JP2006217708A - Cellular phone charging system, cellular phone, and method of charging electricity - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cellular phone charging system which can effectively utilize wave resource emitted from a portable telephone easily, a cellular phone, and a charging method. <P>SOLUTION: This system is equipped with a cellular phone 1, a Schottky diode 2 which receives electromagnetic waves emitted from the cellular phone 1 and converts them into currents and also rectify the currents, and a first charging means (for example, nickel hydrogen battery 3) which is electrically connected with a Schottky diode 2 and accumulates electricity, based on the current obtained by the Schottky diode 2. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a mobile phone power storage system, a mobile phone, and a power storage method for storing power using electromagnetic waves emitted from a mobile phone.

  Mobile phones are widely used as small and lightweight mobile communication terminals. In a mobile phone, a circuit board, a transmitter / receiver, a lithium ion battery, and the like necessary for wireless communication are accommodated in an outer case mainly formed of non-metal. The lithium ion battery is used because it has a high volumetric energy density and high weight energy density, and is extremely effective for driving a mobile phone for a long time and reducing the size and weight.

  In general, when a mobile phone is turned on, terminal information such as a phone number and a position is transmitted to the nearest radio base station using weak electromagnetic waves, and a higher-level station always carries it via the radio base station. The telephone position is confirmed (so-called intermittent wireless communication). When there is a communication line connection request from a mobile phone in another network, the upper station calls the mobile phone via the wireless base station and establishes a communication connection. A call with a telephone becomes possible.

  Here, when making a call with another mobile phone, the mobile phone is held in the vicinity of the temporal region by the user's hand, and a microphone and a speaker (a part of the above-described transmission / reception unit described above) disposed on the outer case surface. ) To make a call. At this time, electromagnetic waves are sequentially emitted from the mobile phone toward the radio base station.

  By the way, in recent years, attempts have been made to effectively use electromagnetic waves radiated from a mobile phone toward a radio base station. For example, the invention described in Patent Document 1 is a mobile phone battery automatic charger having a receiving antenna, a rectifier circuit, and a battery in a charging circuit. According to this mobile phone battery automatic charger, Since the battery can be charged using the radiated electromagnetic waves, the use of the mobile phone can be continued for a long time even in a place where there is no facility for commercial power supply for charging the battery. ing.

JP-A-11-234914 (paragraph numbers [0015], [0028])

  However, in the invention described in Patent Document 1 described above, radio wave resources cannot be easily and effectively used.

  That is, the mobile phone battery automatic charging device according to Patent Document 1 includes the receiving antenna, the rectifier circuit, and the battery in the charging circuit (mostly a lithium ion battery that is most suitable for a mobile phone) as described above. Since the circuit is composed of a full-wave rectifier circuit composed of four rectifier diodes (see FIG. 2 of Patent Document 1), a plurality of elements / wirings are required to supply current to the battery in the charging circuit. It cannot be said that radio resources are simply used effectively. As another embodiment of the rectifier circuit, a non-inverted half-wave rectifier circuit using an OP amplifier is also conceivable. However, as in Patent Document 1, it cannot be said that radio wave resources are simply and effectively used.

  The present invention has been made in view of these points, and an object thereof is to provide a mobile phone power storage system, a mobile phone, and a power storage method capable of easily and effectively using radio wave resources emitted from a mobile phone. There is to do.

  In order to solve the above problems, the present invention provides the following.

  (1) A cellular phone, a Schottky diode that receives an electromagnetic wave emitted from the cellular phone and converts the electromagnetic wave into a current and rectifies the current; and the Schottky diode electrically connected to the Schottky diode And a first power storage means for storing power based on the current obtained by the mobile phone.

  According to the present invention, a mobile phone power storage system receives a mobile phone and an electromagnetic wave (for example, an electromagnetic wave having a frequency of 1.5 GHz) emitted from the mobile phone, converts the current into a current, and rectifies the current. And the first power storage means for storing power based on the current obtained by the Schottky diode, the weak current generated in the Schottky diode is supplied to the first power storage means, In the power storage means, appropriate power storage is performed.

  Therefore, unlike the mobile phone battery automatic charging device described in Patent Document 1 described above, the radio wave resources emitted from the mobile phone can be simply and effectively used without requiring a rectifier circuit or a receiving antenna consisting of four diodes. be able to.

