JP5239706B2 - Charging apparatus and charging method - Google Patents

Description

The present invention relates to a non-contact charging device that charges a battery mounted on a device such as a portable device, and more particularly to a charging device and a charging method that perform optimal charging according to the position and charging state of an object to be charged.

  Conventionally, for example, in charging devices such as an electric shaver and a cordless telephone, a non-contact method is employed in which a charger contact is not provided. In such non-contact charging, the device cannot be charged unless the device is placed in a dedicated charging holder or the like.

  Regarding non-contact charging, Patent Document 1 discloses that a secondary side device is provided with a receiving coil that receives power from a power transmission coil of a primary side device, and a dielectric coil is provided. When a reduction in the capacity of the secondary battery is detected, the device searches for the direction of the primary device based on the electromagnetic field component from the power transmission coil detected by the dielectric coil, and the secondary device is free-running. And thereby, the secondary device is guided to a position close to the primary device, and the power receiving coil can receive sufficient power from the power transmitting coil to charge the secondary battery. .

  Further, as a configuration that is non-contact charging and can be charged to different devices, Patent Document 2 discloses that a common cradle includes a power transmission module including a coil inside and a commercial voltage is supplied. Is equipped with a power receiving module including a coil inside, and by placing the PDA on the shared cradle, a magnetic coupling is generated between the coil in the PDA and the coil in the shared cradle, and the commercial cradle is supplied to the shared cradle Based on the voltage, a voltage is induced at both ends of the coil in the PDA, and power is supplied to the PDA. At this time, data communication is possible between the shared cradle and the PC. It is disclosed that data transmission is performed in

  In Patent Document 3, a non-contact charging device is connected to a non-contact power transmission device having a primary coil connected to a regulator circuit and a secondary coil that is magnetically coupled to the primary coil in the non-contact power transmission device. Non-contact charging device and non-contact charging module having a rectifying means modularized and charging secondary batteries in a plurality of portable electronic devices via the rectifying means of the non-contact power receiving module A charging system and a non-contact charging method are described.

Regarding configuring the non-contact charging device to be movable, Patent Document 4 discloses that a rechargeable battery is attached to a movable portion such as a Y-axis direction moving member so as to be movable along with the load. A non-contact rechargeable power supply device is described in which the rechargeable battery can always be recharged in a non-contact manner by a power supply unit for charging when it is disposed at the home position.
JP 2001-155944 A JP 2006-141170 A JP 2006-314181 A JP-A-6-153411

  By the way, as a non-contact type charging device, there is one configured in a flat panel shape, but in that case, it is necessary to place an object to be charged within a limited range on the panel, so that the chargeable range is limited. In addition, if the chargeable range was to be expanded, there was a problem that the primary coil for charging had to be increased accordingly.

  In addition, in the configuration in which the charging object is provided with moving means and guided to the charging device side, it is necessary to add a driving motor, a roller or the like to the charging object, and it is mounted on a miniaturized device such as a portable device. There is a problem that it is difficult to do. Furthermore, when the device to be charged is moved, the battery for the movement is consumed, so it is necessary to secure power for reaching the charger, and the remaining power of the battery becomes zero. In some cases, there is a problem that charging cannot be performed.

  Regarding such demands and problems, Patent Documents 1 to 4 do not disclose or suggest them, and do not disclose or suggest a configuration for solving them.

  Therefore, an object of the present invention is to provide a charging environment for automatically charging an object to be charged or a charging device without intervention of an artificial operation.

Another object of the present invention is to reliably perform a charging process by moving the charging device side with respect to an object to be charged and to improve charging efficiency.

  In order to achieve the above object, the present invention is a non-contact charging device that receives a measurement result of a wireless electric field intensity of the position detection signal from a charging target that has received the position detection signal, and charges from the measurement result. Move by specifying the target position. And if a charge process is started, it will be the structure which receives the measurement result of the induced electromotive force from charge object, and adjusts the position of a charging device according to the measurement result. With such a configuration, it is not necessary for the user to bring the charging target to a predetermined chargeable position of the charging device. Further, since the electric field strength is confirmed and the charging device is moved to the most efficient position, efficient charging is possible.

  Therefore, in order to achieve the above object, the present invention provides a charging device that performs charging in a non-contact manner with a charged side, wireless communication means for transmitting and receiving signals to and from the charging target, and notification from the charging target Position detecting means for detecting the position of the charging target from the electric field strength of the signal, movement means for moving the charging device to the position of the charging target, and charging when reaching the position of the charging target And charging control means.

  According to such a configuration, charging can be performed automatically without intervention of an artificial operation, charging efficiency can be improved, and the above object can be achieved.

  In order to achieve the above object, the charging device preferably includes a determination unit that determines a state of an electromotive force supplied to the charging target, and the charge control unit includes a determination result of the determination unit. Accordingly, the moving means may be controlled to adjust the optimum position. The above object can also be achieved by such a configuration.

In order to achieve the above object, the present invention provides a charging method in which charging is performed in a non-contact manner with a charged side, the step of transmitting / receiving a signal to / from a charging target, and the signal notified from the charging target Detecting the position of the charging target from the electric field strength of the battery, moving the charging device to the charging target position, and starting charging when the charging target position is reached. . According to such a configuration, the above object can be achieved.

  According to the present invention, the following effects can be obtained.

  (1) When charging is required, for example, when the user of the device moves the device away from the body for charging, the charging can be performed without being aware of the position of the charging device.

  (2) By measuring the electromotive force between the coils, the position of the charging device with respect to the charging target can be optimally adjusted, and the charging efficiency can be increased.

  (3) Compared to conventional non-contact charging devices, the chargeable range is widened.

