JP6979288B2 - Transmitters, power receivers, power transmission / reception systems, automated teller machines and power transmission / reception methods - Google Patents

Description

The present invention relates to a transmitter, a power receiver, a power transmission / reception system, an automated teller machine, and a power transmission / reception method.

Patent Document 1 is an automated teller machine including a main body housing and a banknote storage that is provided so as to be able to be pulled out from the main body housing and stores the conveyed bills. A non-contact power transmitting means and a device-side wireless communication unit for performing information communication by electromagnetic waves are installed inside, and the bill storage is internally a non-contact power receiving means that receives power from the non-contact power transmitting means. The non-contact power receiving means is powered by the device-side wireless communication unit and has a storage-side wireless communication unit for performing information communication. The non-contact power transmitting means and the non-contact power receiving means are the banknotes. Described is a technique for an automated teller machine characterized in that the storage is in an approaching state in a storage state in which the storage is stored inside the main body housing.

Japanese Unexamined Patent Publication No. 2016-004286

In the technique described in Patent Document 1, a wireless communication unit is required on each of the automatic teller machine main body side and the bill storage side in order to perform information communication, which may be expensive.

INDUSTRIAL APPLICABILITY The present invention provides a wire-saving, non-contact wireless system between a transmitter and a power receiver, and at a low cost, a power transmitter, a power receiver, a power transmission / reception system, and a power transmitter, a power receiver, and a power transmission / reception system for transmitting power and information between the transmitter and the power receiver. The purpose is to provide a method of transmitting and receiving power.

The present application includes a plurality of means for solving at least a part of the above problems, and examples thereof are as follows. In order to solve the above problems, the transmitter according to one aspect of the present invention has a control unit and a first non-contact power transmission unit provided with a first magnetic antenna for transmitting first unmodulated electric power in a non-contact manner. And a second magnetic antenna that receives the second unmodulated power transmitted non-contact using a part of the first unmodulated power, and consumes the second unmodulated power. A non-contact power receiving unit including a first power receiving load and a demodulating unit are provided, and the control unit sets the load state of the first power receiving load to the power transmission source of the second unmodulated power. The second unmodulated electric power is varied by changing the control content to control the device, and the second magnetic antenna transmits the third unmodulated electric power in a non-contact manner, and the above-mentioned second unmodulated electric power is transmitted. The demodulator is characterized in that it detects and demolishes the fluctuation of the third unmodulated power.

According to the present invention, it is possible to reduce the wiring between the transmitter and the receiver and to make the wireless contactless, and to transmit power and information between the transmitter and the receiver at a low cost. Issues, configurations and effects other than those described above will be clarified by the following description of the embodiments.

It is an example of the block diagram of the automatic teller machine which concerns on 1st Embodiment of this invention. This is an example of a configuration diagram of a conventional automated teller machine. It is an example of the block diagram of the automatic teller machine which concerns on 1st Embodiment of this invention. It is an example of the block diagram which concerns on the control transmission operation of the automatic teller machine which concerns on 1st Embodiment of this invention. It is a circuit diagram of the load which concerns on 1st Embodiment of this invention. It is a circuit diagram of the control information demodulation part which concerns on 1st Embodiment of this invention. It is a figure which shows the example of the waveform of the signal of the automatic teller machine which concerns on 1st Embodiment of this invention. It is an example of the block diagram of the automatic teller machine which concerns on the 2nd Embodiment of this invention. It is an example of the block diagram which concerns on the operation of the switching part which controls the bill storage of the automatic teller machine which concerns on the 2nd Embodiment of this invention. This is an example of a block diagram relating to the operation of a switching unit for transmitting information to the main body of the automatic teller machine according to the second embodiment of the present invention. It is an example of the block diagram of the automatic teller machine which concerns on 3rd Embodiment of this invention. It is an example of the block diagram of the automatic teller machine which concerns on 4th Embodiment of this invention. It is a figure explaining the problem of the electric power supply of a general automatic teller machine. It is an example of the block diagram of the power supply part of the automatic teller machine which concerns on 4th Embodiment of this invention. It is another example of the block diagram of the power supply part of the automatic teller machine which concerns on 4th Embodiment of this invention. It is an example of the figure which shows the structural example of the banknote storage of the automatic teller machine which concerns on 4th Embodiment of this invention. It is an example of the figure which shows the example of the waveform of the signal when the drive power use part of the automatic teller machine which concerns on 4th Embodiment of this invention is a solenoid. It is an example of the figure which shows the structure when the constant load part is added to the drive system of the automatic teller machine which concerns on 4th Embodiment of this invention. It is an example of the figure which shows the structure in the case where the drive power use part of the automatic trading apparatus which concerns on 4th Embodiment of this invention is a DC motor. It is an output characteristic diagram of a general DC motor. It is a figure which shows the example of the DC motor drive electric power of the automatic trading apparatus which concerns on 4th Embodiment of this invention. It is a figure which shows the operation flow of the drive system electric power use part of the automatic teller machine which concerns on 4th Embodiment of this invention. It is a figure which shows the initial operation flow of the automatic trading apparatus which concerns on 4th Embodiment of this invention. It is an example of the block diagram of the automatic teller machine which concerns on the 5th Embodiment of this invention. This is an example of a block diagram of an automated teller machine according to a sixth embodiment of the present invention. It is an example of the block diagram of the automatic teller machine which concerns on the 7th Embodiment of this invention. It is an example of the block diagram of the automatic teller machine which concerns on 8th Embodiment of this invention. It is an example of the block diagram of the automatic teller machine which concerns on the 9th Embodiment of this invention. It is an example of the block diagram of the automatic teller machine which concerns on tenth Embodiment of this invention. It is an example of the block diagram of the automatic teller machine which concerns on tenth embodiment of this invention. It is an example of the block diagram of the power transmission / reception system which concerns on the tenth embodiment of this invention. It is an example of the figure which shows the data structure used in the power transmission / reception system which concerns on the tenth embodiment of this invention. It is a figure which shows the initial operation flow of the power transmission / reception system which concerns on tenth embodiment of this invention.

Hereinafter, embodiments will be described in detail with reference to the drawings. However, the present invention is not limited to the description of the embodiments shown below. It is easily understood by those skilled in the art that a specific configuration thereof can be changed without departing from the idea or purpose of the present invention.

In the configuration of the invention described below, the same reference numerals may be used in common among different drawings for the same parts or parts having similar functions, and duplicate description may be omitted. The notations such as "first", "second", and "third" in the present specification and the like are attached to identify the components, and are not necessarily limited in number or order. Further, the numbers for identifying the components are used for each context, and the numbers used in one context do not always indicate the same composition in the other contexts. Further, it does not prevent the component identified by a certain number from having the function of the component identified by another number.

The position, size, shape, range, etc. of each configuration shown in the drawings and the like may not represent the actual position, size, shape, range, etc. in order to facilitate understanding of the invention. Therefore, the present invention is not necessarily limited to the position, size, shape, range and the like disclosed in the drawings and the like.

In addition, when saying "consisting of A", "consisting of A", "having A", and "including A", other elements are excluded unless it is clearly stated that it is only that element. It goes without saying that it is not something to do. Similarly, in the following embodiments, when the shape, positional relationship, etc. of the constituent elements are referred to, the shape is substantially the same, except when it is clearly stated or when it is considered that it is not clearly the case in principle. Etc., etc. shall be included.

Generally, in automated teller machines (ATMs) and automated teller machines, power and data transmission wiring such as sensors are complicated, and it is required to reduce wiring, that is, to make it wireless and to reduce costs. There is. In-device wireless has the advantages of reducing the number of mounting man-hours, reducing the weight of automated teller machines, and improving maintenance and convenience because the number of connectors and harnesses between devices is reduced.

The bill storage is often taken out of the main body of the automated teller machine for replenishment and collection of cash, but generally, the bill storage and the main body are connected by a connector. A known example of wireless communication of this portion is shown in, for example, Patent Document 1, in which a device-side wireless communication unit for performing information communication with a non-contact power transmission means by electromagnetic waves is provided inside the bill storage. It has a non-contact power receiving means and a storage-side wireless communication unit for transmitting information by the non-contact power receiving means and performing information communication with the device-side wireless communication unit.

[First Embodiment] FIG. 1 is an example of a block diagram of an automated teller machine according to the first embodiment of the present invention. Further, FIG. 2 shows an example of a configuration diagram of a conventional automated teller machine. FIG. 3 shows an example of a configuration diagram of an automated teller machine according to the first embodiment of the present invention.

FIG. 2 is an example of a configuration diagram of a conventional automated teller machine. As shown in FIG. 2, the main body 100 of the automated teller machine is configured to include a housing portion 201 and a drawer portion 202. Although the drawer portion 202 is shown in a state of being pulled out from the housing portion 201 in FIG. 2, it is normally contained in the housing portion 201. A plurality of banknote storages 211 are contained in the drawer unit 202, and in the example of FIG. 2, five banknote storages 211 are contained in the drawer unit 202. Hereinafter, when distinguishing each banknote storage, they are distinguished by subscripts such as 211a, 211b, 211c, 211d, 211e, etc., and when indicating the entire banknote storage, they are referred to as banknote storage 211. ..

Conventionally, as shown in FIG. 2, the housing portion 201 and the bill storage 211 are electrically connected to each other by connecting a plurality of connectors 212 provided on the main body side board 210 and connectors 213 in the bill storage 211. Wired connection. The connector 212 on the main body side board 210 and the connector 213 of the bill storage 211 can be attached to and detached from each other by inserting and removing the corresponding uneven portions having a predetermined shape provided in both connectors. Various sensors and actuators such as solenoids and servomotors are incorporated in the bill storage 211, and perform predetermined operations regarding the storage and ejection of bills.

The plurality of connectors 212 of the main body side board 210 are connected to the control unit 207 and the power supply / actuator unit 208 in the housing unit 201 via data wiring and power supply wiring called leader wire 209. The plurality of connectors 212 of the main body side board 210 mediate the power supply, the actuator control in the bill storage 211, and the exchange of information of various sensors. The actuator control in the bill storage 211 may be performed by creating a signal on the main body side board 210 from the power supply and the actuator control information.