  As a method of using electromagnetic waves using a Schottky diode, there is a self-light emitting antenna attached as an accessory to a strap of a mobile phone or the like. This self-luminous antenna is composed of an antenna for transmitting and receiving electromagnetic waves, and a light emitting unit attached to the tip of the antenna. In the light emitting portion, elements such as a metal coil, a Schottky diode, a light emitting diode, and a capacitor are incorporated. However, such a self-light-emitting antenna is widely known as a usage mode as an accessory for a mobile phone, and is not even noticed in a usage mode for converting electromagnetic waves into electrical energy. The reason for this is that even if an attempt is made to store electricity using a self-luminous antenna, it is difficult to charge the battery (lithium ion battery) of the mobile phone because the current generated by the Schottky diode is weak. The present invention can solve such a problem by providing a first power storage unit that stores power based on a weak current obtained by a Schottky diode as a component of a mobile phone power storage system.

  Here, specific examples of the “first power storage means” include batteries such as a nickel cadmium battery, a nickel metal hydride battery, and a lithium ion battery, which have a small nominal voltage and minimum capacity. It is not intended to be limited to crab. Any device can be used as long as it can store electricity based on the weak current obtained by the Schottky diode.

  (2) The mobile phone storage system according to (1), wherein the mobile phone power storage system includes a plurality of the first power storage units, and the plurality of first power storage units are connected in parallel to each other. Power storage system.

  According to the present invention, the mobile phone power storage system described above is provided with a plurality of first power storage means, and the plurality of first power storage means are connected in parallel to each other. Can be increased.

  Accordingly, a large amount of electricity can be stored at one time, and radio wave resources emitted from the mobile phone can be used more effectively. Moreover, it can contribute to the lifetime extension of the 1st electrical storage means.

  (3) The mobile phone is provided with a second power storage means for storing power for the mobile phone to perform a call function or a communication function, and the second power storage means is the first power storage means. The mobile phone power storage system according to (1) or (2), wherein the mobile phone power storage system is electrically connectable to the first power storage means and receives power supply from the first power storage means.

  The mobile phone described above is provided with second power storage means (for example, a lithium ion battery having a nominal voltage of 3.8 V and a minimum capacity of 650 mAh) for storing power for the mobile phone to perform a call function or a communication function. Since the second power storage means can be electrically connected to the first power storage means described above and is supplied with power from the first power storage means, it is referred to as a Schottky diode → first power storage means. The power stored in the flow can be supplied in the flow of the first power storage means → the second power storage means.

  Therefore, the radio wave resources emitted from the mobile phone can be easily and effectively used, and the mobile phone can be used for a long time even in a place where there is no commercial power supply facility for charging the battery (second power storage means). Can continue over to. In addition, according to the present invention, since charging can be performed using radio wave resources emitted from a mobile phone, it is generally possible to charge without using an adapter required when charging a mobile phone. As a result, convenience and versatility can be improved, such as charging using radio wave resources emitted from mobile phones of other models (models with different adapter shapes).

  (4) The mobile phone power storage system according to any one of (1) to (3), wherein the Schottky diode and the first power storage unit are provided in the mobile phone.

  Since the Schottky diode and the first power storage unit described above are provided in the mobile phone, even when only the mobile phone is carried, electromagnetic waves are radiated from the mobile phone toward the radio base station. Sometimes, the battery (second power storage means) can be charged through the first power storage means, and as a result, radio wave resources emitted from the mobile phone can be easily and effectively used.

  (5) The mobile phone power storage system according to (4), wherein the Schottky diode is provided in contact with an antenna portion of the mobile phone.

  According to the present invention, since the Schottky diode described above is provided in contact with the antenna portion of the mobile phone, the electromagnetic wave can be converted into electric energy at a portion where the electromagnetic wave is radiated most strongly from the mobile phone. As a result, the radio wave resources emitted from the mobile phone can be effectively used simply and efficiently.

  Here, the Schottky diode can be provided in contact with the antenna portion on the front side of the mobile phone. According to this configuration, it is possible to reduce electromagnetic waves that are harmful to the human body.

