无线平板充电系统。
背景技术
随着科技的发展,越来越多的用电设备在人们的生活中使用。在使用该等用电设备时,通常是直接通过电源插头等,直接接入电源为用电设备供电,或者为用电设备的电池供电。然而随着用电设备的增多,电源插头也会随之增加。这样对使用者造成了使用上的不便。
另外,不同的用电设备通常使用不同的电源插口,需要配备不同电源插头的适配器,因而,使得使用者有很多电源适配器,不利于节能环保,造成极大的资源浪费。
另外,在需要进行多个用电设备同时充电时,要同时使用多个电源适配器,增加了插板的使用,而且电源适配器的连接线很容易发生缠绕,造成使用者的使用不便 。
发明内容
本发明要解决的技术问题在于,提供一种使用方便、通用性好的无线充电装置。
本发明所要解决的另一技术问题在于,提供一种可在该无线充电装置上使用的功率接收装置。
本发明所要解决的另一技术问题在于,提供一种使用方便、通用性好的无线平板充电系统。
本发明解决其技术问题所采用的技术方案是:提供 一种无线充电装置,包括支撑主体,在所述支撑主体表面设有至少两个电极,所述电极之间具有绝缘缝隙;每一所述电极分别连接至充电电源;所述电极的形状为规则形或不规则形。
在本发明的无线充电装置中,所述电极包括第一电极和第二电极,所述第二电极包围在所述第一电极外围。
在本发明的无线充电装置中,所述第一电极与第二电极之间的所述绝缘缝隙的距离相等,并且,所述第二电极外围还设有限位凸缘。
在本发明的无线充电装置中,所述支撑主体为平板状主体;所述电极包括两个以上,并且所述电极之间为等距或不等距排列在所述平板状主体上。
在本发明的无线充电装置中,所述充电电源包括与所述电极电连接的供电电路;所述供电电路设置在所述支撑主体上、或者与所述支撑主体分开设置。
在本发明的无线充电装置中,所述供电电路包括检测电路、开关电路、控制电路以及与所述检测电路、开关电路、控制电路连接供电的电源电路;
所述检测电路与每一所述电极电连接,用于检测所述电极是否有功率接收装置的导电触点与其接触;
所述开关电路与每一所述电极电连接,用于接通或断开所述电极的供电;
所述控制电路与所述检测电路、开关电路连接,用于根据所述检测电路检测到的每一所述电极是否有导电触点与其接触来发出控制信号至所述开关电路,控制每一所述电极与所述电源电路的接通或断开。
在本发明的无线充电装置中,所述开关电路包括与每一所述电极同时连接的正极开关电路以及负极开关电路;
所述检测电路包括多个检测单元,每一所述检测单元与一个所述电极对应电连接;
所述正极开关电路包括多个正极开关单元,每一所述正极开关单元与一个所述电极电连接;
所述负极开关电路包括多个负极开关单元,每一所述负极开关单元与一个所述电极电连接;
所述控制电路控制与同一所述电极连接的所述正极开关单元和负极开关单元择一接通或同时断开。
本发明还提供一种功率接收装置,可与上述任一种所述的无线充电装置配合使用,包括至少两个导电触点;
单个所述导电触点的边缘最短距离大于所述无线充电装置的电极之间的绝缘缝隙的大小;并且,相邻所述导电触点边缘之间的最小距离大于单个所述电极的边缘的最大距离。
在本发明的功率接收装置中,所述功率接收装置还包括与所述导电触点电连接的功率模块,所述功率模块包括玩具、游戏设备、手机、电池、充电器、手持设备、电动工具、功率连接器、电热杯、音乐播放器、照相机、计算器、遥控器、录像机、视频播放器、传真机、PDA美容设备、电动剃须刀、电动牙刷、电推剪、电视机、电冰箱中的一种或多种。
在本发明的功率接收装置中,所述功率接收装置还包括一外壳,所述导电触点设置在所述外壳上,并且,所述外壳还设有与所述导电触点电连接的接口模块。
本发明还提供一种无线充电系统,包括上述任一种所述的无线充电装置、以及上述任一种所述的功率接收装置;所述功率接收装置放置在所述无线充电装置上,并且所述功率接收装置的两个导电触点分别与所述无线充电装置的至少两个电极导电接触,由所述无线充电装置为所述功率接收装置供电。