The operation of a general automatic teller machine 100 in a normal state in which the drawer portion 202 is housed in the housing portion 201 is shown below. When depositing money, when the banknotes are deposited from the deposit / withdrawal unit 203, the banknotes are transported via the banknote transport path 206, the authenticity and denomination of the banknotes are determined by the identification unit 204, and the customer uses the temporary holding unit 205. It will be temporarily suspended until the payment is confirmed. After that, the bills are sorted into the bill storages 211a, 211b, 211c, 211d, and 211e according to the denomination via the bill transport path 206. In the case of withdrawal, it will be withdrawn by the reverse route. These operations are realized by obtaining sensor information of each unit including the inside of the bill storage 211 in the control unit 207 and the power supply / actuator unit 208, and controlling the actuator according to the information.

FIG. 3 is an example of a configuration diagram of an automated teller machine according to the first embodiment of the present invention. In the automatic teller machine according to the first embodiment of the present invention, the connectors 212 and 213 shown in FIG. 2 are not used, and instead of these, the power transmission of the power supply, the actuator control, and the information of various sensors are used. Communication is done wirelessly. That is, in the automated teller machine according to the first embodiment of the present invention, the main body side board 210 is not provided with the connector 212, and the main body side wireless unit 102 is placed on the main body side board 210 in the bill storage 120. One or more are provided depending on the number of entering. Hereinafter, when distinguishing each banknote storage, they are distinguished by subscripts such as 120a, 120b, 120c, 120d, 120e, etc., and when indicating the entire banknote storage, they are referred to as banknote storage 120. .. A wireless unit is provided in each of the bill storages 120a to 120e.

Returning to the description of FIG. FIG. 1 shows a main body side wireless unit 102 on the main body side substrate 210 and one system of constituent blocks for making the bill storage 120 wireless.

The main body side control unit 101 controls the main body side wireless unit 102 in addition to the control of the main body 100. Here, wireless power transmission from the main body side wireless unit 102 to the bill storage 120 will be described.

The main body side control unit 101 outputs a clock 108 having a first carrier frequency for wireless power transmission to the power supply unit 103. The power supply unit 103 supplies the output power 110 according to the output power control signal 107 from the main body side control unit 101 to the main body side power transmission coil 104. The main body side power transmission coil 104 is connected to a capacitor so as to resonate at the first carrier frequency for wireless power transmission, whereby the wireless power 121 due to the magnetic field is transmitted. Although the power transmission coil 104 on the main body side of FIG. 1 shows a series resonance configuration, it may have a parallel resonance configuration. Further, the main body side power transmission coil 104 is not limited to the so-called coil in terms of its shape, material and the like, and may be any magnetic antenna capable of transmitting wireless power 121 without modulation.

The bill storage side power receiving coil 112 is connected to a capacitor so as to resonate at the first carrier frequency for wireless power transmission, whereby the wireless power 121 due to the magnetic field is received. Although the power receiving coil 112 on the banknote storage side in FIG. 1 shows a series resonance configuration, it may have a parallel resonance configuration. Further, the bill storage side power receiving coil 112 is not limited to the so-called coil in terms of its shape, material and the like, and may be a magnetic antenna capable of receiving wireless power 121 without modulation.

The received power 123 received by the bill storage side power receiving coil 112 is rectified by the rectifying unit 113 to become the rectified power 124, becomes a stable direct current by the DC-DC converter 114, and is supplied to each block.

The bill storage control unit 119 receives the power supply and controls the power supplied to the power usage unit 115 by the control signal 127. The power-using unit 115 is various sensors and actuators such as solenoids and servomotors. The electric power use unit 115 performs an operation required in the bill storage 120 by receiving the supply of the electric power 125, and outputs the obtained information 126 to the bill storage control unit 119.

Next, a mechanism for transmitting control information for controlling the inside of the bill storage 120 from the main body 100 to the bill storage 120 will be continuously described with reference to FIG. 1.

A part 131 of the electric power obtained by the DC-DC converter 114 is supplied to the buffer 116. The buffer 116 buffers the clock 128 of the second carrier frequency output from the bill storage control unit 119, and supplies the output power 129 to the bill storage side coil 117. A coil is connected to the bill storage side coil 117 so as to resonate at a second carrier frequency for wireless power transmission, whereby wireless power 122 due to a magnetic field is transmitted. Although the bill storage side coil 117 in FIG. 1 shows a series resonance configuration, it may have a parallel resonance configuration. Further, the bill storage side coil 117 is not limited to the so-called coil in terms of its shape, material and the like, and may be a magnetic antenna capable of transmitting wireless power 122 without modulation.

A coil is connected to the main body side coil 106 so as to resonate at a second carrier frequency for wireless power transmission, whereby the wireless power 122 due to a magnetic field is received. Although the main body side coil 106 in FIG. 1 shows a series resonance configuration, it may have a parallel resonance configuration. Further, the coil 106 on the main body side is not limited to the so-called coil in terms of its shape, material and the like, and may be a magnetic antenna capable of receiving wireless power 122 without modulation.

The electric power 111 received by the coil 106 on the main body side is consumed by the load 105. By changing this load state from the main body side control unit 101 using the control signal 109, the wireless power 122 fluctuates. The control signal 109 is changed from the main body 100 in correspondence with the control information for controlling the bill storage 120 to control the fluctuation of the wireless power 122. The fluctuation of the radio power 122 is detected and demodulated by the control information demodulation unit 118 on the bill storage side. The signal 130 obtained by being detected and demodulated is control information for controlling the bill storage 120 from the main body 100. By outputting this to the bill storage control unit 119 by the control information demodulation unit 118 on the bill storage side, the bill storage control unit 119 can recognize the control information for controlling the bill storage 120 from the main body 100. ..

The transmission of control information for controlling the inside of the bill storage 120 from the main body 100 to the bill storage 120 will be described in detail with reference to FIGS. 4 to 7.

FIG. 4 is an example of a configuration diagram relating to a control transmission operation of the automated teller machine according to the first embodiment of the present invention. FIG. 5 is a circuit diagram of a load according to the first embodiment of the present invention. FIG. 6 is a circuit diagram of a control information demodulation unit according to the first embodiment of the present invention. FIG. 7 is a diagram showing an example of a signal waveform of an automated teller machine according to the first embodiment of the present invention.

The period 321 shown in FIG. 7 is a period during which control information for controlling the inside of the banknote storage 120 is not transmitted from the main body 100 to the banknote storage 120, and the period 322 is a period in which the banknotes are stored from the main body 100 to the banknote storage 120. This is the period during which the control information for controlling the inside of the storage 120 is transmitted.

As shown in FIG. 5, the load 105 provided in the main body 100 includes, for example, resistors 301 and 303, and an NaCl-FET 302. ON / OFF of the NaCl-FET 302 is controlled by the control signal 109. In the example of FIG. 5, High is ON and Low is OFF. Therefore, when the load 105 is OFF, the load is the load of only the resistor 303, and when the load 105 is ON, the load is the parallel of the resistors 301 and 303 when the ON resistance of the µ-FET 302 is ignored.

The period 321 during which the control information for controlling the inside of the banknote storage 120 is not transmitted from the main body 100 shown in FIG. 7 to the banknote storage 120 can be realized by turning off the nanotube-FET 302. That is, when the load state of the load 105 is the resistance 303, the radio power 122 shows the waveform shown in the period 321 of FIG. In this method, the buffer 116 is supplied with a part 131 of the electric power obtained by the DC-DC converter 114, and the clock 128 of the second carrier frequency is buffered to obtain the output electric power 129, which is used as the bill storage side coil 117. Corresponds to the unmodulated radio power 122 supplied to and transmitted to.

For the period 322 in which the control information for controlling the inside of the bill storage 120 is transmitted from the main body 100 shown in FIG. 7 to the bill storage 120, the control signal 109 is used as the control information for controlling the bill storage 120 from the main body 100. Correspondingly, the control signal 109 is changed to High / Low. When the nanotube-FET 302 is ON, the load state of the load 105 is parallel to the resistors 301 and 303, which is smaller than that of the resistor 303 alone. At this time, reflected power (corresponding to the signal 130 detected and demodulated) is generated from the main body 100, and the radio power 122 is combined with the reflected power, so that the amplitude changes. Therefore, the amplitude of the radio power 122 changes according to the High / Low of the control signal 109.

As shown in FIG. 6, the control information demodulation unit 118 includes a detection unit 304, a filter unit 305, and a voltage shift unit 306.

The detection unit 304 detects the envelope, which is a change in the amplitude of the radio power 122, at the detection unit 304. The filter unit 305 removes frequency components above the second carrier frequency. The voltage shift unit 306 determines the threshold identification voltage of the demodulated signal and outputs it as the detected and demodulated signal 130.

The detection unit 304 is composed of a so-called voltage doubler detection circuit. For example, in the detection unit 304, the received output power 129 is connected to the node 1 via the capacitor 307 so that the diode 308 is turned ON from the GND in the direction of the node 1, and the diode 309 is connected in the direction from the node 1 to the node 2. The capacitor 310 is connected between the node 2 and the GND, the resistor 311 is connected between the node 2 and the GND, and the node 2 is used as an output.

The filter unit 305 is composed of a so-called twin T notch filter circuit. For example, in the filter unit 305, the resistor 312 is connected between the input node and the node 3, the resistor 313 is connected between the node 3 and the node 4, and the capacitor 314 is connected between the node 3 and GND. Then, the capacitor 315 is connected between the input node and the node 5, the capacitor 316 is connected between the node 5 and the node 4, the resistor 317 is connected between the node 5 and GND, and the node 4 is output. For example, when the second carrier frequency of the clock 128 is 3.39 MHz (megahertz), the resistor 312, 313 is about 6.8 kΩ (kiloohm), the resistor 317 is about 1.8 kΩ, and the capacitor 314, 315, 316 is about 10 pF (. Pico Farad).

For example, the voltage shift unit 306 divides the node 6 via the capacitor 318 between the voltage Vdd and GND due to the electric power obtained by the DC-DC converter 114 by the resistor 319 and the resistor 320 to determine the threshold identification voltage. .. However, at this time, the control signal 109 removes the DC voltage by Manchester coding or another coding method.