  That is, in recent years, there are concerns about the adverse effects of electromagnetic waves that pass through the user's head on the human body (particularly the brain). For example, the energy of electromagnetic waves emitted from a mobile phone has a risk of causing damage to a magnetic organ that controls endocrine by causing a heat concentration point at an abnormally high temperature to appear in the center of the brain. As described above, the electromagnetic wave emitted from the mobile phone may cause a specific health hazard. As described above, the Schottky diode is provided in contact with the antenna portion on the front side of the mobile phone (Schottky). Electromagnetic waves that are harmful to the human body (especially the brain), because extra electromagnetic waves are absorbed (converted into electrical energy) by Schottky diodes (by interposing a diode between the antenna part and the temporal region of the mobile phone). It is possible to reduce electromagnetic waves that pass through.

  Here, the Schottky diode is provided in contact with the antenna portion on the front side of the mobile phone. However, the present invention is not limited to this, and the back side of the mobile phone can be used if electromagnetic waves harmful to the human body can be reduced. It is good also as providing in contact with the antenna part. Here, the Schottky diode is provided on the front side or the back side of the mobile phone, in particular, the electromagnetic wave passing through the brain is reduced. For example, by providing it near the heart, the Schottky diode passes through the heart (or pacemaker). It is possible to reduce electromagnetic waves (interfering electromagnetic waves).

  (6) The mobile phone according to any one of (1) to (5), wherein the first power storage means is a nickel metal hydride battery capable of storing power based on a weak current obtained by the Schottky diode. Power storage system.

  According to the present invention, the first power storage means described above is a nickel metal hydride battery that can store power based on the weak current obtained by the Schottky diode. Thus, radio wave resources emitted from the mobile phone can be easily and effectively used.

  (7) The mobile phone power storage system according to any one of (1) to (6), wherein the first power storage means is a nickel metal hydride battery having a nominal voltage of 1.2 V and a minimum capacity of 100 mAh.

  Since the first power storage means described above is a nickel metal hydride battery having a nominal voltage of 1.2 V and a minimum capacity of 100 mAh, optimal power storage is performed in the nickel metal hydride battery having such a rating, and the power can be emitted from the mobile phone. It is possible to easily and effectively use radio wave resources.

  (8) The mobile phone power storage system according to any one of (1) to (7), wherein the total length of the Schottky diode is approximately 50 mm.

  According to the present invention, since the total length of the Schottky diode described above is approximately 50 mm, it is an electromagnetic wave used when the mobile phone performs wireless communication, and is about 1.5 GHz which is currently mainstream. Electromagnetic waves can be efficiently absorbed (converted into electrical energy), and as a result, radio wave resources emitted from mobile phones can be simply and effectively used.

  (9) A mobile phone comprising a Schottky diode and a first power storage means used in the mobile phone power storage system according to any one of (1) to (8).

  According to the present invention, since the mobile phone is provided with the Schottky diode and the first power storage means used in the above-described mobile phone power storage system, the mobile phone can easily and effectively use radio wave resources emitted from the mobile phone. Can be provided.

  (10) A power storage method using the mobile phone power storage system according to any one of (1) to (9).

  According to the present invention, since the mobile phone power storage system described above is used for the power storage method, it is possible to provide a power storage method that can easily and effectively use radio wave resources emitted from the mobile phone.

  As described above, the present invention uses the Schottky diode and the first power storage means to perform appropriate power storage based on a weak current, and thus easily and effectively uses radio wave resources emitted from a mobile phone. be able to. Further, by providing the Schottky diode in contact with the front side of the antenna portion of the mobile phone, electromagnetic waves harmful to the human body (particularly, electromagnetic waves passing through the brain) can be reduced.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[Cellular power storage system]
FIG. 1 is a system schematic diagram of a mobile phone power storage system according to an embodiment of the present invention.

  In FIG. 1, the mobile phone power storage system according to the embodiment of the present invention includes a mobile phone 1, a Schottky diode 2, and a nickel metal hydride battery 3 as an example of a first power storage means.