实施本发明具有以下有益效果:功率接收装置放置在无线充电装置上,功率接收装置的导电触点与无线充电装置的电极接触,利用电极直接为导电触点供电,避免了现有技术中需要使用电源插头所带来的不便,具有使用方便、通用性好的优点。
另外,通过将 单个导电触点的边缘最短距离设置为大于无线充电装置的电极之间的绝缘缝隙的大小;并且,相邻导电触点边缘之间的距离大于单个电极的边缘的最大距离,使得功率接收装置可以任意放置在无线充电装置的支撑主体上,都能够实现导电触点与电极之间的电连接,使得使用更加的方便,便捷。
另外,可以通过设置多个电极,多个功率接收装置可以同时放置在无线充电装置上,实现了为多个功率接收装置同时供电的功能,避免了现有技术需要使用多个电源适配器的麻烦 。
附图说明
下面将结合附图及实施例对本发明作进一步说明,附图中:
图1是本发明无线充电装置的一个实施例的示意图;
图2是本发明无线充电装置的电极为圆形的示意图;
图3是本发明无线充电装置的电极为长方形的示意图
图4是本发明无线充电装置的电极为圆形并错开排列的示意图;
图5是本发明无线充电装置和充电电源的供电电路的示意框图;
图6是本发明功率接收装置的一个实施例的示意图;
图7是本发明的功率接收装置放置在无线充电装置上的一种状态的示意图;
图8是本发明的功率接收装置放置在无线充电装置上的另一种状态的示意图;
图9是本发明的功率接收装置的工作过程示意图;
图10是本发明无线充电装置的另一实施例电极为圆形的示意图;
图11是本发明无线充电装置的另一实施例电极为方形的示意图。
具体实施方式
如图1~4所示,是本发明的无线充电装置100的一个实施例,可用于为功率接收装置提供供电平台,以方便功率接收装置的使用。
该无线充电装置100包括支撑主体110,在支撑主体110表面设有多个电极111,并且在电极111之间为绝缘缝隙112,从而将多个电极111分别隔开。每一电极111可分别连接至充电电源,以接入电源供电。
如图所示,本实施例的支撑主体110为平板状主体,该平板状主体的形状、尺寸可以根据需要进行调整。
该电极111为正方形,并且按矩阵形式等距排列在支撑主体110上。可以理解的,该电极111的形状还可以根据需要设置为其他形状,例如圆形(如图2所示)、长方形(如图3所示)、棱形、梯形、不规则形等。
为了方便电极111的布置,通常电极111之间采用规则的等距排列,当然,在一些需要特殊设计的场合,该等电极111也可以采用不等距或不规则排列方式排列。如图4所示,是电极111错开排列的示意图。
进一步的,电极111的数量可以根据是需要进行设计,只要包括两个以上即可。在本实施例中,该支撑主体110为绝缘平板状主体;电极111直接贴设在支撑主体110表面,电极111之间就自然形成绝缘缝隙112;当然,也可以在支撑主体110上设置凹槽、卡位等,将电极111嵌入固定在支撑主体110上。另外,还可以在电极111之间灌封绝缘胶等,防止电极111之间的短接。
如图5所示,该无线充电装置100的电极111连接至充电电源,在本实施例中,该充电电源包括与电极111电连接的供电电路。该供电电路可以直接设置在支撑主体110内,也可以将供电电路设置在一个独立的外壳内,再通过导线、排线、触点等方式与电极111导电连接。
该供电电路包括检测电路120、开关电路130、控制电路140以及与检测电路120、开关电路130、控制电路140连接供电的电源电路。
结合图5和图6所示,该检测电路120与每一电极111电连接,用于检测电极111是否有导电触点151与其接触。多个检测单元121,每一检测单元121与一个电极111对应电连接。通过该检测单元121在电极111上加载微电压,使得每个电极111都处于待检测状态,以检测是否有导电触点151接触;并在有导电触点151接触时,产生触发信号至控制电路140,进行判断设定。