With the above configuration, the control information demodulation unit 118 obtains the detected and demodulated signal 130 as a signal in which High / Low of the control signal 109 is inverted.

The above is the configuration of the automated teller machine according to the first embodiment of the power transmission / reception system including the power transmitter and the power receiver according to the present invention. According to the first embodiment of FIG. 1, control information for controlling the inside of the bill storage 120 is transmitted from the main body 100 to the bill storage 120 with a simple configuration of changing the load state of the load 105 on the main body 100 side. Therefore, there is an effect that the transmission of control information can be realized at low cost. Further, since the value of the load state of the load 105 can be set only under a simple condition that the control information can be transmitted, there is an effect that the optimum value can be set even with a small amount of power.

[Second Embodiment] FIG. 8 is an example of a block diagram of an automated teller machine according to a second embodiment of the present invention. In the first embodiment shown in FIGS. 1 and 3 to 7, control is performed between the bill storage side coil 117 and the main body side coil 106 to control the inside of the bill storage 120 from the main body 100 to the bill storage 120. Information is transmitted, but in the embodiment shown in FIG. 8, in addition to this, sensor information in the bill storage 120 is transmitted from the bill storage 120 to the main body 100 between the main body side coil 106 and the bill storage side coil 117. It has a configuration for transmitting banknote storage information.

The operation of the automated teller machine of FIG. 8 will be described with reference to FIG. FIG. 9 is an example of a block diagram relating to the operation of the switching unit that controls the banknote storage of the automated teller machine according to the second embodiment of the present invention. In the second embodiment, the mechanism of wireless power transmission from the main body side wireless unit 102 to the bill storage 120 is the same as in FIG.

In FIG. 9, a switching unit 413 on the banknote storage side relating to transmission of control information for controlling the inside of the banknote storage 120 from the main body 100 to the banknote storage 120 between the coil 117 on the banknote storage side and the coil 106 on the main body side. , The operation of the switching unit 402 on the main body side is shown.

When a part 131 of the electric power obtained by the DC-DC converter 114 is supplied to the buffer 116, the buffer 116 buffers the clock 128 of the second carrier frequency from the banknote storage control unit 119 and outputs the output power. 129 is output to the switching unit 413. When the switching unit 413 receives the control signal 411 from the bill storage control unit 119, the switching unit 413 supplies the output power 129 to the bill storage side coil 117 (transmission 415T) and connects to the control information demodulation unit 118 (transmission 416). ..

A coil is connected to the bill storage side coil 117 so as to resonate at a second carrier frequency for wireless power transmission, whereby wireless power 122 due to a magnetic field is transmitted. A coil is connected to the main body side coil 106 so as to resonate at a second carrier frequency for wireless power transmission, whereby the wireless power 122 due to a magnetic field is received. The received power 404 received is output to the switching unit 402.

When the switching unit 402 receives the control signal 410 from the main body side control unit 101, the receiving power 404 is connected to the load 105 (transmission 409), and the received power 404 is consumed by the load 105. By changing this load state from the main body side control unit 101 using the control signal 109, the wireless power 122 fluctuates. The control signal 109 controls the fluctuation of the wireless power 122 by being changed in correspondence with the control information for controlling the inside of the bill storage 120 transmitted from the main body 100 to the bill storage 120. The fluctuation of the radio power 122 is detected and demodulated by the control information demodulation unit 118 on the bill storage side. The signal 130 obtained by being detected and demodulated is control information for controlling the bill storage 120 from the main body 100. By outputting this to the bill storage control unit 119 by the control information demodulation unit 118 on the bill storage side, the bill storage control unit 119 can recognize the control information for controlling the bill storage 120 from the main body 100. .. The above mechanism is the same as the operation of transmitting control information for controlling the inside of the bill storage 120 from the main body 100 according to the first embodiment to the bill storage 120.

FIG. 10 is an example of a block diagram relating to the operation of the switching unit for transmitting information to the main body of the automated teller machine according to the second embodiment of the present invention. In FIG. 10, the bill storage side is related to the case where bill storage information such as sensor information in the bill storage 120 is transmitted from the bill storage 120 to the main body 100 between the main body side coil 106 and the bill storage side coil 117. The operation of the switching unit 413 and the switching unit 402 on the main body side is shown.

The buffer 401 in the main body side wireless unit 102 buffers the clock 407 of the second carrier frequency from the main body side control unit 101, and outputs the output power 408 to the switching unit 402. Upon receiving the control signal 410 from the main body side control unit 101, the switching unit 402 supplies the output power 408 to the main body side coil 106 (transmission 404T) and connects to the bill storage information demodulation unit 403 (transmission 405).

A coil is connected to the main body side coil 106 so as to resonate at a second carrier frequency for wireless power transmission, whereby wireless power 414 due to a magnetic field is transmitted. The bill storage side coil 117 is connected to a capacitor so as to resonate at a second carrier frequency for wireless power transmission, thereby receiving wireless power 414 due to a magnetic field. The received power 415 received is output to the switching unit 413.

When the switching unit 413 receives the control signal 411 from the bill storage control unit 119, the switching unit 413 connects the received power 415 to the load 412 (transmission 417), and the received power 415 is consumed by the load 412. By changing this load state from the bill storage control unit 119 using the control signal 418, the wireless power 414 fluctuates. The control signal 418 is changed in correspondence with the bill storage information such as the sensor information in the bill storage 120 transmitted from the bill storage 120 to the main body 100 to control the fluctuation of the wireless power 414. The fluctuation of the wireless power 414 is detected and demodulated by the bill storage information demodulation unit 403 on the main body side. The signal 406 obtained by being detected and demodulated is banknote storage information such as sensor information in the banknote storage 120 transmitted from the banknote storage 120 to the main body 100. By outputting this to the main body side control unit 101, the main body side control unit 101 can recognize the bill storage information such as the sensor information in the bill storage 120 transmitted from the bill storage 120 to the main body 100. .. In the above mechanism, the direction of the wireless power between the main body side coil 106 and the bill storage side coil 117 is opposite to that of FIG. 9, as in the case of the wireless power 122 to the wireless power 414, and the buffer 401 and the buffer 116. , The load 412 and the load 105, and the operations of the bill storage information demodulating unit 403 and the control information demodulating unit 118 are switched. Further, the buffer 401 and the buffer 116, the load 412 and the load 105, and the bill storage information demodulation unit 403 and the control information demodulation unit 118 each have the same circuit configuration.

With reference to FIGS. 8 to 10, the configuration of the automated teller machine according to the second embodiment of the power transmission / reception system including the transmitter and the power receiver according to the present invention has been described above. According to the second embodiment, the control information for controlling the inside of the bill storage 120 can be transmitted from the main body 100 to the bill storage 120 with a simple configuration of changing the load state on the main body 100 side. With a simple configuration of changing the load state of the load 105 of the load 412 on the banknote storage 120 side, banknote storage information such as sensor information in the banknote storage 120 can be transmitted from the banknote storage 120 to the main body. Therefore, there is an effect that the transmission of control information and banknote storage information can be realized at low cost. Further, since the load state values of the load 105 and the load 412 can be set only on the condition that the control information and the bill storage information can be transmitted, the optimum values can be set even with a small amount of power. effective.

During the above operation, when the buffer 116 or the buffer 401 is not selected for the switching unit 413 or the switching unit 402, respectively, the clock 128 or the clock 407 is stopped, or the power 131 or the buffer 401 of the buffer 116 is used. The operation of the buffer 116 or the buffer 401 may be stopped by stopping the power supply or the like.

[Third Embodiment] FIG. 11 is an example of a block diagram of an automated teller machine according to a third embodiment of the present invention. Also in the third embodiment shown in FIG. 11, similarly to FIG. 8, control information for controlling the inside of the bill storage 120 from the main body 100 to the bill storage 120 between the bill storage side coil 117 and the main body side coil 106. In addition to the transmission of the above, the banknote storage information such as the sensor information in the banknote storage 120 is transmitted from the banknote storage 120 to the main body 100.

The third embodiment differs from the second embodiment in that the three-state buffer 603 and the three-state buffer 601 are used instead of the switching unit 413 and the buffer 116, and the switching unit 402 and the buffer 401, respectively. Is.

When the control information for controlling the inside of the bill storage 120 is transmitted from the main body 100 to the bill storage 120 by using the bill storage side coil 117 and the main body side coil 106 as in FIG. 9, the 3-state buffer 601 is set to high. The impedance and the three-state buffer 603 are controlled by the control signal 410 and the control signal 411, respectively, so as to be an output. At this time, the difference from FIG. 9 is that the banknote storage information demodulation unit 403 is connected in FIG. If the input impedance of the bill storage information demodulation unit 403 is set to a high impedance that does not affect the value of the load state of the load 105, it does not affect the fluctuation of the wireless power 122 due to the change of the load state.

When transmitting bill storage information such as sensor information in the bill storage 120 from the bill storage 120 to the main body 100 by using the main body side coil 106 and the bill storage side coil 117 as in FIG. 10, a 3-state buffer is used. The 603 is controlled by the control signal 411 and the control signal 410, respectively, so that the high impedance and the three-state buffer 601 are outputs. At this time, the difference from FIG. 10 is that the control information demodulation unit 118 is connected in FIG. If the input impedance of the control information demodulation unit 118 is set to a high impedance that does not affect the value of the load state of the load 412, it does not affect the fluctuation of the radio power 414 due to the change of the load state.

According to the automatic teller machine according to the third embodiment of FIG. 11, since the same operation as that of the second embodiment can be realized with a simpler circuit configuration, control information and bill storage information can be transmitted. There is an effect that can be realized at low cost. Further, since the bill storage information demodulation unit 403 is always connected to the transmission 602 and the control information demodulation unit 118 is always connected to the transmission 604, the change in the load state of the load 105 is notified to the bill storage information demodulation unit 403, respectively. Alternatively, the control information demodulation unit 118 echoes back the change in the load state of the load 412 to the main body side control unit 101 as a signal 406 and to the bill storage control unit 119 as an operation confirmation signal as a signal 130, respectively. There is an effect that can be done.