  The mobile phone 1 includes an antenna 11 that receives an electric field in free space, and terminal information such as a telephone number and a position is transmitted from the antenna 11 to a nearby radio base station (not shown) as needed using weak electromagnetic waves. So-called intermittent wireless communication is performed. When there is a request for connection of a communication line with the mobile phone 1 from a mobile phone in another network, a higher-level station (not shown) calls the mobile phone 1 via the radio base station. In response to this, an electromagnetic wave of 1.5 GHz or 800 MHz, for example, is transmitted from the mobile phone 1 via the antenna 11 to establish a communication connection.

  A Schottky diode (also called a Schottky barrier diode) 2 is a kind of a detection diode, and has a structure in which a metal and a semiconductor are brought into contact with each other. The contact surface has a rectifying action. When this Schottky diode 2 is used, it is possible to operate at high speed and high frequency, and to improve the reverse recovery (recovery) characteristics.

  For example, the nickel metal hydride battery 3 is wound in a spiral shape with a positive electrode plate and a negative electrode plate separated by a separator, and is housed in a metal case. And when a hydrogen ion moves to the positive electrode plate side, an electric current can be taken out. On the other hand, when current is supplied, hydrogen ions move to the negative electrode plate side, and electricity is stored. As described above, the nickel metal hydride battery 3 performs power storage by using a chemical reaction that occurs between the hydrogen storage alloy and the alkaline electrolyte.

  Next, the operation of the system outline diagram shown in FIG. 1 will be described. First, when there is a request for connection of a communication line with a mobile phone 1 from a mobile phone in another network, as described above, the mobile phone 1 transmits an electromagnetic wave such as 1.5 GHz or 800 MHz through the antenna 11. To send. Note that the electromagnetic waves are transmitted as appropriate during a call.

  Next, the electromagnetic wave is caught by a series circuit including the Schottky diode 2 and the nickel metal hydride battery 3. More specifically, by appropriately adjusting the overall length of the Schottky diode 2, the electromagnetic wave emitted from the mobile phone 1 in the Schottky diode 2 is converted into a current, and the current is rectified. For example, if the electromagnetic wave emitted from the mobile phone 1 is 1.5 GHz, the electromagnetic wave can be appropriately (efficiently) caught by setting the total length of the Schottky diode to approximately 50 mm.

  Here, although the wiring connecting the Schottky diode 2 and the nickel metal hydride battery 3 is ignored, the circuit length of the entire series circuit composed of the Schottky diode 2 and the nickel metal hydride battery 3 is approximately 50 mm in consideration of this. You may do it.

  Finally, the weak current rectified in the Schottky diode 2 is stored in the nickel metal hydride battery 3. At this time, since the current generated in the Schottky diode 2 is weak, it is preferable that the nominal voltage and the minimum capacity be as small as possible. For example, a nickel metal hydride battery having a nominal voltage of 1.2 V and a minimum capacity of 100 mAh can be employed. Thereby, it is possible to appropriately store electricity based on the weak current rectified by the Schottky diode 2.

  Thus, according to the mobile phone power storage system according to the embodiment of the present invention, radio wave resources emitted from the mobile phone can be easily and effectively used.

[Modification]
FIG. 2 is a system schematic diagram of a mobile phone power storage system according to another embodiment of the present invention. The same electrical elements as those in FIG. 1 are denoted by the same reference numerals.

  In FIG. 2, in a mobile phone power storage system according to another embodiment of the present invention, three nickel metal hydride batteries 3a, 3b, 3c are connected in parallel to each other. By doing so, the total capacity of the nickel metal hydride battery can be increased, and as a result, radio wave resources emitted from the mobile phone can be used more effectively. In addition, it can contribute to extending the life of the nickel metal hydride battery.

  FIG. 3 is an explanatory diagram showing a state in which power is supplied to the lithium ion battery 12 provided in the mobile phone 1. The same electrical elements as those in FIG. 1 are denoted by the same reference numerals.

  In FIG. 3A, the nickel metal hydride battery 3 is charged based on the current I obtained by the Schottky diode 2. When the power storage is completed, the power stored in the nickel metal hydride battery 3 is supplied via the power line or the like to the lithium ion battery 12 that stores the power for the mobile phone 1 to perform a call function or a communication function. (FIG. 3B). By doing in this way, use of the mobile phone 1 can be continued for a long time even in a place where there is no commercial power supply facility for charging the lithium ion battery 12.