  (4) Since the charging target side is not moved, the charging target does not become unable to be charged due to running out of the battery while moving to the charging device, and charging can be performed reliably.

Other objects, features, and advantages of the present invention will become clearer with reference to the accompanying drawings and each embodiment.

[First Embodiment]

  The first embodiment will be described with reference to FIG. FIG. 1 is a diagram illustrating a configuration of a contactless charging system according to the first embodiment. The configuration shown in FIG. 1 is an example, and the present invention is not limited to this.

  The charging system 2 is a non-contact charging system, and includes a charging device 4 that is a charging unit that supplies power and a device 6 that is an object to be charged. In this non-contact charging, charging is performed by generating electromotive force due to electromagnetic induction in coils provided in the charging device 4 and the device 6. Further, the charging system 2 is configured to move the charging device 4 to an optimal charging position with respect to the device 6 that requires charging.

  The charging device 4 includes, for example, a primary coil 8 that generates an electromotive force for the device 6, a two-way wireless communication processing unit 10, a charging determination unit 12, a moving roller 14, and a movement control unit 16. The bidirectional wireless communication processing unit 10 includes a bidirectional wireless communication transmitting / receiving unit 18, a bidirectional wireless communication message processing unit 20, and a charging object authentication determination unit 22. The charging determination unit 12 includes an electromagnetic field strength determination unit 24, The charging state determination unit 26 is configured, and the electromagnetic field strength determination unit 24 includes an induced electromotive force determination unit 28 and a wireless electric field strength determination unit 30. The movement control unit 16 includes a roller control unit 32 and a roller drive unit 34.

  The primary coil 8 serves as a current supply means of the charging device 4, for example, generates a magnetic flux by receiving a current supplied from an AC power supply 36 outside the charging device 4, and a secondary coil 38 on the side of the device 6 that receives the charging. An electromotive force is generated on the side by electromagnetic induction. The current supply means for the charging process is not limited to the external AC power source 36, and the charging device 4 may include a battery for charging.

  The two-way wireless communication processing unit 10 is a wireless communication unit that performs two-way wireless communication between the charging device 4 and the device 6. In addition to controlling wireless communication, the two-way wireless communication processing unit 10 is connected to the charge determination unit 12 side from the device 6 side. The received charge state, electromagnetic field strength measurement results, etc. are transmitted. The bidirectional wireless communication transmitting / receiving unit 18 is connected to the antenna 40 provided in the charging device 4 and performs bidirectional wireless communication with the device 6 side. As will be described later, the two-way wireless communication message processing unit 20 creates a message to be transmitted / received to / from the device 6 that requires charging, decodes a message received from the device 6, and the like. The charging object authentication determination unit 22 is configured to perform an authentication process as to whether or not the device 6 is appropriate as a charging target when communicating with the device 6.

  The charge determination unit 12 is a determination unit that determines the measurement result of the electromagnetic field intensity and the charge state measured on the device 6 side, and also a position detection unit that detects the position of the device described later using the determination result. Also, it is a position adjusting means for adjusting the charging position. Furthermore, a charging control means for controlling the charging process such as starting the charging process when reaching the optimal charging position by moving the charging device 4 and adjusting the position is also configured.

  The electromagnetic field strength determination unit 24 is a determination unit that determines the electric field strength from the measurement result measured on the device 6 side with respect to the electric field strength of the wireless communication emitted on the charging device 4 side. The charge state determination unit 26 is a determination unit that receives a measurement result of the charge state measured on the side of the device 6 that is charged, and determines whether charging is necessary from the measurement result. When the charging state determination unit 26 determines that the charging battery 42 of the device 6 is fully charged, the power supply from the AC power source 36 connected to the primary coil 8 is cut off.

  The induced electromotive force determination unit 28 of the electromagnetic field strength determination unit 24 is a determination unit that determines the induced electromotive force measured on the device 6 side. The wireless electric field strength determination unit 30 is a unit that determines the wireless electric field strength of wireless communication emitted from the charging device 4. Using the determination result of the induced electromotive force and the determination result of the wireless electric field intensity, the position of the device 6 is specified and the position of the charging device 4 is adjusted.

  The moving roller 14 is a moving unit of the charging device 4. For example, wheels or the like are configured at two locations on the bottom side of the charging device 4. The movement control unit 16 includes a roller control unit 32 that controls the operation of the moving roller 14 and a roller driving unit 34 that is configured by, for example, a motor for driving the moving roller 14. The movement control unit 16 moves in accordance with the electromotive force generated by the magnetic flux generated between the charging device 4 and the device 6 or the electric field strength of the two-way wireless communication determined by the electromagnetic field strength determination unit 24. The charging position with respect to the device 4 can be optimized by operating the roller 14 and moving the charging device 4.

  As a configuration on the charging object side, the device 6 includes, for example, a secondary coil 38, a charging battery 42, a two-way wireless communication processing unit 44, and a charge measuring unit 46. The charge measurement unit 46 includes a charge state measurement unit 48 and an electromagnetic field strength measurement unit 50, and the electromagnetic field strength measurement unit 50 includes a wireless electric field strength measurement unit 52 and an induced electromotive force measurement unit 54. The bidirectional wireless communication processing unit 44 includes a bidirectional wireless communication transmitting / receiving unit 56, a bidirectional wireless communication message processing unit 58, and an authentication processing unit 60.

  An electromotive force is generated in the secondary coil 38 by the magnetic flux generated between the primary coil 8 and the electromotive force is sent to the charging battery 42 to charge the device 6.