[Fourth Embodiment] FIG. 12 is an example of a block diagram of an automated teller machine according to a fourth embodiment of the present invention. Similar to FIGS. 8 and 11, the embodiment of FIG. 12 also uses the bill storage side coil 117 and the main body side coil 106 to provide control information for controlling the inside of the bill storage 120 from the main body 100 to the bill storage 120. In addition to the transmission, the banknote storage information such as the sensor information in the banknote storage 120 is transmitted from the banknote storage 120 to the main body 100.

The difference from the automatic teller machine according to the third embodiment of FIG. 11 is that the power-using unit 115 is divided into two systems, a drive system power-using unit 701 and a sensor-based power-using unit 702.

The drive system power-using unit 701 operates an actuator system such as a solenoid, a DC motor, or a stepping motor. These actuator systems generally have a higher drive voltage and a larger drive current than the sensor system. As the drive voltage, for example, 24 V (volt) or 12 V is used, and the drive current is generally, for example, about 1 A (ampere). Further, in the sensor system, it is necessary that the input voltage is stabilized, but in the actuator system, even if the drive voltage is not stabilized, there is often no problem in driving.

Therefore, the rectified power 124, which is the output of the rectified unit 113, can be directly supplied to the drive system power-using unit 701. The drive system power usage unit 701 controls drive ON / OFF and forward / reverse rotation by a control signal 705 from the bill storage control unit 119, and outputs an operation confirmation signal 704 to the bill storage control unit 119 in some cases. do.

The sensor-based power-using unit 702 operates, for example, an optical sensor, and generally operates at a voltage of about 5 V, and consumes at most 100 mA (milliampere) / piece, but to some extent. A regulated voltage is often required. Therefore, the sensor system power usage unit 702 is supplied with power stabilized to the required voltage from the DC-DC conversion unit 114. The sensor system power usage unit 702 is given control information necessary for sensor operation by a control signal 707 from the bill storage control unit 119, and outputs the sensor information 706 obtained by the sensor to the bill storage control unit 119.

According to the automatic trading apparatus according to the fourth embodiment of FIG. 12, when there are a plurality of systems having different drive voltages such as the drive system power use unit 701 and the sensor system power use unit 702 on the power receiving side, Since it is not necessary for the DC-DC converter 114 to generate the drive voltage required for each system, there is an effect that the configuration can be made at low cost.

Here, the problem of the drive voltage when the device to which the DC power is generally supplied by wire is converted into the power supply by wireless will be described with reference to FIG.

FIG. 13 is a diagram illustrating a problem of power supply of a general automated teller machine. Consider a case where a system that has been supplied with power by wire, for example, with a drive voltage of 24 V, is divided into a power transmission system and a power reception system, and wireless power is transmitted from the power transmission system to the power reception system. In the case of wireless power transmission, it is necessary to temporarily convert AC (AC) on the power transmission side, and it is necessary to rectify the AC power and convert it to DC on the power receiving side. At this time, if the transmission voltage is not adjusted, it is generally a 24V peak-to-peak alternating current, so even if full-wave rectification is performed by rectification, only half the voltage of 12V can be obtained on the power receiving side. In reality, since the AC waveform is sinusoidal and has conversion efficiency in rectification, the received voltage on the receiving side is smaller than 12V. Therefore, even if wireless power is transmitted, it is necessary to boost the voltage in order to obtain the same receiving voltage as the wired one. As a method of this boosting, boosting on the power transmission side and boosting on the power receiving side can be considered.

On the other hand, on the power receiving side, for example, in the fourth embodiment of FIG. 12, [1] each drive block such as the bill storage control unit 119, [2] the drive system power usage unit 701 and [1], [3] sensors. There are power usage statuses such as the system power usage unit 702 and [1], the drive system power usage unit 701 and the sensor system power usage unit 702 and [1]. Therefore, it is necessary to adjust the wireless power on the power transmission side according to each power usage situation.

A method of adjusting the voltage on the power transmission side can be conceivable for these wireless power adjustments and boosting to the same receiving voltage as the wired one described above. FIG. 13 shows an example in which 24V is converted to 48V by voltage doubler AC to become 24V on the power receiving side. FIG. 14 shows a method of adjusting the voltage on the power transmission side.

FIG. 14 is an example of a block diagram of a power supply unit of an automated teller machine according to a fourth embodiment of the present invention.
FIG. 14 shows a configuration block when the power supply amplifier 902 is of a type in which the output gain is variable according to the supplied power supply voltage. Specifically, this is the case where the amplifier 902 has a class E amplifier configuration.

The voltage of the power supply 903 is stepped up or down in the voltage adjusting unit 901 according to the output power control signal 107 from the main body side control unit 101, and is used as the supply voltage to the amplifier 902. As a result, the clock 108 having the first carrier frequency input to the amplifier 902 has a variable power amplification gain depending on the supply voltage value. The voltage adjusting unit 901 is composed of a step-up / down chopper, a step-up chopper, a step-down chopper, and the like. The output power control signal 107 is used as a PWM (Pulse Width Modulation) wave, and the supply voltage value can be adjusted by changing the duty ratio thereof. Since the peak-to-peak value of the output voltage can be designed to be larger than the supply voltage in the class E amplifier, the class E amplifier is designed so that the maximum value of the required voltage on the receiving side can be supplied, and the voltage adjustment unit 901 is stepped down chopper. It is possible to configure with. Further, it is also possible to design a class E amplifier so as to supply the minimum value of the required voltage on the power receiving side when the voltage of the power supply 903 is used, and to configure the voltage adjusting unit 901 with a step-up chopper.

FIG. 15 is another example of a block diagram of a power supply unit of an automated teller machine according to a fourth embodiment of the present invention. FIG. 15 shows a configuration in which the power supply amplifier 905 can adjust the gain according to the output power control signal 107. Specifically, this is a case where the amplifier 905 is composed of a voltage amplification unit and a buffer unit whose gain can be adjusted.

If the voltage of the power supply 903 is boosted by the booster 904 until the maximum value of the required voltage on the power receiving side can be supplied and supplied to the amplifier 905, the clock 108 of the first carrier frequency input to the amplifier 905 is output as an output power control signal. The voltage is amplified or attenuated according to the gain adjustment of 107, and can be buffered from 0 V to the voltage boosted by the booster unit 904.

According to the constituent blocks of the power supply unit 103 exemplified in FIGS. 14 and 15, the problem of voltage drop when the power supply is changed from the wired to the wireless shown in FIG. 13 can be overcome, and the above-mentioned [1]. ] To [4], it has the effect of being able to handle any of the power usage conditions on the power receiving side.

FIG. 16 is an example of a diagram showing a configuration example of a banknote storage of an automated teller machine according to a fourth embodiment of the present invention. Specifically, it is a connection example of the rectifying unit 113, the DC-DC conversion unit 114, the drive system power usage unit 701, and the sensor system power usage unit 702 of the banknote storage 120 of the automatic teller machine.

The electric power received by the power receiving coil 112 on the bill storage side is rectified by the rectifying unit 113, smoothed by the capacitor 1001 connected to the GND, becomes the electric power 1005, and is supplied to the drive system power using unit 701. The electric power 1005 further becomes the electric power 1006 via the diode 1002. The diode 1002 is connected from the rectifying unit 113 to the DC-DC conversion unit 114 in the direction in which a current flows.

The electric power 1006 becomes the electric power 1007 through a filter composed of the inductor 1003, the capacitor 1004 connected to the GND, and is supplied to the DC-DC conversion unit 114. The DC-DC converter 114 supplies electric power 1008, which is a regulated voltage required by the sensor-based power-using unit 702, to the sensor-based power-using unit 702.

Regarding the above operation, FIG. 17 is used to show an example in which the drive system power consumption unit 701 is a solenoid.

FIG. 17 is an example of a diagram showing an example of a signal waveform when the drive power usage unit of the automated teller machine according to the fourth embodiment of the present invention is a solenoid. The graph shown in FIG. 17A represents an output power control signal 107 that controls a power supply unit 103 included in the main body 100 of the fourth embodiment shown in FIG. The horizontal axis is the time axis, and the vertical axis is the magnitude of the gain of the power supply unit 103. The period 1101 and the period 1104 are periods for supplying power for each drive block ([1]) such as the above-mentioned [3] sensor system power use unit 702 and bill storage control unit 119. The period 1102 and the period 1103 are periods for supplying power for each drive block ([1]) such as [4] drive system power use unit 701, sensor system power use unit 702, and bill storage control unit 119. .. Of these, period 1102 is a period of strong excitation for starting the solenoid, and period 1103 is a period of weak excitation for maintaining the solenoid.

According to the output power control signal 107 of FIG. 17A, the output power 110 of the power supply unit 103, the wireless power 121 which is the output of the main body side power transmission coil 104, and the power received power 123 of the bill storage side power receiving coil 112 , Take the waveform of FIG. 17 (b). In the electric power 1005 smoothed by the capacitor 1001, the waveform of the envelope is obtained by the rectification by the rectifying unit 113 and the time constant due to the capacity of the capacitor 1001, and the waveform of FIG. 17A is obtained. The control signal 705 from the bill storage control unit 119 turns on the solenoid during the period 1102 and 1103, the solenoid operates, and the solenoid echo indicating the operation of the solenoid is output to the bill storage control unit 119 as an operation confirmation signal 704. Will be done.

At this time, the electric power 1007 input to the DC-DC converter 114 has the waveform shown in FIG. 17 (c) due to the effect of the filter composed of the diode 1002, the inductor 1003, and the capacitor 1004. Due to the effect of the diode 1002, it is possible to prevent the backflow of the current from the capacitor 1004 to the power 1005 side at the time of the weak excitation period 1103 without power or the steep rise of the strong excitation period 1102. Further, it is possible to avoid falling below the input voltage required by the DC-DC converter 114 in the power 1007. Further, the inductor 1003 makes it possible to obtain the envelope of FIG. 17A by making the capacitance of the capacitor 1004 other than the capacitor 1001 invisible to the capacitor capacitance at the power of 1005 when the diode 1002 is turned on.