  FIG. 4 is a system schematic diagram of a mobile phone power storage system according to another embodiment of the present invention. The same electrical elements as those in FIG. 1 are denoted by the same reference numerals.

  In FIG. 4, the Schottky diode 2 and the nickel metal hydride battery 3 are built in the mobile phone 1. In this way, even when only the mobile phone 1 is carried around, when electromagnetic waves are radiated from the mobile phone 1 toward the radio base station, the lithium is transmitted through the Schottky diode 2 and the nickel metal hydride battery 3. The ion battery 12 can be charged (see FIG. 3), and as a result, radio wave resources emitted from the mobile phone can be easily and effectively used.

  FIG. 5 is a system schematic diagram of a mobile phone power storage system according to another embodiment of the present invention. The same electrical elements as those in FIG. 1 are denoted by the same reference numerals.

  In FIG. 5, the Schottky diode 2 is provided in contact with the antenna 11 of the mobile phone 1. Moreover, the Schottky diode 2 is provided near the boundary between the antenna 11 and the housing. Thereby, electromagnetic waves from the mobile phone 1 can be efficiently converted into electric energy, and as a result, radio wave resources emitted from the mobile phone 1 can be effectively used simply and efficiently.

  In addition, according to the experimental result mentioned later, about 1 cm or 2 cm upper vicinity (position of -1 or -2 in FIG. 7) from the boundary of the antenna 11 and a housing | casing is preferable. Thereby, radio wave resources can be most effectively used.

  FIG. 6 is an explanatory diagram for explaining a state when the Schottky diode 2 is provided on the front side of the mobile phone 1 in the mobile phone power storage system according to another embodiment of the present invention shown in FIG.

  In FIG. 6, the Schottky diode 2 is provided on the front side of the mobile phone 1, that is, on the side where the microphone and the speaker are arranged on the surface of the outer case (housing) of the mobile phone 1. By doing so, excess electromagnetic waves are absorbed (converted into electric energy) by the Schottky diode 2, and electromagnetic waves harmful to the human body (particularly electromagnetic waves passing through the brain) can be reduced.

FIG. 7 is a system schematic diagram of the mobile phone power storage system according to the embodiment of the present invention.
Basically, it is the same as the mobile phone power storage system shown in FIG. 1, but here the Schottky diode 2 is brought into contact with the antenna 11 (see FIG. 7A).

  As Schottky diode 2, Schottky diode “1SS106” manufactured by Hitachi, Ltd., Schottky diode for small signal “1SS86” manufactured by Renesas Technology Corp., and manufactured by Renesas Technology Corp. Three types of switching diodes “1S2076A” were used. Further, as the nickel metal hydride battery 3, a nickel metal hydride battery (cylindrical, GP model: GP10AAAHR, unit cell standard: 1/3 AAA, nominal voltage: 1.2 V, minimum capacity: 100 mAh, representative capacity: manufactured by Kanagawa Co., Ltd. 110 mAh, diameter: 10.4 mm, height: 15.6 mm) and Ni-MH battery (cylindrical, GP model: GP16AAAM, unit cell standard: 1/3 AAA, nominal voltage: 1.2 V, minimum capacity: 160 mAh, representative capacity: 168 mAh, diameter: 10.2 mm, height: 14.6 mm) were used.

On the other hand, as a position where the Schottky diode 2 is brought into contact with the antenna 11, the boundary between the antenna 11 and the housing is set to 0, and from there, the scale is -1, -2 every 1 cm in the outward direction (upward in FIG. 7). (See FIG. 7A). Similarly, the scale was swung to 1 and 2 for every 1 cm from the position 0 to the inward direction (downward in FIG. 7) of the mobile phone 1 (see FIG. 7A). Further, the total length of the Schottky diode 2 was l, the cathode side tip was A, the cathode side base end was B ₁ , the anode side base end was B ₂ , and the anode side tip was C.

  Hereinafter, the results of experiments conducted in such a mobile phone power storage system will be described.