  The two-way wireless communication processing unit 44 performs wireless communication with the two-way wireless communication processing unit 10 on the charging device 4 side, transmits the charging state and the measurement result of the electromagnetic field strength, and the instruction from the charging device 4 side. Etc. are received. The bidirectional wireless communication transmission / reception unit 56 transmits / receives communication with the charging device 4 using the antenna 62 of the device 6. The two-way wireless communication message processing unit 58 creates a transmission message with the charging device 4 and decodes a received message. The authentication processing unit 60 is configured to perform transmission / reception of authentication information and the like with the charging object authentication determination unit 22.

  The charging state measuring unit 48 of the charging measuring unit 46 measures the charging state of the charging battery 42 of the device 6.

  The induced electromotive force measurement unit 54 of the electromagnetic field intensity measurement unit 50 measures the induced electromotive force due to the magnetic flux generated between the primary coil 8 of the charging device 4 and the secondary coil 38 on the device 6 side. The wireless field strength measuring unit 52 measures the wireless field strength of wireless communication between the bidirectional wireless communication transmitting / receiving units 18 and 56.

  And the measurement result in the charge condition measurement part 48 of the apparatus 6 or the electromagnetic field intensity measurement part 50 is sent to the charge determination part 12 via the bidirectional | two-way radio | wireless communication process parts 44 and 10, and is determined.

  Next, the charging system, the charging method, and the processing of the charging program will be described with reference to FIGS. 2, 3, 4, 5, and 6. 2, FIG. 3, FIG. 4, FIG. 5 and FIG. 6 are sequences of charging processing in the charging system. In each figure, A, B, C, D, E, F, G, and H are connectors between the flowcharts. 2, 3, 4, 5, and 6 are merely examples, and the present invention is not limited to these.

  In the charging process in the charging system 2, for example, the position detection and movement process of the device 6 by the charging device 4 (process F1), the confirmation process of the necessity of charging (process F2), the authentication process (process F3), It consists of an adjustment process (process F4) and a charging process (process F5).

  By transmitting a position detection signal from the charging device 4 side to the device 6 side that requires charging, and transmitting a reply message from the device 6 side receiving the position detection signal to the charging device 4 side, The position is specified, and the charging device 4 is moved to the position of the device 6. For specifying the position of the device 6, the received electric field strength of the position detection signal emitted from the charging device 4 is used. That is, the charging position is identified by repeating transmission and reception of messages between the charging device 4 and the device 6 (processing F1).

  Next, transmission / reception of a message regarding whether or not charging is necessary for the device 6 (process F2) and transmission / reception of a message indicating whether or not the device 6 is a charging target (process F3) are performed.

  In the charging process, a message is transmitted and received for the measurement result of the electromotive force generated in the secondary coil 38, and the position of the charging device 4 is adjusted to the optimum position according to the measurement result (process F4). When the adjustment to the proper charging position is completed, the charging process is started (process F5), a message is transmitted / received with respect to the measurement result of the charging state on the device 6 side, and the charging completion process is terminated according to the measurement result To do.

  The above processing content will be described.

  First, the position detection and movement process (process F1) of the apparatus 6 by the charging device 4 is performed. When the charging device 4 is activated (step S101), the two-way wireless communication transmitting / receiving unit 18 of the charging device 4 starts periodic continuous transmission of a position detection request signal to the device 6 that is the charging target (step S102). This position detection request signal is a search signal for the charging device 4 to search for a device 6 that needs to be charged. For example, the device 6 that has received this signal measures the electric field strength at the time of receiving this signal. A request message for transmitting the measurement result to the charging device 4 is included.

  Along with the transmission of the position detection request signal, scanning for searching for the position of the device 6 is started (step S103). In this scanning process, as described above, bidirectional wireless communication from the device 6 side is detected. In the scanning process, the movement control unit 16 activates the moving roller 14 (step S104), and starts the movement of the charging device 4 (step S105).

  On the device 6 side, when the position detection request signal from the charging device 4 is received (step S106), the received electric field strength of the position detection request signal is measured according to the message included in the position detection request signal (step S107). Then, the measurement result of the received electric field strength is periodically and continuously transmitted to the charging device 4 side by bidirectional wireless communication (step S108). The transmission of the measurement result of the electric field strength is, for example, a reply message for notifying the discovery of the device 6 and its position in response to a transmission message transmitted from the charging device 4 side to the device 6 side. Therefore, regular continuous transmission is performed so that the charging device 4 can be surely received.

  On the charging device 4 side, when the received electric field strength result signal is received from the device 6 (step S109), the received electric field strength threshold is determined (step S110). That is, since the measurement result of the received electric field strength changes according to the distance between the charging device 4 and the device 6, a threshold is set for the electric field strength as a chargeable distance, and charging is performed up to a position where the electric field strength exceeds the threshold. The device 4 is moved (NG in step S110).

  Then, the electric field intensity becomes equal to or higher than the threshold (OK in step S110), and if the charging device 4 recognizes this (step S111), it is known that the device 6 is in the immediate vicinity of the charging device 4, and the position of the device 6 is reached. Can be specified (step S112). At that time, scanning by the charging device 4 is stopped (step S113), and the movement roller 14 is stopped by the movement control unit 16 (step S114).

  With the above processing, the position detection and movement processing (processing F1) of the device 6 by the charging device 4 is completed.

  Next, transmission / reception of a message regarding the necessity of charging (processing F2) is performed. As shown in FIG. 3, the process F2 is a process for determining whether or not the device 6 discovered by position detection needs charging.

  The charging device 4 transmits a charge start request signal to the device 6 by bidirectional wireless communication (step S115). The charge start request signal includes a message that causes the device 6 side to execute a determination process as to whether or not a charging process is necessary, and return whether or not the charging process is necessary. On the device 6 side, when the charging start request signal is received from the charging device 4 (step S116), it is determined whether charging is necessary (step S117). If charging is necessary (OK in step S117), two-way wireless communication is performed. Then, a charging start response signal is transmitted to the charging device 4 (step S118). Then, when the charging device 4 side receives the charging start response signal (step S119), the transmission / reception of the message regarding the necessity of charging (processing F2) is terminated, and the process proceeds to the next processing F3.