Due to the effect of preventing the backflow of the diode 1002, the power 1007 does not fall below the input voltage required by the DC-DC converter 114. Therefore, the power 10008, which is the output of the DC-DC converter 114, can be supplied to the sensor-based power-using unit 702 with the regulated voltage required by the sensor-based power-using unit 702 shown in FIG. 17 (d).

As described above, the second electric power is between the first electric power-using system that uses a large amount of electric power or intermittently uses electric power and the second electric power-using system that requires stable electric power. By inserting the diode in the direction in which no current flows from the used system to the first power-using system, there is an effect of stabilizing the input voltage of the second power-using system.

FIG. 18 is an example of a diagram showing a configuration when a constant load unit is added to the drive system of the automated teller machine according to the fourth embodiment of the present invention. In the configuration shown in FIG. 18, a constant load unit 1201 that suppresses the influence of fluctuations in the amount of power consumption of the drive system power usage unit 701 is further added to the connection example of FIG. The operation of FIG. 18 will be described with reference to FIGS. 19, 20, and 21. In this example, the case where the drive system power usage unit 701 is a DC motor is used.

FIG. 19 is an example of a diagram showing a configuration in a case where the drive power consumption unit of the automatic teller machine according to the fourth embodiment of the present invention is a DC motor. Electric power 1005 is supplied to the driver 1301, and the driver 1301 controls the connected DC motor 1302 to switch between rotation ON / OFF and forward / reverse rotation according to the control signal 705 from the bill storage control unit 119. conduct.

FIG. 20 is an output characteristic diagram of a general DC motor. In a general DC motor, the maximum torque is exhibited in a state where the rotational load is large and the rotation speed is low, and the maximum current flows in that state.

FIG. 21 is a diagram showing an example of DC motor drive power of the automated teller machine according to the fourth embodiment of the present invention. FIG. 21A is a graph showing an output power control signal 107 that controls a power supply unit 103 included in the main body 100 of the fourth embodiment. The horizontal axis is the time axis, and the vertical axis is the magnitude of the gain of the power supply unit 103. The period 1501 and the period 1503 are periods for supplying power for each drive block ([1]) such as the above-mentioned [3] sensor system power use unit 702 and bill storage control unit 119. The period 1502 is a period for supplying power for each drive block ([1]) such as [4] drive system power use unit 701, sensor system power use unit 702, and bill storage control unit 119.

As described with reference to FIG. 17, the waveform of FIG. 21 (a) is obtained at the power 1005 as the envelope of the received power. According to the control signal 705 from the bill storage control unit 119, the DC motor 1302 is turned on and the DC motor operates in the period 1502. The current waveform of the electric power 1005 at this time is shown in FIG. 21 (b), and the voltage waveform is shown in FIG. 21 (c). It is assumed that the DC motor 1302 is initially stopped, starts to rotate, a rotational load is applied after the period 1504, and is stopped for the period 1505.

Immediately after the first motor ON control in the period 1502, the motor is stopped and a rotational load of a certain size of the static friction coefficient is applied, so that a large amount of current flows for a moment. After that, when the motor starts to rotate, the rotational load decreases and the current decreases. Then, in the period 1505, the maximum current flows because the motor is stopped due to the rotational load.

On the other hand, in the period 1502, since wireless power is transmitted with enough power to supply the maximum current at the maximum rotation load, that is, when the motor is stopped at the rated voltage, the required current is reduced while the motor is rotating, and the power is supplied. It becomes too much. Therefore, the voltage rises. During the period 1505 when the maximum current is consumed, the supplied power and the required power are balanced and become the rated voltage of the motor. This voltage rise may occur at the power of 1005 and may exceed the withstand voltage of peripheral components.

In order to prevent the withstand voltage of peripheral parts from being exceeded, the constant load unit 1201 switches on when the voltage exceeds a certain constant voltage to release the current, and the load combined with the drive system power usage unit 701 is made constant, and the voltage is changed. Do not go above this. In a specific circuit, as shown in FIG. 18, a resistor 1202 is provided between the input contact of the drive system power-using unit 701 and the node 1, and the node 1 and the diode are generated so that the Zener voltage is generated at the node 1. A Zener diode 1203 is provided between the two. On the other hand, the source of the polyclonal-FET 1204 is connected to the input node, the gate is connected to the node 1, the drain is connected to the node 2, and the resistor 1205 is provided between the node 2 and the GND.

With such a configuration, when the voltage of the input node, that is, the power 1005 rises and exceeds the Zener voltage, a potential difference is generated across the resistor 1202 so that the polyclonal-FET 1204 is turned on. Is turned on, and a current flows through the resistor 1205. As a result, the load at the input node combined with the drive system power-using unit 701 can be made constant, and the voltage rise of the power 1005 can be suppressed. FIG. 21D shows a voltage waveform of the electric power 1005 when the constant load unit 1201 is added. It can be said that the voltage rise is suppressed as compared with the example of FIG. 21 (c).

As described above, in the fourth embodiment, when the constant load unit 1201 shown in FIG. 18 is provided, it is driven when the rotational load during rotation when the DC motor is used for the drive system power usage unit 701 is light. It has the effect of suppressing an increase in the input voltage of the system power usage unit 701. At this time, the load of the constant load unit 1201 is adjusted so that the upper limit of the input voltage is the maximum power consumption used by the DC motor. Further, when the power transmission side transmits more power than the power required by the power reception side, the effect of suppressing the voltage rise on the power reception side can be obtained.

FIG. 22 is a diagram showing an operation flow of a drive system power-using unit of an automated teller machine according to a fourth embodiment of the present invention. FIG. 22 shows an operation flow for operating the drive system power-using unit 701 shown in FIG. 17 or 21 in the configuration block of the automated teller machine of FIG. 12. In FIG. 22, when information is transmitted from the main body 100 to the bill storage 120, the load state of the load 105 of the wireless power 122 is changed and the information is obtained by the control information demodulation unit 118, and the information is obtained from the bill storage 120. When the information is transmitted to the main body 100, the load state of the load 412 of the wireless power 414 is changed and the information is obtained by the bill storage information demodulation unit 403.

First, the main body side control unit 101 of the main body 100 instructs the start of operation of the drive system power use unit 701 (step S1601).

Next, the bill storage control unit 119 receives the operation start information and sets the operation of the drive system power usage unit 701 to ON by the control signal 705. After the setting, the bill storage control unit 119 transmits the preparation completion information to the main body 100 (step S1602).

Then, the main body side control unit 101 controls the power supply unit 103 by the output power control signal 107 to emit the radio power for the drive system power use unit 701 (in the state of the above [4]) (step S1603).

Then, the bill storage control unit 119 observes the state inside the bill storage 120 with a sensor or the like, and transmits predetermined bill storage information including the sensor information obtained as a result of the observation to the main body 100 (step S1604). ..

Then, the bill storage control unit 119 detects the completion of the operation of the drive system power usage unit 701 and requests the main body 100 to end the wireless power transmission operation (step S1605).

Then, the power supply unit 103 changes from the state of emitting the wireless power for the drive system power usage unit 701 to the normal power ([1] or [2] above), and the main body side control unit 101 performs the normal operation as a bill. Notify the storage control unit 119 (step S1606). In response to this, the bill storage control unit 119 sets the operation of the drive system power usage unit 701 to OFF by the control signal 705.

According to the configuration of the automatic teller machine according to the fourth embodiment of FIG. 12, by the above series of operations, the main body 100 and the bill storage are stored in a state where wireless power is sent from the main body 100 to the bill storage 120. There is an effect that information can be exchanged between the warehouses 120.

FIG. 23 is a diagram showing an initial operation flow of the automated teller machine according to the fourth embodiment of the present invention.

First, in the initial initial state between the main body 100 and the bill storage 120, the main body side control unit 101 first emits wireless power 121 to confirm the existence of the bill storage 120 on the main body 100 side (step S1701). .. The electric power at this time is the electric power in the state of the above [1], that is, the electric power for operating each drive block such as the bill storage control unit 119.

Then, the bill storage 120 receives the wireless power 121, and power is supplied from the DC-DC conversion unit 114 to the bill storage control unit 119 and the like for the initial operation of the drive block. As a result, the bill storage control unit 119 is activated, and under the control of the bill storage control unit 119, the 3-state buffer 603 is operated by a part of the power 131 of the received power, and the bill storage side coil 117 is used. The radio power 122 is emitted (step S1702).

Then, the main body 100 side changes the 3-state buffer 601 to a high impedance state by the control signal 410 from the main body side control unit 101, and outputs the bill storage information demodulation unit 403 in order to confirm the reception of the wireless power 122. The 406 is monitored by the main body side control unit 101 (step S1703). At this time, by changing the load state of the load 105 by using the control signal 109 from the main body side control unit 101, whether or not the same echo back as the change appears in the output 406 of the banknote storage information demodulation unit 403. May be monitored from the main body side control unit 101. After confirming the wireless power from the bill storage 120, the main body side control unit 101 starts transmitting the control information for controlling the bill storage 120 to the bill storage 120, and the bill storage 120 receives the control information. Starts a predetermined control operation.

Through the above series of initial operations, the main body side control unit 101 has the effect of being able to confirm that the banknote storage 120 normally exists by confirming the output of the wireless power 122 from the banknote storage 120.

[Fifth Embodiment] FIG. 24 is an example of a block diagram of an automated teller machine according to a fifth embodiment of the present invention. In the first embodiment shown in FIG. 1, control information for controlling the inside of the bill storage 120 is transmitted from the main body 100 to the bill storage 120 between the bill storage side coil 117 and the main body side coil 106. The same applies to the present embodiment, but in the embodiment shown in FIG. 24, in addition to this, the bill storage from the bill storage 120 to the main body 100 between the main body side power transmission coil 104 and the bill storage side power receiving coil 112. It transmits banknote storage information such as sensor information in 120.

Further, in the embodiment shown in FIG. 24, the electric power received by the power receiving coil 112 on the bill storage side of the bill storage 120 is directly supplied to the power using unit 115 via the rectifying unit 113 and the DC-DC conversion unit 114. Instead, power is temporarily stored (charged) in the storage unit 1803, power is supplied from the storage unit 1803 to each block, power 131 is supplied to the buffer 116, and power is supplied to the power usage unit 115. As a result, the wireless power supply from the main body side power transmission coil 104 to the bill storage side power receiving coil 112 can be uniformly sent in a predetermined amount.