8 and 9 are bar graphs when statistical analysis is performed in the mobile phone power storage system shown in FIG. More specifically, FIG. 8 shows three types of Schottky diode 2 (“1SS106”, “1SS86”, “1S2076A”) and three measurement sites (AB ₁ , AC, B) of Schottky diode 2. ₁ B _2), three full-length l (60 mm Schottky diodes 2, 50 mm, 40 mm), paying attention to two of the three positions of the antenna 11 (-2, -1, 0, 1, 2) It is a bar graph when statistical analysis is performed. The vertical axis indicates the electromotive force [V] obtained by the Schottky diode 2. On the other hand, FIG. 9 is a bar graph when statistical analysis is performed on three types of Schottky diodes 2 (“1SS106”, “1SS86”, “1S2076A”).

In FIG. 8A, the measurement site of the Schottky diode 2 is AB ₁ , AC, B ₁ B _{2 in} each of the three types of Schottky diodes 2 (“1SS106”, “1SS86”, “1S2076A”). The electromotive force when changed is shown, and according to this figure, it is understood that the condition that the type of the Schottky diode 2 is “1SS106” and the measurement site of the Schottky diode 2 is AC is optimal. In FIG. 8B, the total length l of the Schottky diode 2 is changed to 60 mm, 50 mm, and 40 mm in each of the three types of Schottky diodes 2 (“1SS106”, “1SS86”, and “1S2076A”). In this figure, it is understood that the condition that the type of the Schottky diode 2 is “1SS106” and the total length 1 of the Schottky diode 2 is 50 mm is optimal. In FIG. 8C, the types of the Schottky diodes 2 are “1SS106”, “1SS86”, “1S2076A” at each of the three positions (−2, −1, 0, 1, 2) of the antenna 11. The electromotive force at the time of changing is shown. According to this figure, it is understood that the condition that the position of the antenna 11 is −2 and the type of the Schottky diode 2 is “1SS106” is optimal. Further, according to FIG. 8D, the total length l of the Schottky diode 2 is changed to 60 mm, 50 mm, and 40 mm at each of the three measurement sites (AB ₁ , AC, B ₁ B ₂ ) of the Schottky diode 2. In this figure, it can be seen that the condition that the measurement site of the Schottky diode 2 is AC and the total length l of the Schottky diode 2 is 50 mm is optimal. Further, in FIG. 8 (e), the measurement sites of the Schottky diode 2 are AB ₁ , AC, B ₁ B _{2 at} each of the three positions (−2, −1, 0, 1, 2) of the antenna 11. The electromotive force when changed is shown, and according to this figure, it is understood that the condition that the position of the antenna 11 is −2 (or −1) and the measurement site of the Schottky diode 2 is AC is optimal. . Finally, in FIG. 8F, when the total length l of the Schottky diode 2 is changed to 60 mm, 50 mm, and 40 mm at each of the three positions (−2, −1, 0, 1, 2) of the antenna 11. According to this figure, it is understood that the condition that the position of the antenna 11 is −2 and the total length 1 of the Schottky diode 2 is 50 mm is optimal.

  Here, according to FIGS. 8C, 8 </ b> E, and 8 </ b> F, there is no great difference between the position of the antenna 11 being −2 and −1. Accordingly, the type of the Schottky diode 2 is “1SS106”, the measurement site of the Schottky diode 2 is AC, the total length l of the Schottky diode is 50 mm, and the position of the antenna 11 is −1. The electromotive force can be generated most efficiently in the Schottky diode 2 also by radiating.

  Next, experimental results when statistical analysis is performed on three types of Schottky diodes 2 (“1SS106”, “1SS86”, and “1S2076A”) will be described.

  According to FIG. 9, when “1SS106” is adopted as the type of Schottky diode 2, the largest electromotive force (approximately 1.1 V) is generated. That is, it can be seen that the electromotive force can be generated most efficiently in the Schottky diode 2 by radiating electromagnetic waves from the mobile phone 1 with the type of the Schottky diode 2 being “1SS106”.

  FIG. 10 shows the result of the experiment described above, where “1SS106” is adopted as the type of the Schottky diode 2, the position (cm) of the antenna 11 is the X axis, and the measurement site of the diode (Schottky diode 2) is the Y axis. And a three-dimensional graph in which the electromotive force is plotted when the total length l of the Schottky diode 2 is changed.