  If charging is not necessary (NG in step S117), the charging process is terminated. Even when the charging process is unnecessary, a response signal including a message indicating that charging is not required may be transmitted to the charging device 4 side.

  When the confirmation process regarding the necessity of charging (process F2) is completed, the process proceeds to an authentication process (process F3) as to whether or not the device 6 is appropriate for charging.

  In the authentication process, an authentication request signal is transmitted from the charging device 4 to the device 6 side by bidirectional wireless communication (step S120). The authentication request signal includes, for example, an instruction to perform authentication processing on the device 6 side and return the result, and a request message such as authentication information of the charging device 4 necessary for authentication.

  On the device 6 side, when the authentication request signal from the charging device 4 is received (step S121), the authentication processing unit 60 of the bidirectional wireless communication processing unit 44 performs authentication processing (step S122). In this authentication process, for example, from the authentication information from the charging device 4 or the like, authentication of whether or not the device 6 and the charging device 4 are compatible, and other users registered in the charging device 4 and the device 6 match. You may authenticate whether or not to do so. When the authentication process is performed, a message including the authentication result is transmitted as an authentication response signal from the device 6 to the charging device 4 side (step S123).

  On the charging device 4 side, when the authentication response signal from the device 6 is received (step S124), the authentication result performed on the device 6 side is determined (step S125). In this determination process, if there is no problem in the authentication result (OK in step S125), the authentication process (F3) is terminated and the process proceeds to the next process. When there is a problem in the authentication result (NG in step S125), it is determined that the device 6 is not appropriate as a charging target, and the charging process is terminated.

  Next, the process proceeds to the position adjustment process (process F4) of the charging device 4. In the process F4, similarly to the charged state, a magnetic flux is generated between the charging device 4 and the device 6, and the electromotive force generated on the device 6 side is measured. And it is the process which adjusts the position of the charging device 4 with respect to the apparatus 6 from this measurement result, and moves the charging device 4 to a position where charging efficiency is better.

  On the charging device 4 side, when the primary coil 8 is activated (step S126), an electromotive force is generated in the secondary coil 38 on the device 6 side by electromagnetic induction (step S127). Then, the generated electromotive force is measured by the induced electromotive force measurement unit 54 on the device 6 side (step S128), and the measurement result is regularly transmitted to the charging device 4 using bidirectional wireless communication (step S129). Since the position adjustment of the charging device 4 is performed using the electromotive force measurement result, the device 6 side repeatedly performs electromotive force measurement (step S128) and measurement result transmission (step S129).

  On the charging device 4 side, the electromotive force measurement result signal of the secondary coil 38 from the device 6 side is received (step S130). And based on the received electromotive force measurement result, it determines in the induced electromotive force determination part 28, and the fine adjustment of the position with the apparatus 6 is started (step S131). In the fine adjustment of the position of the charging device 4, the movement control unit 16 activates the moving roller 14 (step S132), and starts the movement of the charging device 4 (step S133). In the adjustment of the charging device 4, for example, the direction in which the charging device 4 is moved may be determined from the determination result of the induced electromotive force determination unit 28 and the control information of the movement control unit 16.

  On the device 6 side, the electromotive force generated in the secondary coil 38 is continuously measured, and the measurement result is regularly transmitted to the charging device 4 side (step S134).

  When receiving the electromotive force measurement result signal of the secondary coil 38 periodically transmitted from the device 6 side (step S135), the charging device 4 performs electromotive force threshold determination on the measurement result (step S136). In this determination, if the electromotive force exceeds the threshold (OK in step S134), it can be determined that the device 6 is provided with the optimum electromotive force from the charging device 4. That is, it can be recognized that the relative position between the charging device 4 and the device 6 is appropriate.

  If it is recognized that the electromotive force is equal to or greater than the threshold (step S137), fine adjustment of the position of the charging device 4 is stopped (step S138), and the movement roller 14 is stopped by the movement control unit 16 (step S138). S139).

  Further, in the electromotive force threshold value determination process, when the result exceeding the threshold value is not obtained, the measurement result from the device 6 is repeatedly received and the movement adjustment of the charging device 4 is repeated (NG in step S136).

  With the above process, the position adjustment process (process F4) of the charging device 4 is terminated, and the process proceeds to the process of charging the device 6 (process F5).

  When the charging process from the charging device 4 to the device 6 is started (step S140), the device 6 side periodically sends a report including a message indicating the charging state to the charging device 4 side using bidirectional wireless communication. Continuous transmission is performed (step S141). In this charging state report, for example, the charging state of the charging battery 42 is measured by the charging state measuring unit 48 of the device 6 and the measurement result is transmitted as a message.

  In the charging device 4, for example, when the measurement result of the received charging state is determined by the charging state determination unit 26 and it is determined that the charging is completed (OK in step S <b> 142), the charging device 4 transmits the measurement result to the device 6 side by bidirectional wireless communication. On the other hand, a charge completion request signal is transmitted (step S143). The charge completion request signal may include, for example, a message such as an instruction for measuring the state of charge and transmitting the completion signal to the device 6 side.

  On the device 6 side, when a charge completion request signal is received from the charging device 4 (step S144), it is determined whether or not the battery is fully charged (step S145). When the battery is fully charged (OK in step S143), the process proceeds to process F51 as a charge completion process. In this case, a charging completion response signal is transmitted using bidirectional wireless communication (step S146).