Therefore, when the load 1804 is connected to the electric power 1805 which is the output of the power receiving coil 112 on the bill storage side which is uniformly receiving power, and the load state is changed according to the control signal 1806 of the bill storage control unit 119, this load is obtained. The wireless power 121 fluctuates due to the change in the state. This fluctuation can be detected and demodulated by the bill storage information demodulation unit 1801 on the main body 100 side, and the detected and demodulated signal 1802 is output to the main body side control unit 101 and recognized.

The control signal 1806 is associated with banknote storage information such as sensor information, whereby the banknote storage information can be transmitted from the banknote storage 120 to the main body 100 side. The above operation is, so to speak, the same as the configuration in which the main body 100 and the bill storage 120 have the information transmission directions reversed in FIG. 4. That is, if the load 105 on the power receiving side is replaced with the load 1804 and the control information demodulation unit 118 is replaced with the bill storage information demodulation unit 1801, the same mechanism can be said.

According to the fifth embodiment shown in FIG. 24, the control information for controlling the inside of the bill storage 120 transmitted from the main body 100 to the bill storage 120 is between the bill storage side coil 117 and the main body side coil 106. , The bill storage information such as the sensor information in the bill storage 120 transmitted from the bill storage 120 to the main body 100 is transmitted between the main body side transmission coil 104 and the bill storage side power receiving coil 112, so that the control information is simultaneously controlled. It has the effect of making it possible to exchange banknote storage information with. Further, since the electric power is stored in the storage unit 1803, the wireless power 122 can be emitted from the bill storage 120 to the main body 100 even when the wireless power 121 is not supplied. That is, there is an effect that the control information for controlling the inside of the bill storage 120 can be transmitted from the main body 100 to the bill storage 120.

[Sixth Embodiment] FIG. 25 is an example of a block diagram of an automated teller machine according to a sixth embodiment of the present invention. In the fifth embodiment shown in FIG. 24, the banknote storage 120 has the storage unit 1803, but in the sixth embodiment shown in FIG. 25, the storage unit 1803 is eliminated and the storage unit 1803 is used. It is a power supply type that supplies power from the DC-DC converter 114 to the buffer 116 instead of supplying the charged power.

Therefore, it is possible to uniformly send a predetermined amount of wireless power supply from the main body side power transmission coil 104 to the bill storage side power receiving coil 112 by each drive block such as the above-mentioned [1] bill storage control unit 119. At the time of power supply to [3] sensor system power use unit 702 and at the time of power supply to [1]. However, even if the drive system power using unit 701 is in use, if the wireless power supply can be uniformly performed, the above [2] drive system power using unit 701 and [1] may be supplied with power, or [4]. ] It can also be realized when power is supplied to the drive system power use unit 701, the sensor system power use unit 702, and [1].

As described above, as in the sixth embodiment shown in FIG. 25, even when the storage unit 1803 is not provided, the wireless power is supplied from the main body side transmission coil 104 to the bill storage side power receiving coil 112. It is possible to transmit banknote storage information such as sensor information in the banknote storage 120 from the banknote storage 120 to the main body 100 during the period of uniform feeding in a fixed quantity, which is shown in FIG. 24. It has the same effect as the embodiment.

[Seventh Embodiment] FIG. 26 is an example of a block diagram of an automated teller machine according to a seventh embodiment of the present invention. From the first embodiment to the sixth embodiment, the clock 128 of the second carrier frequency, which is the input to the buffer 116 or the three-state buffer 603, is obtained from the banknote storage control unit 119. However, in the seventh embodiment shown in FIG. 26, the frequency dividing portion 2001 divides the wireless power 121 with respect to the first carrier frequency component included in the power 1805 received by the power receiving coil 112 on the bill storage side. Then, the clock 2002 of the second carrier frequency is used. The frequency dividing section 2001 divides the frequency by 1/2, and sets a frequency that is half of the first carrier frequency as the second carrier frequency.

FIG. 26 shows an example in which the present embodiment is applied to the sixth embodiment, but it is clear that the present embodiment is not limited to this and can be applied to other embodiments.

According to the seventh embodiment shown in FIG. 26, since it is not necessary for the bill storage control unit 119 to oscillate the second carrier frequency, not only the processing of the bill storage control unit 119 is reduced, but also the processing of the bill storage control unit 119 is reduced. It has the effect of reducing costs. Further, the first carrier frequency and the second carrier frequency are synchronized, but since the second carrier frequency is the division of the first carrier frequency, the second carrier frequency is the first. The frequency is lower than the carrier frequency. Therefore, there is an effect that there is no harmonic interference from the radio power 121 which is the first carrier frequency to the radio power 122 which is the second carrier frequency.

[Eighth Embodiment] FIG. 27 is an example of a block diagram of an automated teller machine according to an eighth embodiment of the present invention.

The difference from the sixth embodiment shown in FIG. 25 is that in the sixth embodiment, the power supply to the drive system power use unit 701 and the sensor system power use unit 702 is the power transmission coil 104 on the main body side. Although it was obtained from the wireless power 121 between the power receiving coils 112 on the bill storage side, in the eighth embodiment shown in FIG. 27, the power transmitting coil 2102 on the main body side is independently connected to the main body 100 for the drive system power usage unit 701. And the bill storage side power receiving coil 2107 is provided in the bill storage 120, and the wireless power 2106 is independently transmitted for the drive system power usage unit 701.

The main body side control unit 101 outputs a clock 2104 having a third carrier frequency for wireless power transmission to the power supply unit 2101. The power supply unit 2101 supplies the output power 2105 according to the output power control signal 2103 from the main body side control unit 101 to the main body side power transmission coil 2102. The main body side power transmission coil 2102 is connected to a capacitor so as to resonate at a third carrier frequency for wireless power transmission, thereby transmitting wireless power 2106 by a magnetic field. Although the power transmission coil 2102 on the main body side of FIG. 27 shows a series resonance configuration, it may have a parallel resonance configuration. Further, the main body side power transmission coil 2102 is not limited to the so-called coil in terms of its shape, material and the like, and may be any magnetic antenna capable of transmitting wireless power 2106 without modulation.

The power receiving coil 2107 on the bill storage side is connected to a capacitor so as to resonate at a third carrier frequency for wireless power transmission, thereby receiving wireless power 2106 by a magnetic field. Although the power receiving coil 2107 on the banknote storage side in FIG. 27 shows a series resonance configuration, it may have a parallel resonance configuration. Further, the bill storage side power receiving coil 2107 is not limited to the so-called coil in terms of its shape, material and the like, and may be a magnetic antenna capable of receiving wireless power 2106 without modulation. ..

The electric power 2109 received by the power receiving coil 2107 on the bill storage side is rectified by the rectifying unit 2108 to become the rectified power 2110, and power is supplied to the drive system power using unit 701. The bill storage control unit 119 receives power and controls the drive system power usage unit 701 by the control signal 705. The drive system power usage unit 701 is an actuator such as a solenoid or a servo motor. The drive system power usage unit 701 executes the operation required in the bill storage 120 by receiving the supply of the power 2110, and outputs the obtained operation confirmation signal 704 to the bill storage control unit 119.

According to the eighth embodiment shown in FIG. 27, between the main body side power transmission coil 104 and the bill storage side power receiving coil 112, the bill storage 120 to the main body 100, the bill storage such as sensor information in the bill storage 120, etc. In the case of transmitting information, in the sixth embodiment shown in FIG. 25, even when the wireless power cannot be uniformly supplied due to the power supply to the drive system power use unit 701, the drive system power use unit 701 Since the power is supplied to the power via another system, the wireless power is uniformly supplied from the main body side power transmission coil 104 to the bill storage side power receiving coil 112 regardless of the operating period of the drive system power usage unit 701. It is possible to transmit the bill storage information such as the sensor information in the bill storage 120 from the bill storage 120 to the main body 100 during the period of sending to the same as the fifth embodiment shown in FIG. 24. There is an effect of.

[Ninth Embodiment] FIG. 28 is an example of a block diagram of an automated teller machine according to a ninth embodiment of the present invention.

In the drive system power-using unit 701 of the eighth embodiment shown in FIG. 27, there are a plurality of actuators such as solenoids and servomotors, and ON / OFF and control of each operation are performed from the bill storage control unit 119. It was controlled by the control signal 705. In FIG. 28, the power supply unit 2101, the main body side power transmission coil 2102, the bill storage side power receiving coil 2107, and the rectifying unit 2108 of FIG. 27 are individually prepared for each of the plurality of actuators. FIG. 28 shows an example in which there are two systems of actuators, and the difference between the two systems is represented by the subscripts a and b of the reference numerals. The drive system power-using unit 701 is separated into drive system power-using units 2201a and 2201b of individual actuators according to a plurality of systems.

If the solenoid or DC motor has a constant rotation direction, it is possible to control the drive ON / OFF depending on whether or not power is supplied.

According to the ninth embodiment of FIG. 28, the inside of the bill storage 120 is controlled from the main body 100 transmitted between the bill storage side coil 117 and the main body side coil 106 using the wireless power 122 to the bill storage 120. ON / OFF control of the drive system power usage unit 2201a and the drive system power usage unit 2201b by controlling the wireless transmission of the power 2106a and the power 2106b from the main body 100 to the bill storage 120 independently without exchanging control information. Has the effect of being able to do.

[10th Embodiment] FIG. 29 is an example of a configuration diagram of an automated teller machine according to a tenth embodiment of the present invention. In the automated teller machine according to the tenth embodiment, the banknote storage 120 can be connected to a terminal 2301 other than the main body 100 and handled. The bill storage 120 is taken out from the main body 100, and the bills in the bill storage 120 are replenished or taken out at another place in a state of being connected to the terminal 2301. FIG. 30 shows a block diagram of a block of an automated teller machine corresponding to this, and FIG. 31 shows an explanation of the operation of the block of the terminal 2301 and the bill storage 120.