  According to FIG. 10, as described above, the type of the Schottky diode 2 is “1SS106”, the measurement site of the Schottky diode 2 is AC, the total length l of the Schottky diode is 50 mm, and the position of the antenna 11 is −1. It can be seen that electromotive force can be generated most efficiently in the Schottky diode 2 by radiating electromagnetic waves from the mobile phone 1 under the conditions (see the black circles in the figure).

  FIG. 11 is a diagram illustrating an experimental result regarding the time change of the electromotive force generated in the Schottky diode 2 in the mobile phone power storage system according to the embodiment of the present invention. More specifically, the type of the Schottky diode 2 is “1SS106”, the measurement site of the Schottky diode 2 is AC, the total length l of the Schottky diode is 50 mm, and the position of the antenna 11 is −1. The experiment on the time change of the electromotive force generated in the diode 2 was performed twice. The first experimental result is shown by a graph 11, and the second experimental result is shown by a graph 12.

  According to graph 11 and graph 12 in FIG. 11, when the Schottky diode 2 is about 2.5 V to 3.5 V (the type of the Schottky diode 2 (“1SS106”, “1SS86”, “1S2076A”) is changed) It can be seen that an average electromotive force of 3.29 V is generated. In this way, an electromotive force for storing electricity can be easily generated using radio wave resources emitted from the mobile phone 1.

  FIG. 12 is a diagram illustrating an experimental result regarding a time change of a voltage obtained from the nickel metal hydride battery 3 by connecting an ultraviolet LED to the stored nickel metal hydride battery 3 in the mobile phone power storage system according to the embodiment of the present invention. . More specifically, first, the nickel metal hydride battery was charged with a 5.2V constant voltage device for about 6 minutes until it reached MAX 4.6V. The number of 4.8 V, 120 mA nickel-metal hydride batteries 3 connected in parallel to each other is changed from one to four, and the number of 395 nm to 405 nm ultraviolet LEDs connected in series to each other is changed from one to four. The experiment on the discharge of the nickel metal hydride battery 3 was performed a plurality of times instead of the individual. The graph 21 shows the time change of voltage (represented by “1 piece, 2 pieces”) in the case of one nickel metal hydride battery and two ultraviolet LEDs. Similarly, the graph 22 is “4 pieces, 1 piece”, the graph 23 is “3 pieces, 1 piece”, the graph 24 is “2 pieces, 1 piece”, the graph 25 is “4 pieces, 2 pieces”, the graph 26. Is “3, 2”, graph 27 is “3, 4”, graph 28 is “4, 3”, graph 29 is “2, 2”, graph 30 is “3, 3” ”, Graph 31 is“ 2, 4 ”, graph 32 is“ 1, 1 ”, graph 33 is“ 3, 4 ”, graph 34 is“ 2, 3 ”, and graph 35 is “1 piece, 3 pieces” and the graph 36 show “1 piece, 4 pieces”. In addition, ultraviolet LED shines barely at about 3.3V.

  According to graphs 21 to 36 in FIG. 12, the longer the number of nickel metal hydride batteries 3 connected in parallel with each other and the fewer the number of ultraviolet LEDs connected in series with each other, It can be seen that it can be lit for hours. In particular, from the viewpoint of lighting for the longest time, as shown in the graph 22 (the voltage obtained from the nickel metal hydride battery 3 is the highest when 457 seconds have elapsed), the number of nickel metal hydride batteries 3 is It is preferable that the number of UV LEDs is four. Further, from the viewpoint of efficiently turning on a large number of ultraviolet LEDs, as shown in the graph 25 (which maintains about 3.3 V or more even after 457 seconds have passed) The number is preferably four and the number of ultraviolet LEDs is preferably two.

  FIG. 13 is a diagram showing experimental results when the nickel metal hydride battery 3 is charged by electromagnetic waves radiated from the mobile phone 1 in the mobile phone power storage system according to the embodiment of the present invention. More specifically, the number of 4.8 V, 120 mA nickel-metal hydride batteries 3 connected in parallel to each other was changed from one to four, and experiments related to charging of the nickel-metal hydride battery 3 were performed a plurality of times. The graph 41 shows the case where there is one nickel metal hydride battery 3, the graph 42 shows the case where there are two nickel metal hydride batteries 3, and the graph 43 shows the case where there are three nickel metal hydride batteries 3. Graph 44 shows the case where there are four nickel metal hydride batteries 3.