  When the charging device 4 receives the charging completion response signal from the device 6 side (step S147), the charging is completed (step S148).

  When it is determined that the battery is not fully charged (NG in step S145), the process proceeds to process F52 as shown in FIG. The device 6 side transmits a charge continuation request signal to the charging device 4 side using bidirectional wireless communication (step S149). When the charging device 4 receives the charging continuation request signal from the device 6 side (step S150), the charging device 4 continues the charging process (step S151), and returns to step S140, for example.

  Next, FIG. 7 is referred to regarding messages included in the bidirectional wireless communication between the charging device and the device. FIG. 7 is a diagram illustrating an example of a message included in the bidirectional wireless communication between the charging device and the device. Note that the message content shown in FIG. 7 is an example, and the present invention is not limited to this.

  In FIG. 7, the request | requirement with respect to the apparatus 6 from the charging device 4 according to each process in said process F1-process F5, or the response and the content of a request | requirement with respect to the charging apparatus 4 from the apparatus 6 side are shown. In this way, by repeatedly exchanging messages between the charging device 4 and the device 6, the charging device 4 detects the position of the device 6, adjusts the charging position, and the like.

  With such a configuration, since the charging device side detects and moves to the device side that requires charging, the charging device that requires charging can be charged without manually operating the charging device. . Further, in the detection of the device, the movement of the charging device, the adjustment of the charging position, etc., it is possible to move and adjust to the optimum charging position by repeatedly communicating between the charging device and the device. In addition, since the device side is not moved, there is no need to add a new configuration to the device side, the device can be downsized, and there is no risk of running out of battery on the moving device side, so charging is performed reliably. be able to.

[Second Embodiment]

  Next, as a second embodiment of the present invention, the configuration of the first position specifying means of the charging device will be described with reference to FIGS. FIG. 8 is a diagram showing the position specifying means of the charging object by measuring the received electric field strength, and FIG. 9 is a diagram showing the relationship between the change in the received electric field strength and the electric field strength threshold when moved. The contents shown in FIGS. 8 and 9 are examples and are not limited to this.

  As described above, the reception field strength measurement result of bidirectional wireless communication is used as the first position specifying means for specifying the positions of the charging device 4 and the device 6 that is the charging target. In the position specifying method, it is assumed that the charging device 4 is at a position A as shown in FIG. At position A, an electric field (radio wave) 100 having a constant transmission power is generated from the charging device 4. The range of the electric field 100 varies depending on the transmission intensity from the charging device 4. In this case, since the electric field 100 generated from the charging device 4 does not reach the device 6 at the position A, the position detection request signal from the charging device 4 to the device 6 or the received electric field from the device 6 to the charging device 4 The message of the strength result response is not exchanged.

  Thereafter, the charging device 4 moves, for example, the moving direction of the charging device 4 in the X direction and / or the Y direction by a predetermined amount. At this time, while moving, the received electric field strength result response from the device 6 is monitored, and scanning is performed.

  For example, when the charging device 4 moves in the direction of the position B, the electric field 100 generated from the charging device 4 on the device 6 side and the position detection request signal to the device 6 side mounted thereon are received. Is possible. And the charging device 4 can recognize that the apparatus 6 which is a charging target object exists in the vicinity of the position B by returning the message of a received electric field strength result response with respect to the charging device 4 side.

  At this time, as shown in FIG. 9, the charging device 4 side performs reception field strength threshold determination with reference to the reception field strength result from the device 6 side while moving from the position A to the position B direction. Then, when the measurement result of the received electric field intensity transmitted from the device 6 side exceeds the threshold value, it is recognized that the positional relationship between the charging device 4 and the device 6 is an optimal place for performing the charging process. To do.

  With such a configuration, by constantly exchanging electric field strength and transmitting measurement results with the device that is the object to be charged, the positional relationship between the two is adjusted, and the charging device is optimally charged. Since it can move to a position, charging efficiency can be increased. Further, as described above, since only the measurement result is transmitted on the device 6 side, the power consumption is suppressed, and there is little possibility of running out of power while moving to the charging position, so that the charging process can be reliably performed. it can.

  [Third Embodiment]

  Next, as a third embodiment of the present invention, the configuration of the second position specifying means of the charging device will be described with reference to FIGS. FIG. 10 is a diagram showing a position specifying state of a charging object generated by electromagnetic induction, and FIG. 11 is a diagram showing a relationship between an electromotive force change and an electromotive force threshold when the object is moved. The contents shown in FIGS. 10 and 11 are examples, and the present invention is not limited to this.

  As a second position specifying means for specifying the position of the charging device 4 and the device 6 that is the charging target, the electromotive force measurement result from the device 6 that is the charging target generated by electromagnetic induction is used. In the position specifying method, an electromotive force due to electromagnetic induction between the primary coil 8 on the charging device 4 side and the secondary coil 38 on the device 6 side is measured on the device 6 side, and the measurement result is measured by the charging device 4. It is the structure determined in the induced electromotive force determination part 28.

The method for measuring electromotive force uses the following Faraday's law formula.
V = dΦ / dt (1)

  By obtaining the electromotive force V generated on the device 6 side from the magnetic flux Φ generated between the primary coil 8 and the secondary coil 38 by the equation (1), the optimum charging position is specified as shown in FIG. The position of the charging device 4 is adjusted.

  FIG. 10A shows a state before the position adjustment of the charging device 4, and FIG. 10B shows a state after the position adjustment of the charging device 4. That is, in the state shown in FIG. 10A, the electromotive force V1 generated by the magnetic flux Φ1 generated between the primary coil 8 and the secondary coil 38. The electromotive force V1 at this time does not reach the electromotive force threshold as shown in FIG. Therefore, the charging device 4 is moved to finely adjust the positional relationship between the primary coil 8 and the secondary coil 38.