该开关电路130与每一电极111电连接,用于接通或断开电极111的供电。在本实施例中,该开关电路130包括与每一电极111同时连接的正极开关电路以及负极开关电路,通过控制电路140来选择正极开关电路或负极开关电路工作,接通对应的电极111。
在本实施例中,该正极开关电路包括多个正极开关单元131,每一正极开关单元131与一个电极111电连接;负极开关电路包括多个负极开关单元132,每一负极开关单元132与一个电极111电连接。每一电极111一一对应连接有一个正极开关单元131和一个负极开关单元132,从而实现电极111的极性的任意设定。
该控制电路140与检测电路120、开关电路130连接,用于根据检测电路120检测到的每一电极111是否有导电触点151与其接触来发出控制信号至开关电路130,控制每一电极111与电源电路的接通或断开。在本实施例中,控制电路140可以通过控制与同一电极111连接的正极开关单元131和负极开关单元132择一接通或同时断开,从而可以设定电极111的极性。
如图5所示,该控制电路140包括检测设定模块141以及控制模块142。该检测设定模块141与检测电路120连接,用于根据检测电路120输入的触发信号,以其中一个有导电触点151接触的电极111为基准,对其他电极111进行扫描,将与该作为基准的电极111短接的电极111设定为同一极性,而将另外没有与作为基准的电极111短接的电极111设定为另一极性。
该控制模块142与开关电路130、检测设定模块141连接,根据检测设定模块141设定的结果,输出开关控制信号至开关电路130,由开关电路130控制对应电极111的接通极性或断开等。
另外,需要说明的是,当电极与功率接收装置的导电触点接触后,可通过相应供电电路的检测单元检测与该电极所接触的导电触点的极性(即与该导电触点连接的功率模块的输入端的极性),当检测到是正极时,控制相应的正极开关单元接通该电极与电源电路正输出端的连接;当检测到是负极时,控制相应的负极开关单元接通该电极与电源电路负输出端的连接。当然,供电电路也可不检测与该电极所接触的导电触点的极性,控制电路任意指定该电极与电源电路的正输出端或负输出端连接,而在功率接收装置内检测与其导电触点接触的电极的极性(即与该电极连接的电源电路输出端的极性),并将电源电路两个输出端相应接到功率模块的两输入端。
进一步的,该无线充电装置100还可以包括安全保护电路、过流保护电路、以及功率感测电路等,以保证无线充电装置100工作的安全、稳定性。
如图6所示,是本发明的功率接收装置150的一个实施例的示意图,可与上述无线充电装置100配合使用。结合图7,该功率接收装置150包括两个导电触点151,可与无线充电装置100的电极111相接触,接入电源为功率接收装置150提供电源。当然,可以根据需要设置两个以上的导电触点151,以方便使用。
请参见图8,该两个导电触点151需要与无线充电装置100的电极111相配合使用,单个导电触点151的边缘最短距离D大于电极111之间的绝缘缝隙112的大小X,从而避免导电触点151整个落入绝缘缝隙112中,保证了在将功率接收装置150放置在支撑主体110上时,导电触点151始终与电极111导电接触。
同时,相邻的导电触点151边缘之间的最小距离C大于单个电极111的边缘的最大距离L,从而保证相邻的导电触点151不会同时与同一电极111导电接触,也就是说,保证了相邻的两个导电触点151始终与两个不同的电极111导电接触,从而保证了两个电极111可以设置不同的极性,形成供电回路。
该功率接收装置150还包括与导电触点151连接的功率模块,该功率模块包括玩具、游戏设备、手机、电池、充电器、手持设备、电动工具、功率连接器、电热杯、音乐播放器、照相机、计算器、遥控器、录像机、视频播放器、传真机、PDA美容设备、电动剃须刀、电动牙刷、电推剪、电视机、电冰箱中的一种或多种。通过导电触点151接入电源,直接为该等功率模块提供电源。