FIG. 30 is an example of a block diagram of an automated teller machine according to a tenth embodiment of the present invention. In FIG. 30, the difference from the fourth embodiment shown in FIG. 12 is that a memory 2401 on the main body side, which is connected to the main body side control unit 101 and can be read / written from the main body side control unit 101, is provided in the main body 100. In the bill storage 120, a memory 2402 on the bill storage side, which is connected to the bill storage control unit 119 and can be read and written from the bill storage control unit 119, is provided.

FIG. 31 is an example of a block diagram of a power transmission / reception system according to a tenth embodiment of the present invention. In FIG. 31, the terminal 2301 has basically the same configuration block as the main body 100, and is connected to the terminal side radio unit 102T and the terminal side control unit 2502, and is connected to the terminal side radio unit 102T and the terminal side control unit. It is connected to the memory 2501 on the terminal side that can be read and written from the 2502, and the control unit 2502 on the terminal side, and is connected to an external device, a mobile phone network, the Internet, a LAN (Local Area Network), a WAN (Wide Area Network), etc. It has a communication unit 2503 that communicates via a communication network regardless of whether it is wired or wireless. The memory 2501 may be detachably attached to the terminal 2301. FIG. 32 shows the contents stored in each memory.

FIG. 32 is an example of a diagram showing a data structure used in the power transmission / reception system according to the tenth embodiment of the present invention. The memory 2401 on the main body side contains main body identification information including information indicating that the main body is used, information such as the main body model name, version, serial number, etc., and the model name and version of the bill storage that can be stored in the main body 100. , Banknote storage identification information that can specify the serial number, etc., drive system information including control information of the actuator used in the drive system power use unit 701, and control of the sensor used in the sensor system power use unit 702. Sensor system information including information, operation information regarding the installation location of the automatic trading device, the number of banknotes deposited in the banknote storage 120, and the like are stored.

The memory 2501 on the terminal side contains terminal identification information including information indicating that the terminal is a terminal, information indicating available privileges, and a bill storage including the model name and version of the bill storage that can be controlled by the terminal 2301. The identification information and the above-mentioned operation information are stored.

In the memory 2402 on the bill storage side, the main body / terminal identification information that can identify the main body and the terminal and, in the case of the terminal, the authority thereof, the above-mentioned bill storage identification information, the drive system information, and the like, Sensor system information and operation information are stored.

The main body identification information, the terminal identification information, and the main body / terminal identification information are not normally rewritten except for special operation conditions such as software update. The drive system information, the sensor system information, and the operation information are rewritten by control from the main body side control unit 101 of the main body 100, training by the bill storage control unit 119 in the bill storage 120, sensor information, and the like. , It is always synchronized so that the same information is obtained between the main body 100 and the bill storage 120.

FIG. 33 is a diagram showing an initial operation flow of the power transmission / reception system according to the tenth embodiment of the present invention. FIG. 33 shows an operation flow of the initial operation of the automated teller machine according to the tenth embodiment shown in FIGS. 30 and 31.

First, in the initial initial state between the main body 100 (or the terminal 2301) and the bill storage 120, as in the initial operation flow of the automatic teller machine according to the fourth embodiment of the present invention shown in FIG. First, the main body side control unit 101 (or the terminal side control unit 2502) emits the wireless power 121 to confirm the existence of the bill storage 120 on the main body 100 (or terminal 2301) side (step S1701). The electric power at this time is the electric power in the state of the above [1], that is, the electric power for operating each drive block such as the bill storage control unit 119.

Then, the bill storage 120 receives the wireless power 121, and power is supplied from the DC-DC conversion unit 114 to the bill storage control unit 119 and the like for the initial operation of the drive block. As a result, the bill storage control unit 119 is activated, and under the control of the bill storage control unit 119, the 3-state buffer 603 is operated by a part of the power 131 of the received power, and the bill storage side coil 117 is used. The radio power 122 is emitted (step S1702).

Then, the main body side control unit 101 of the main body 100 (or the terminal side control unit 2502 of the terminal 2301) transmits the main body identification information (or terminal identification information) to the bill storage 120 (step S2701).

Then, the bill storage control unit 119 of the bill storage 120 recognizes whether the other party that has transmitted the information is the main body 100 or the terminal 2301. If it cannot be recognized, or if it is an inappropriate individual, it is determined that it is not a legitimate main body or terminal, and the transmission of wireless power 122 is stopped. In the case of the terminal 2301, the banknote storage control unit 119 further confirms the authority given to the terminal 2301. For example, it requires control by authority, such as having the authority to open the door of the banknote storage 120 and taking out banknotes, or having the authority to obtain operational information although it cannot take out banknotes. be. When these confirmations are completed, the bill storage control unit 119 transmits the confirmation completion information to the main body 100 (step S2702).

Next, the main body side control unit 101 of the main body 100 (or the terminal side control unit 2502 of the terminal 2301) requests the bill storage 120 to transmit the bill storage identification information (step S2703).

According to the request, the bill storage control unit 119 transmits the bill storage identification information to the main body 100 (or the terminal 2301) (step S2704). After that, the main body side control unit 101 of the main body 100 (or the terminal side control unit 2502 of the terminal 2301) confirms the transmitted bill storage identification information, and if there is no problem, starts controlling the bill storage 120.

After performing the initial processing in this way, the terminal 2301 obtains the operation information from the bill storage 120, writes it in the memory 2501, and in some cases, transmits the operation information to an external device or the like via the communication unit 2503. Further, when the terminal 2301 having a legitimate authority is used, the banknote storage control unit 119 controls the banknote storage 120 so that the door of the banknote storage 120 can be opened and the banknotes can be taken out.

As described above, according to the tenth embodiment, as shown in FIGS. 29, 30, 31, 32, and 33, the main body 100 or the terminal 2301 and the bill storage 120 are identified. Since the identification process using information is performed, there is an effect that information transmission with high security can be achieved. In addition, in FIGS. 30 and 31, elements specific to the embodiment are added based on the fourth embodiment shown in FIG. 12, but elements specific to the embodiment are added based on other examples. It is clear that it can be added.

The above is the automatic teller machine to which the transmitter, the power receiver, the power transmission / reception system, and the power transmission / reception method according to the first to tenth embodiments are applied. The present invention is not limited to the above-described embodiment, and includes various modifications.

The above-described embodiments have been described in detail in order to explain the present invention in an easy-to-understand manner, and are not necessarily limited to those having all the described configurations. It is possible to replace a part of the configuration of the embodiment with another configuration, and it is also possible to add the configuration of another embodiment to the configuration of the embodiment. It is also possible to delete a part of the configuration of the embodiment.

Further, each of the above configurations, functions, processing units and the like may be realized by hardware, for example, by designing a part or all of them by an integrated circuit or the like. Further, each of the above configurations, functions, and the like may be realized by software by the processor interpreting and executing a program that realizes each function. Information such as programs, tables, and files that realize each function can be placed in a memory, a recording device such as a hard disk, or a recording medium such as an IC card, SD card, or DVD.

It should be noted that the control lines and information lines according to the above-described embodiment show what is considered necessary for explanation, and do not necessarily show all the control lines and information lines in the product. In practice, it can be considered that almost all configurations are interconnected. The present invention has been described above with a focus on embodiments.

It can be applied to automated teller machines such as ATMs and ticket vending machines, and general wireless power supply systems.

100 ... Main body, 101 ... Main body side control unit, 102 ... Main body side radio unit, 103 ... Power supply unit, 104 ... Main body side transmission coil, 105 ... Load, 106 ... Main body Side coil, 112 ... Bill storage side power receiving coil, 113 ... Rectifier unit, 114 ... DC-DC conversion unit, 115 ... Power usage unit, 116 ... Buffer, 117 ... Bill Storage side coil, 118 ... Control information demodulator, 119 ... Bill storage control unit, 120 ... Bill storage, 401 ... Buffer, 402 ... Switching unit, 403 ... Bill Storage information demodulation unit, 412 ... load, 413 ... switching unit, 601 ... 3 state buffer, 603 ... 3 state buffer, 701 ... drive system power usage unit, 702 ... Sensor system power usage unit, 1002 ... diode, 1003 ... inductor, 1201 ... constant load unit, 1801 ... bill storage information demodulation unit, 1803 ... storage unit, 1804 ... load , 2001 ... frequency dividing section, 2101 ... power supply section, 2102 ... main body side transmission coil, 2107 ... bill storage side power receiving coil, 2108 ... rectifying section, 2201 ... drive system Power usage unit, 2301 ... Terminal, 2401 ... Main unit side memory, 2402 ... Bill storage side memory, 2501 ... Terminal side memory, 2502 ... Terminal side control unit, 2503・ ・ ・ Communication department.

Claims (19)