  For example, the moving direction at this time may be first moved in a predetermined direction, and thereafter, the moving direction may be adjusted in accordance with the electromotive force change from the device side 6. Then, as shown in FIG. 10B, the position where the electromotive force V2 is generated is specified by adjusting the position to the position where the magnetic flux Φ2 is obtained.

  With such a configuration, the magnetic flux and electromotive force between the coils are adjusted, and when the threshold value is exceeded, it can be recognized that the positional relationship between the charging device and the charging object is the optimum place, so that the charging efficiency is increased. be able to.

[Fourth Embodiment]

  Next, the configuration of a portable device using this charging system will be described with reference to FIGS. 12, 13, 14, 15, 16, 17, and 18. FIG. 12 is a diagram illustrating an example of a hardware configuration of a charging device using the charging system according to the fourth embodiment, and FIG. 13 is a diagram illustrating an example of a hardware configuration of a portable device using the charging system. FIG. 14 is a flowchart showing the position specifying process of the charging device, FIG. 15 is a view showing the position specifying state by the charging device, FIG. 16 is a view showing a state where the charging position is shifted, and FIG. FIG. 18 is a graph showing a change in voltage caused by adjusting the charging position. Note that the configurations, processing contents, and processing procedures illustrated in FIGS. 12, 13, 14, 15, 16, 17, and 18 are merely examples, and the present invention is not limited thereto. In FIG. 12, FIG. 13 and FIG. 15, the same components as those in FIG.

  This charging device 200 is an example of a hardware configuration that constitutes the charging device 4 using the above-described charging system 2, and specifically, constitutes the charging device 200 of a portable device such as a cellular phone device. As shown in FIG. 4, a processor 202, a wireless communication unit 204, a communication antenna 206 (40), a RAM (Random-Access Memory) 208, a program storage unit 210, a data storage unit 212, a movement control unit 214 (16), and power control It is comprised by the part 216, the primary coil 218 (8), etc.

  The processor 202 is an arithmetic processing unit of the charging device 200, and executes execution processing of various control programs stored in the program storage unit 210. The wireless communication unit 204 is connected to a communication antenna 206 installed in the charging device 200 and constitutes the above-described bidirectional wireless communication processing unit 10 (FIG. 1), so that the state of charge, induced electromotive force, or wireless electric field strength is configured. Wireless communication means for performing transmission / reception of measurement results and the like and transmission / reception of messages.

  The RAM 208 is a work area for executing the above-described arithmetic processing and the like, and by operating each control program stored in the program storage unit 210, the charging state determination unit 26 (FIG. 1) and the electromagnetic field The strength determination unit 24 (FIG. 1), the bidirectional wireless communication message processing unit 20, and the like are configured and function as a position detection unit, a charge control unit, a determination unit, and the like. The program storage unit 210 executes, for example, a charging state determination program 220, an electromagnetic field strength determination program 222, creation of a message exchanged with a charging target, decoding processing, charging position identification processing, position adjustment processing, and the like. It is means for storing the message processing program 224 and the like. The data storage unit 212 is a means for storing measurement results such as the state of charge, induced electromotive force, and electric field strength received from the charging object side.

  The power supply control unit 216 is a means for connecting the external AC power supply 36 (FIG. 1) and the charging device 200, and controls energization of the primary coil 218 (8).

  The mobile device 250 is an example of a hardware configuration that configures an object to be charged (device 6) using the above-described charging system 2, and is a mobile device having a communication function such as a mobile phone device, for example. As illustrated in FIG. 13, a processor 252, a wireless communication unit 254, a communication antenna 256 (62), a RAM 258, a storage unit 260, an electric field strength sensor 262, a voltage sensor 264, a secondary coil 265 (38), and an operation input unit 266. The display unit 268 and the like.

  The processor 252 is an arithmetic processing unit of the portable device 250, and executes a program for each process such as an OS (Operating System) for operating the portable device 250, an electric field strength measurement process, and an induced electromotive force and a charge state measurement process. It is means to do. The wireless communication unit 254 is connected to the communication antenna 256 and constitutes a bidirectional wireless communication processing unit 44 (FIG. 1), and transmits / receives measurement results such as charge state, induced electromotive force or wireless electric field strength, and messages. Send and receive.

  The RAM 258 is a work area for executing the arithmetic processing and the like, and by operating each control program stored in the storage unit 260, the bidirectional wireless communication message processing unit 58 (see FIG. 1) and so on.

  The storage unit 260 includes a program storage unit 272 that stores an OS, various operation programs, and the like, and a data storage unit 274 that stores measurement results from the electric field strength sensor 262, the voltage sensor 264, and the like.

  The electric field strength sensor 262 is means for measuring the electric field strength of the bidirectional wireless communication transmitted from the charging device 200, and constitutes the above-described wireless electric field strength measuring unit 52 (FIG. 1). Further, the voltage sensor 264 includes an induced electromotive force measurement unit 54 (FIG. 1) that performs position adjustment processing of the charging device 200 and a charge state measurement unit 48 (FIG. 1) connected to the charging battery 42 (FIG. 1). Configure.

  As the configuration of the portable device 250, the operation input unit 266 includes a cursor key, a character input key, a determination key, and the like, and is used, for example, for an operation for starting execution of the charging process program. The display unit 268 is an information presenting means, and is composed of, for example, an LCD (Liquid Crystal Display), and displays a charging state and a charging completion.

  FIG. 14 shows the position specifying process of the portable device 250 by the charging device 200. In the position specifying process, as described above, position detection using the measurement result of the received electric field strength (step S201) and charge position adjustment using the measurement result of the generated electromotive force (step S202) are performed.