在另一种实施方式中,该功率接收装置150可以包括一外壳,导电触点151设置在外壳的背面或其他位置,同时,在该外壳内设置有与导电触点151电连接的接口模块。该外壳与电子设备(如手机、PDA、平板电脑等)的形状匹配,而接口模块与电子设备的充电接口匹配。将外壳套设在电子设备外围,并将接口模块插入到电子设备的充电接口,从而利用导电触点151接入电源,通过接口模块传送至电子设备,为电子设备供电。
上述无线充电装置100和功率接收装置150组成了无线充电系统,使用时,直接将功率接收装置150放置在无线充电装置100上,并且功率接收装置150的两个导电触点151分别与无线充电装置100的至少两个电极111导电接触,由无线充电装置100为功率接收装置150供电。
如图9所示,使用该无线充电系统进行无线充电时,首先,将无线充电装置100的电极111设置在检测状态。在本实施例中,通过检测电路120的每个检测单元121在其对应连接的电极111上加载微电压,使得每个电极111处于待检测状态。
然后,检测电极111是否有功率接收装置150的导电触点151接触。当电极111上有导电触点151接触时,电极111上的微电压产生变化,从而产生触发信号发送至控制电路140,由控制电路140接收,即可判断电极111是否有导电触点151接入。
然后,判定有导电触点151接触的所有电极111的关联性,并分别设定该等电极111的极性。在本实施例中,控制电路140的检测设定模块141根据检测单元121的触发信号,以其中一个有导电触点151接触的电极111为基准,对其他电极111进行依次扫描,将与该作为基准的电极111短接的电极111设定为同一极性,而将另外没有与作为基准的电极111短接的电极111设定为另一极性。如图7、8所示,是导电触点151与电极111的接触的几种情况的示意图,当两个导电触点151分别与两个电极111接触时,可以简单的将两个电极111分别设定为一个正极、一个负极,如图7所示;当导电触点151同时与多个电极111接触时,可以将同时接触的所有电极111设定为同一极性,通过多个电极111同时供电,如图8所示。
可以理解的,当多个功率接收装置150同时放置在无线充电装置100上时,同样可以执行上述操作,来设定极性,可以同时为多个功率接收装置150供电。
然后,根据电极111所设定的极性,接通与极性相对应的电源。在本实施例中,由于每一电极111连接有正极开关电路的正极开关单元131和负极开关电路的负极开关单元132,在控制时,由控制电路140的控制模块142发送对应的控制信号至正极开关单元131和负极开关单元132,控制与电极111连接的对应的正极开关电路或负极开关电路接通,即可实现供电回路,为功率接收装置150接入电源。
如图10、11所示,是本发明无线充电装置200的另一实施例的示意图。该无线充电装置200的支撑主体上的电极包括第一电极211a和第二电极211b。第二电极211b包围在第一电极211a外围,并且在第一电极211a和第二电极211b之间具有绝缘缝隙212。在绝缘缝隙212中可以填充绝缘材料;当然,该支撑主体采用绝缘材料制作时直接留空即可。
在本实施例中,该第一电极211a和第二电极211b采用规则形状,如圆形(图10)或方形(图11),当然也可以采用其他形状,如椭圆形、棱形、梯形、不规则形状等。
如图所示,第一电极211a和第二电极211b之间的绝缘缝隙212的距离相等,从而便于功率接收装置的随意放置。当然,绝缘缝隙212的距离也可以根据需要调整为不等或按规律排布,对应调整功率接收装置的导电触点的距离即可。
进一步的,为了放置功率接收装置超出无线充电装置200的电极供电范围,在第二电极211b的外围还设有限位凸缘213,使得功率接收装置可以放置在限位凸缘213限定的范围内,保证导电触点与电极之间的导电接触。
本实施例的其他结构、工作原理与上一实施例基本相同,故不赘述。