Control unit and
A first non-contact power transmission unit equipped with a first magnetic antenna that transmits the first unmodulated power in a non-contact manner.
A second magnetic antenna that receives a second unmodulated power transmitted non-contactly using a part of the first unmodulated power, and a first that consumes the second unmodulated power. With a non-contact power receiving part,
And a demodulator,
The control unit changes the load state of the first received load according to the control content for controlling the device of the transmission source of the second unmodulated power, thereby changing the second unmodulated power. To fluctuate,
The second magnetic antenna transmits a third unmodulated power in a non-contact manner.
The demodulation unit detects and demodulates the fluctuation of the third unmodulated power.
A transmitter characterized by that. Control unit and
A first non-contact power transmission unit equipped with a first magnetic antenna that transmits the first unmodulated power in a non-contact manner.
A second magnetic antenna that receives a second unmodulated power transmitted non-contactly using a part of the first unmodulated power, and a first that consumes the second unmodulated power. With a non-contact power receiving part,
Equipped with a demodulation unit and a switching unit,
The control unit changes the load state of the first received load according to the control content for controlling the device of the transmission source of the second unmodulated power, thereby changing the second unmodulated power. To fluctuate,
The second magnetic antenna transmits a third unmodulated power in a non-contact manner.
The demodulation unit detects and demodulates the fluctuation of the third unmodulated power, and demodulates the third unmodulated power.
The switching unit switches between the transmission of the third unmodulated electric power and the reception of the second unmodulated electric power of the second magnetic antenna according to the control from the control unit.
A transmitter characterized by that. Control unit and
A first non-contact power transmission unit equipped with a first magnetic antenna that transmits the first unmodulated power in a non-contact manner.
A second magnetic antenna that receives a second unmodulated power transmitted non-contactly using a part of the first unmodulated power, and a first that consumes the second unmodulated power. With a non-contact power receiving part,
And a demodulator,
The control unit changes the load state of the first received load according to the control content for controlling the device of the transmission source of the second unmodulated power, thereby changing the second unmodulated power. To fluctuate,
The second magnetic antenna transmits a third unmodulated power in a non-contact manner.
The demodulation unit detects and demodulates the fluctuation of the third unmodulated power, and demodulates the third unmodulated power.
It has a 3-state buffer that transmits the third unmodulated power from the second magnetic antenna.
The control unit switches the three-state buffer to high impedance when the second magnetic antenna receives the second unmodulated power.
A transmitter characterized by that. The transmitter according to any one of claims 1 to 3.
In addition, it comprises a third magnetic antenna that transmits a fourth unmodulated power in a non-contact manner.
A transmitter characterized by that. The transmitter according to any one of claims 1 to 4.
The control unit adjusts the voltage of the first unmodulated electric power to a voltage required by the power receiver.
A transmitter characterized by that. A first non-contact power receiving unit equipped with a first magnetic antenna for receiving the first unmodulated power transmitted in a non-contact manner, and a first non-contact power receiving unit.
The first power-using unit that uses the first unmodulated power, and
A non-contact power transmission unit provided with a second magnetic antenna that transmits a part of the power of the first unmodulated power as a second unmodulated power in a non-contact manner.
Has a demodulator and
The demodulation unit detects and demodulates the fluctuation of the second unmodulated power, and demodulates the second unmodulated power.
The first power usage unit includes a large power usage unit having a large power usage fluctuation and a constant power usage unit having a smaller power usage fluctuation than the large power usage unit.
A diode is provided between the constant power use unit and the high power use unit in a direction in which no current flows from the constant power use unit to the high power use unit.
A power receiver characterized by that. A first non-contact power receiving unit equipped with a first magnetic antenna for receiving the first unmodulated power transmitted in a non-contact manner, and a first non-contact power receiving unit.
The first power-using unit that uses the first unmodulated power, and
A non-contact power transmission unit provided with a second magnetic antenna that transmits a part of the power of the first unmodulated power as a second unmodulated power in a non-contact manner.
Has a demodulator and
The demodulation unit detects and demodulates the fluctuation of the second unmodulated power, and demodulates the second unmodulated power.
The first power usage unit includes a large power usage unit having a large power usage fluctuation and a constant power usage unit having a smaller power usage fluctuation than the large power usage unit.
In parallel with the high power consumption unit, it has a constant load unit that adjusts to the maximum power consumption of the high power consumption unit.
A power receiver characterized by that. It is an automated teller machine equipped with a main body and a banknote storage for storing the transported banknotes.
The main body has a main body side control unit and a first non-contact power transmission unit provided with a first magnetic antenna for transmitting first unmodulated electric power from the main body to the bill storage in a non-contact manner. death,
The bill storage has a first non-contact power receiving unit provided with a first power receiving magnetic antenna for receiving the first unmodulated electric power transmitted from the main body to the bill storage in a non-contact manner. The first power-using unit that uses the first unmodulated power and a part of the power of the first unmodulated power are used as the second unmodulated power, and the power is not transferred from the bill storage to the main body. It has a second non-contact power transmission unit with a magnetic antenna on the bill storage side that transmits power by contact.
The body further includes a body-side magnetic antenna for receiving power of the second unmodulated, first power receiving load that consumes power of the second unmodulated, a second non-contact power receiving unit comprising , With a bill storage information demodulation unit ,
The banknote storage further includes a first demodulator that detects and demodulates the second unmodulated power fluctuations.
The main body side control unit changes the load state of the first power receiving load according to the control content for controlling the bill storage from the main body to change the second unmodulated power.
The first demodulation unit detects and demodulates the fluctuation of the second unmodulated power to specify the control information corresponding to the control content .
The main body side magnetic antenna transmits a third unmodulated electric power in a non-contact manner.
The bill storage information demodulation unit detects and demodulates the fluctuation of the third unmodulated power.
An automated teller machine that features. It is an automated teller machine equipped with a main body and a banknote storage for storing the transported banknotes.
The main body has a main body side control unit and a first non-contact power transmission unit provided with a first magnetic antenna for transmitting first unmodulated electric power from the main body to the bill storage in a non-contact manner. death,
The bill storage has a first non-contact power receiving unit provided with a first power receiving magnetic antenna for receiving the first unmodulated electric power transmitted from the main body to the bill storage in a non-contact manner. The first power-using unit that uses the first unmodulated power and a part of the power of the first unmodulated power are used as the second unmodulated power, and the power is not transferred from the bill storage to the main body. It has a second non-contact power transmission unit with a magnetic antenna on the bill storage side that transmits power by contact.
The main body further includes a second non-contact power receiving unit including a main body side magnetic antenna that receives the second unmodulated power and a first power receiving load that consumes the second unmodulated power. , Has a bill storage information demodulation unit and a switching unit,
The banknote storage further includes a first demodulator that detects and demodulates the second unmodulated power fluctuations.
The main body side control unit changes the load state of the first power receiving load according to the control content for controlling the bill storage from the main body to change the second unmodulated power.
The first demodulation unit detects and demodulates the fluctuation of the second unmodulated power to specify the control information corresponding to the control content.
The main body side magnetic antenna transmits a third unmodulated electric power in a non-contact manner.
The bill storage information demodulation unit detects and demodulates the fluctuation of the third unmodulated power, and demodulates the third unmodulated power.
The switching unit switches between the transmission of the third unmodulated electric power and the reception of the second unmodulated electric power of the main body side magnetic antenna according to the control from the main body side control unit.
An automated teller machine that features. It is an automated teller machine equipped with a main body and a banknote storage for storing the transported banknotes.
The main body has a main body side control unit and a first non-contact power transmission unit provided with a first magnetic antenna for transmitting first unmodulated electric power from the main body to the bill storage in a non-contact manner. death,
The bill storage has a first non-contact power receiving unit provided with a first power receiving magnetic antenna for receiving the first unmodulated electric power transmitted from the main body to the bill storage in a non-contact manner. The first power-using unit that uses the first unmodulated power and a part of the power of the first unmodulated power are used as the second unmodulated power, and the power is not transferred from the bill storage to the main body. It has a second non-contact power transmission unit with a magnetic antenna on the bill storage side that transmits power by contact.
The main body further includes a second non-contact power receiving unit including a main body side magnetic antenna that receives the second unmodulated power and a first power receiving load that consumes the second unmodulated power. , With a bill storage information demodulation unit,
The banknote storage further includes a first demodulator that detects and demodulates the second unmodulated power fluctuations.
The main body side control unit changes the load state of the first power receiving load according to the control content for controlling the bill storage from the main body to change the second unmodulated power.
The first demodulation unit detects and demodulates the fluctuation of the second unmodulated power to specify the control information corresponding to the control content.
The main body side magnetic antenna transmits a third unmodulated electric power in a non-contact manner.
The bill storage information demodulation unit detects and demodulates the fluctuation of the third unmodulated power, and demodulates the third unmodulated power.
It has a 3-state buffer that transmits the third unmodulated power from the main body side magnetic antenna.
The main body-side control unit switches the three-state buffer to high impedance when the main body-side magnetic antenna receives the second unmodulated power.
An automated teller machine that features. The automated teller machine according to any one of claims 8 to 10.
Further, the main body comprises a third magnetic antenna that transmits a fourth unmodulated power in a non-contact manner.
An automated teller machine that features. The automated teller machine according to any one of claims 8 to 11.
The main body side control unit adjusts the voltage of the first unmodulated electric power to be the voltage required for the bill storage.
An automated teller machine that features. The automated teller machine according to any one of claims 8 to 12.
The bill storage further includes a control unit and a frequency dividing unit.
The control unit obtains the frequency of the second unmodulated power by dividing the frequency of the received first unmodulated power by the frequency dividing unit.
An automated teller machine that features. The automated teller machine according to any one of claims 8 to 12.
The bill storage is further divided into a control unit and
A third equipped with a third magnetic antenna that receives a third unmodulated electric power transmitted from the main body in a non-contact manner, and a second power-using unit that consumes the third unmodulated electric power. Non-contact power receiving part and
Equipped with
The control unit changes the load state of the second power-using unit in response to predetermined transmission information to change the third unmodulated power.
An automated teller machine that features. The automated teller machine according to any one of claims 8 to 12.
The bill storage is further divided into a control unit and
A third power-using unit, which consumes the first unmodulated power, is provided.
The control unit changes the load state of the third power-using unit in response to predetermined transmission information to change the first unmodulated power.
An automated teller machine that features. The automated teller machine according to any one of claims 8 to 12.
The banknote storage further comprises a third non-contact power receiving unit provided with a fourth magnetic antenna for receiving a fourth unmodulated power transmitted in a non-contact manner.
A fourth power-using unit that uses the fourth unmodulated power,
An automated teller machine characterized by being equipped with. The automated teller machine according to any one of claims 8 to 12.
The banknote storage further comprises a third non-contact power receiving unit provided with a fourth magnetic antenna for receiving a fourth unmodulated power transmitted in a non-contact manner.
A fourth power-using unit that uses the fourth unmodulated power is provided.
The main body side control unit controls the operation of the fourth power-using unit by controlling the electric energy of the fourth unmodulated electric power.
An automated teller machine that features. The automated teller machine according to any one of claims 8 to 12.
The first power usage unit includes a large power usage unit having a large power usage fluctuation and a constant power usage unit having a smaller power usage fluctuation than the large power usage unit.
A diode is provided between the constant power use unit and the high power use unit in a direction in which no current flows from the constant power use unit to the high power use unit.
An automated teller machine that features. The automated teller machine according to any one of claims 8 to 12.
The first power usage unit includes a large power usage unit having a large power usage fluctuation and a constant power usage unit having a smaller power usage fluctuation than the large power usage unit.
In parallel with the high power consumption unit, it has a constant load unit that adjusts to the maximum power consumption of the high power consumption unit.
An automated teller machine that features.

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