  An example of the position specifying process of the portable device 250 by the charging device 200 is shown in FIG.

  The charging device 200 installed on the table 280 detects the position of the portable device 250, moves to a chargeable position, and performs charging. In this case, first, a position detection request is transmitted from the charging device 200. As described above, the position detection request includes an instruction to measure the field strength of the wireless communication with respect to the received portable device 250 and transmit the measurement result to the charging device 200 side.

  When the portable device 250 is not in a position where wireless communication from the charging device 200 can be received, the position detection request is continuously transmitted while moving in a predetermined direction. When portable device 250 receives a position detection request, portable device 250 returns a received electric field strength result to charging device 200 side. On the charging device 200 side, when the reception field strength result from the portable device 250 is received, the position of the portable device 250 is specified based on the reception field strength result information.

  In specifying the position of the portable device 250, for example, the transmission of the position detection request and the measurement result of the received electric field strength are repeatedly performed between the charging device 200 and the portable device 250 to move the charging device 200. A position where the reception electric field strength result that varies with the result exceeds a predetermined threshold is determined as a charging position. Then, at the point where the charging position is specified, the charging device 200 is stopped and preparation for starting charging is performed.

  However, in the position detection based only on the response of the received electric field strength detected by the portable device 250, the position where charging is possible can be specified, but the optimum position of charging efficiency may not be specified. That is, as shown in FIG. 16, it is conceivable that the charging efficiency is lowered due to a positional shift between the primary coil 218 on the charging device 200 side and the secondary coil 265 on the portable device 250 side.

  Therefore, as shown in FIGS. 17 and 18, the induced electromotive force generated in the secondary coil 265 of the portable device 250 is measured, and the measurement result is transmitted to the charging device 200. The portable device 250 defines a threshold value of electromotive force generated by charging, and when exceeding the threshold value, transmits a request to the charging device 200 that a sufficient electromotive force has been generated. Further, it is determined whether or not the electromotive force has reached the threshold value. If the threshold value has not been reached, a request is transmitted to the charging device 200 so as to adjust the positional deviation, and the optimum charging position is determined. Move to.

  When the charging device 200 receives the request that the electromotive force exceeds the threshold value, the charging device 200 ends the fine adjustment of the charging position, stops the movement of the position adjustment, and starts charging the portable device 250.

  According to such a configuration, since the charging device side detects the position of the portable device and moves to the optimum charging position, the user of the portable device does not need to search for the position of the charging device, and the portable device is charged for charging. There is no need to return the device to a predetermined position, and it is possible to prevent a situation such as forgetting to place the portable device at the predetermined position or inability to charge due to insufficient placement. Moreover, since it is not necessary to mount a moving means etc. in a portable apparatus, it contributes also to size reduction of a portable apparatus.

  The characteristic items and the like of the embodiment described above are listed as follows.

  (1) The non-contact charging device 4 has a function of recognizing the position of the charging object and moving to that position.

  (2) Further, the charging device 4 has a function capable of moving autonomously in a two-dimensional or three-dimensional manner toward the charging object.

  (3) The charging device 4 has a function that enables non-contact communication with an object to be charged and can detect and specify the position of the object to be charged.

  (4) The charging device 4 has a function of enabling non-contact communication with an object to be charged and authenticating whether or not the object to be charged is appropriate as an object to be charged.

  (5) The charging device 4 has a function that enables non-contact communication with a charging object during charging and can communicate information on the charging status.

  (6) The charging device 4 has a function of detecting a change in power supply efficiency with the charging object during charging, specifying a position where the power supply efficiency is optimal, and correcting the position.

[Other Embodiments]

  (1) In the above embodiment, in the position detection of the charging object by the charging device, the measurement result of the electric field strength is received and the position of the charging object is specified using the measurement result. For example, in the reply message of the measurement result of the electric field strength from the charging object, the direction in which the movement instruction information or the reply from the device is transmitted is determined so that the moving direction of the charging device is determined. Data that can be determined may be included. Also with such a configuration, position detection by the charging device is possible.

  (2) In addition, in detecting the position of the charging object by the charging device, the direction and direction in which the charging device is moved when receiving a response to the measurement result of the received electric field strength are determined in advance, and the direction of the charging device is determined accordingly. When the change is made, the measurement result of the received electric field strength stored in the data storage unit 274 or the like before the direction change is compared with the received electric field strength after the direction change, and the charging device is moved. You may make it provide such a program.

  Next, technical ideas extracted from the embodiments of the present invention described above are listed as appendices in accordance with the description format of the claims. The technical idea according to the present invention can be grasped by various levels and variations from the superordinate concept to the subordinate concept, and the present invention is not limited to the following supplementary notes.

(Supplementary Note 1) A charging device that performs charging in a non-contact manner with a charged side,
Wireless communication means for transmitting and receiving signals to and from the charging target;
Position detecting means for detecting the position of the charging target from the electric field strength of the signal notified from the charging target;
Moving means for moving the charging device to a position to be charged;
Charging control means for starting charging when the position to be charged is reached;
A charging device comprising:

(Supplementary note 2) In the charging device of Supplementary note 1,
A determination unit configured to determine a state of an electromotive force supplied to the charging target, wherein the charge control unit adjusts an optimal position by controlling the moving unit according to a determination result of the determination unit; Charging device.

(Supplementary Note 3) In the charging device of Supplementary Note 1,
The said position detection means determines whether the received electric field strength of the said communication is more than a threshold value, and specifies the position of charge object, The charging device characterized by the above-mentioned.

(Supplementary Note 4) In the charging device of Supplementary Note 1,
It has a primary coil that receives power from an external power source,
A charging device characterized in that an electromotive force is generated by electromagnetic induction with respect to a secondary coil provided for the charging object, and charging is performed.