此外,本发明是通过实施例进行描述的,但本发明不局限于实施例。本领域技术人员知悉,在不脱离本发明的范围情况下,可以 进行各种改变。

Claims (11)

  1. 一种无线充电装置,其特征在于,包括支撑主体,在所述支撑主体表面设有至少两个电极,所述电极之间具有绝缘缝隙;每一所述电极分别连接至充电电源;所述电极的形状为规则形或不规则形。
  2. 根据权利要求1所述的无线充电装置,其特征在于,所述电极包括第一电极和第二电极,所述第二电极包围在所述第一电极外围。
  3. 根据权利要求2所述的无线充电装置,其特征在于,所述第一电极与第二电极之间的所述绝缘缝隙的距离相等,并且,所述第二电极外围还设有限位凸缘。
  4. 根据权利要求1所述的无线充电装置,其特征在于,所述支撑主体为平板状主体;所述电极包括两个以上,并且所述电极之间为等距或不等距排列在所述平板状主体上。
  5. 根据权利要求1所述的无线充电装置,其特征在于,所述充电电源包括与所述电极电连接的供电电路;所述供电电路设置在所述支撑主体上、或者与所述支撑主体分开设置。
  6. 根据权利要求5所述的无线充电装置,其特征在于,所述供电电路包括检测电路、开关电路、控制电路以及与所述检测电路、开关电路、控制电路连接供电的电源电路;
    所述检测电路与每一所述电极电连接,用于检测所述电极是否有功率接收装置的导电触点与其接触;
    所述开关电路与每一所述电极电连接,用于接通或断开所述电极的供电;
    所述控制电路与所述检测电路、开关电路连接,用于根据所述检测电路检测到的每一所述电极是否有导电触点与其接触来发出控制信号至所述开关电路,控制每一所述电极与所述电源电路的接通或断开。
  7. 根据权利要求6所述的无线充电装置,其特征在于,所述开关电路包括与每一所述电极同时连接的正极开关电路以及负极开关电路;
    所述检测电路包括多个检测单元,每一所述检测单元与一个所述电极对应电连接;
    所述正极开关电路包括多个正极开关单元,每一所述正极开关单元与一个所述电极电连接;
    所述负极开关电路包括多个负极开关单元,每一所述负极开关单元与一个所述电极电连接;
    所述控制电路控制与同一所述电极连接的所述正极开关单元和负极开关单元择一接通或同时断开。
  8. 一种功率接收装置,可与权利要求1-7任一项所述的无线充电装置配合使用,其特征在于,包括至少两个导电触点;
    单个所述导电触点的边缘最短距离大于所述无线充电装置的电极之间的绝缘缝隙的大小;并且,相邻所述导电触点边缘之间的最小距离大于单个所述电极的边缘的最大距离。
  9. 根据权利要求8所述的功率接收装置,其特征在于,所述功率接收装置还包括与所述导电触点电连接的功率模块,所述功率模块包括玩具、游戏设备、手机、电池、充电器、手持设备、电动工具、功率连接器、电热杯、音乐播放器、照相机、计算器、遥控器、录像机、视频播放器、传真机、PDA美容设备、电动剃须刀、电动牙刷、电推剪、电视机、电冰箱中的一种或多种。
  10. 根据权利要求8所述的功率接收装置,其特征在于,所述功率接收装置还包括一外壳,所述导电触点设置在所述外壳上,并且,所述外壳还设有与所述导电触点电连接的接口模块。
  11. 一种无线充电系统,其特征在于,包括权利要求1-7任一项所述的无线充电装置、以及权利要求8-10任一项所述的功率接收装置;所述功率接收装置放置在所述无线充电装置上,并且所述功率接收装置的两个导电触点分别与所述无线充电装置的至少两个电极导电接触,由所述无线充电装置为所述功率接收装置供电 。
PCT/CN2012/087063 2012-04-24 2012-12-20 无线充电装置、功率接收装置及无线平板充电系统 WO2013159548A1 (zh)

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