  According to the graphs 41 to 44 in FIG. 13, the voltage across the nickel metal hydride battery 3 when charged by the mobile phone 1 is smaller as the number of nickel metal hydride batteries 3 connected in parallel with each other is smaller. It has become big. Further, if charging is performed for about 90 seconds, all of the graphs 41 to 44 reach the peak value, so the optimum charging time in the mobile phone power storage system according to the embodiment of the present invention is about 90 seconds. It can be said.

  As described above, according to the mobile phone power storage system according to the embodiment of the present invention, a weak current can be obtained from the electromagnetic wave emitted from the mobile phone 1 by the Schottky diode 2 described above, and the above-described The nickel metal hydride battery 3 can appropriately store the weak current.

  INDUSTRIAL APPLICABILITY The mobile phone power storage system, the mobile phone, and the power storage method according to the present invention are useful as those that can easily and effectively use radio wave resources emitted from the mobile phone.

It is a system outline figure of a cellular phone power storage system concerning an embodiment of the invention. It is a system outline | summary figure of the mobile telephone electrical storage system which concerns on other embodiment of this invention. It is explanatory drawing which shows a mode that electric power is supplied with respect to the lithium ion battery provided in the mobile telephone. It is a system outline | summary figure of the mobile telephone electrical storage system which concerns on other embodiment of this invention. It is a system outline | summary figure of the mobile telephone electrical storage system which concerns on other embodiment of this invention. FIG. 6 is an explanatory diagram for explaining a state when a Schottky diode is provided on the front side of a mobile phone in the mobile phone power storage system according to another embodiment of the present invention shown in FIG. 5. 1 is a system schematic diagram of a mobile phone power storage system according to an embodiment of the present invention. 8 is a bar graph when statistical analysis is performed in the mobile phone power storage system shown in FIG. 7. 8 is a bar graph when statistical analysis is performed in the mobile phone power storage system shown in FIG. 7. It is the three-dimensional graph which plotted the electromotive force in a Schottky diode. It is a figure which shows the experimental result regarding the time change of the electromotive force which arises in a Schottky diode in the mobile telephone electrical storage system which concerns on the Example of this invention. It is a figure which shows the experimental result regarding the time change of the voltage obtained by connecting ultraviolet LED to the stored nickel metal hydride battery in the cellular phone power storage system according to the embodiment of the present invention. It is a figure which shows the experimental result when the nickel metal hydride battery is charged with the electromagnetic waves radiated | emitted with a mobile telephone in the mobile telephone electrical storage system which concerns on the Example of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Mobile telephone 2 Schottky diode 3 1st electrical storage means 11 Antenna 12 2nd electrical storage means

Claims (10)

A mobile phone,
The electromagnetic wave emitted from the mobile phone is received and converted into a current, and a Schottky diode that rectifies the current,
And a first power storage unit that is electrically connected to the Schottky diode and stores power based on a current obtained by the Schottky diode. The mobile phone power storage system includes a plurality of the first power storage means,
The mobile phone power storage system according to claim 1, wherein the plurality of first power storage units are connected in parallel to each other. The mobile phone is provided with second power storage means for storing power for the mobile phone to perform a call function or a communication function,
3. The mobile phone power storage according to claim 1, wherein the second power storage means is electrically connectable to the first power storage means and receives power supply from the first power storage means. system.   4. The mobile phone power storage system according to claim 1, wherein the Schottky diode and the first power storage unit are provided in the mobile phone. 5.   The mobile phone power storage system according to claim 4, wherein the Schottky diode is provided in contact with an antenna portion of the mobile phone.   6. The mobile phone power storage system according to claim 1, wherein the first power storage means is a nickel metal hydride battery capable of storing power based on a weak current obtained by the Schottky diode.   The mobile phone power storage system according to any one of claims 1 to 6, wherein the first power storage means is a nickel metal hydride battery having a nominal voltage of 1.2V and a minimum capacity of 100mAh.   The mobile phone power storage system according to any one of claims 1 to 7, wherein a total length of the Schottky diode is approximately 50 mm.   A mobile phone comprising a Schottky diode and first power storage means used in the mobile phone power storage system according to claim 1. A power storage method using the mobile phone power storage system according to claim 1.