(Appendix 5) In the charging device of Appendix 2,
The said determination means acquires the measurement information of the electromotive force supplied to the said charging object, and determines whether the electromotive force is more than a threshold value, The charging device characterized by the above-mentioned.

(Appendix 6) In the charging device of Appendix 1,
It has an authentication judgment unit that authenticates whether or not it is an appropriate charging target,
A charging device that transmits a signal for requesting authentication information to the charging target and performs a charging process when a response signal to the authentication request is received.

(Supplementary note 7) A charging method for charging in a non-contact manner with a charged side,
Sending and receiving signals to and from the charging target;
Detecting the position of the charging target from the electric field strength of the signal notified from the charging target;
Moving the charging device to the position to be charged;
Starting charging when the charging target position is reached;
The charging method characterized by including.

(Supplementary Note 8) A charging system for charging a charged side and a charging side in a non-contact manner,
A charging means, and a charging target charged by the charging means,
The charging means transmits a signal to the charging target, specifies the position of the charging target from the electric field strength of the signal notified from the charging target in response to the signal, moves to the position,
The charging system receives the signal from the charging unit, and notifies the charging unit of the electric field strength.

(Supplementary note 9) A charging program that is executed by a computer and performs charging without contact with a charged side,
A function to send and receive signals to and from the charging target,
A function of detecting the position of the charging target from the electric field strength of the signal notified from the charging target;
A function of issuing an instruction to move to the position to be charged;
A function to issue an instruction to start charging when the position to be charged is reached;
A function to issue an instruction to authenticate whether or not the battery is properly charged;
A function of sending a signal requesting authentication information to the charging target and issuing an instruction to perform a charging process when receiving a response signal to the authentication request;
A charging program characterized by causing a computer to execute.

As described above, the most preferable embodiment and the like of the present invention have been described. However, the present invention is not limited to the above description, and is described in the claims or the best for carrying out the invention. It goes without saying that various modifications and changes can be made by those skilled in the art based on the gist of the invention disclosed in the embodiments, and such modifications and changes are included in the scope of the present invention.

The present invention relates to a charging device that charges a charging target, such as a portable device, in a non-contact manner, and uses a measurement result of electric field strength of a wireless communication performed between the charging target and an electromotive force to be generated. By specifying the target position, moving to a chargeable position, and adjusting the optimal charging position, charging is automatically performed on the charging target that requires charging without human intervention. In addition, it is possible to increase charging efficiency by adjusting the position according to the measured electromotive force, which is useful.

It is a figure which shows the structure of the non-contact charge system which concerns on 1st Embodiment. It is the sequence of the charging process in a charging system. It is the sequence of the charging process following FIG. It is the sequence of the charging process following FIG. It is the sequence of the charging process following FIG. It is the sequence of the charging process following FIG. It is a figure which shows an example of the message contained in the bidirectional | two-way radio | wireless communication of a charging device and an apparatus. It is a figure which shows the position identification means of the charging target object by receiving electric field strength measurement. It is a figure which shows the relationship with the change of the received electric field strength at the time of moving, and an electric field strength threshold value. It is a figure which shows the position specific state of the charging target produced | generated by electromagnetic induction. It is a figure which shows the relationship between the change of the electromotive force at the time of moving, and an electromotive force threshold value. It is a figure which shows an example of the hardware constitutions of the charging device which utilizes the charging system based on 4th Embodiment. It is a figure which shows an example of the hardware constitutions of the portable apparatus using a charging system. It is a flowchart which shows the position specific process of a charging device. It is a figure which shows the position specific state by a charging device. It is a figure which shows the state from which the charge position shifted | deviated. It is a figure which shows the state which adjusted the charge position. It is a graph which shows the change of the voltage which arises by adjustment of a charge position.

Explanation of symbols

2 Charging system 4 Charging device 6 Equipment (object to be charged)
DESCRIPTION OF SYMBOLS 8 Primary coil 10 Two-way radio | wireless communication processing part 12 Charge determination part 14 Roller for movement 16 Movement control part 18 Two-way radio communication transmission / reception part 20 Two-way radio communication message processing part 22 Charge object authentication determination part 24 Electromagnetic field strength determination part 26 Charging State Determination Unit 28 Induced Electromotive Force Determination Unit 30 Wireless Field Strength Determination Unit 38 Secondary Coil 44 Bidirectional Wireless Communication Processing Unit 46 Charging Measurement Unit 48 Charging State Measurement Unit 50 Electromagnetic Field Strength Measurement Unit 52 Wireless Field Strength Measurement Unit 54 Inductive electromotive force measurement unit 56 Bidirectional wireless communication transmission / reception unit 58 Bidirectional wireless communication message processing unit 60 Authentication processing unit 100 Electric field

Claims (3)

A charging device that performs charging in a non-contact manner with a charged side,
Wireless communication means for transmitting and receiving signals to and from the charging target;
Position detecting means for detecting the position of the charging target from the electric field strength of the signal notified from the charging target;
Moving means for moving the charging device to a position to be charged;
Charging control means for starting charging when the position to be charged is reached;
A charging device comprising:
The charging device according to claim 1, wherein
A determination unit configured to determine a state of an electromotive force supplied to the charging target, wherein the charge control unit adjusts an optimal position by controlling the moving unit according to a determination result of the determination unit; Charging device.
A charging method for charging in a non-contact manner with the charged side,
Sending and receiving signals to and from the charging target;
Detecting the position of the charging target from the electric field strength of the signal notified from the charging target;
Moving the charging device to the position to be charged;
Starting charging when the charging target position is reached;
The charging method characterized by including.

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