JP3955259B2 - Charging device, charging system, and power generation amount display program - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a charging device, a portable terminal, and a power generation amount display program capable of displaying a power generation amount generated by a solar cell when charging a secondary battery using electric power generated by the solar cell.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a solar cell type mobile phone charger is known in which a solar cell is connected to a mobile phone and a secondary battery provided in the mobile phone is charged with sunlight (see, for example, Patent Document 1). This is characterized in that charging is possible even in outdoor places where there is no AC power source.
[0003]
[Patent Document 1]
Japanese Patent Laid-Open No. 2001-308356
[Problems to be solved by the invention]
By the way, in the solar cell, the electric power obtained is normally different between when the sun is sunny and strong and when it is cloudy, and the amount of sunlight varies depending on the season and time. Moreover, it is normal that the electric power obtained also changes with the direction and angle of a solar cell with respect to solar radiation. Therefore, there is a problem that a user who uses a charger as described in Patent Document 1 does not have a means for objectively determining the power generation efficiency of the solar cell, and charging is not always performed efficiently. Even if the generated voltage is displayed in real time, there is no means to determine what state the value indicates, so how can the user want to charge efficiently? In other words, there is a problem that it is impossible to know whether charging can be performed efficiently.
[0005]
The present invention has been made in view of such circumstances, and provides a charging device, a portable terminal, and a power generation amount display program that enable efficient charging by displaying the power generation amount of a solar cell in a growing state of a plant. The purpose is to provide.
[0006]
[Means for Solving the Problems]
The charging device according to the present invention is a secondary battery that temporarily stores the power generated by the solar battery to charge the secondary battery to be charged and the solar battery that generates electricity according to the amount of light applied. A battery, a power generation amount detection unit that detects and outputs the power generation amount of the solar battery, and converts the power generation amount output from the power generation amount detection unit at a predetermined time into irradiated light amount data for each time A light amount storage unit for storing, a plant information storage unit in which an image for each plant growth state is stored in advance, and a standard light amount data storage in which standard light amount data that can be obtained as a standard at every predetermined time is stored in advance. and parts, obtains the difference between the standard light quantity data stored the light quantity data stored in the light amount storage unit in the standard light quantity data storage unit for each of the predetermined time, the sum of the differences for each the predetermined time determine the growth state of the plant Te, this A control unit that selects and reads a plant image corresponding to a growth state from images stored in the plant information storage unit; and a display unit that displays the image read by the control unit. To do.
According to this configuration, the amount of power generated is regarded as an act of growing a plant, in which the sunlight is applied to the solar cell so that the growth of the plant is affected by the degree of irradiation of the solar cell with sunlight. Therefore, it is possible to encourage the solar cell to be irradiated with sunlight so that the plant grows well. As a result, sunlight is actively applied to the solar cell, so that it is possible to efficiently perform temporary charging of the secondary battery provided in the charging device, and the charging of the secondary battery to be charged can be shortened. It can be done in time. In addition, since it is possible to know that the amount of power generation varies depending on the irradiation angle of sunlight with respect to the solar cell, it is possible to encourage efficient charging by devising the direction and angle of the solar cell.
[0007]
The charging system according to the present invention is a charging system comprising a mobile terminal and a charging device for charging a secondary battery provided in the mobile terminal, wherein the charging device generates electricity according to the amount of light irradiated. A solar battery that generates power, a secondary battery that temporarily stores the power generated by the solar battery to charge the secondary battery to be charged, and a power generation amount detection that detects and outputs the power generation amount of the solar battery A light amount storage unit that converts the power generation amount output from the power generation amount detection unit at a predetermined time into irradiated light amount data and stores it at each time, and the light amount in response to a request from the portable terminal An interface for performing a connection process for reading the light amount data stored in the storage unit, the portable terminal, a plant information storage unit in which an image for each plant growth state is stored in advance, and at a predetermined time, As standard A standard light quantity data storage unit in which standard light quantity data that can be stored is stored, and the light quantity data stored in the light quantity storage unit are read out via the interface, and the read light quantity data and the standard light quantity data are read out. A difference from the standard light amount data stored in the storage unit is obtained at each predetermined time, a difference at each predetermined time is summed to obtain a growth state of the plant, and a plant image corresponding to the growth state is obtained as the plant image. A control unit is provided that selects and reads out an image stored in the information storage unit, and a display unit that displays the image read out by the control unit .
According to this configuration, the plant information storage unit that requires a large storage capacity is provided in the mobile terminal, and the control unit, the input unit, and the display unit are combined with those originally provided by the mobile terminal. Rutotomoni can simplify the configuration of the apparatus, it is possible to simplify the configuration of the charging device.
[0009]
A power generation amount display program according to the present invention temporarily stores a solar battery that generates electricity according to the amount of light applied and power generated by the solar battery in order to charge a secondary battery to be charged. A secondary battery , a plant information storage unit in which an image of each plant growth state is stored in advance, and a standard light amount data storage unit in which standard light amount data that can be obtained in a standard manner at each predetermined time is stored in advance A power generation amount display program that operates in a charging device including a light amount storage unit that stores light amount data and a display unit, and detects a power generation amount of the solar cell and outputs the generated power amount, and a predetermined amount A light amount storage process for converting the power generation amount obtained by the power generation amount detection process at the time into irradiated light amount data and storing it in the light amount storage unit at each time, and a light amount data stored in the light amount storage unit said the Obtains the difference between the standard light quantity data stored in the semi-light quantity data storage unit for each of the predetermined time, seeking the growth conditions of the plant by summing the difference between each said predetermined time, plant image corresponding to the state of growth The image selecting process for selecting and reading out the image stored in the plant information storage unit and the display process for displaying the read image on the display unit are performed by a computer. [0010]
A power generation amount display program according to the present invention temporarily stores a solar battery that generates electricity according to the amount of light applied and power generated by the solar battery in order to charge a secondary battery to be charged. A secondary battery , a power generation amount detection unit that detects and outputs the power generation amount of the solar cell, and a power generation amount output from the power generation amount detection unit at a predetermined time is converted into irradiated light amount data and time A charging device including a light amount storage unit that stores data every time, and an interface that performs connection processing for reading out the light amount data stored in the light amount storage unit in response to a request from the portable terminal , and a growth state of the plant A portable terminal provided with a plant information storage unit in which each image is stored in advance, a standard light amount data storage unit in which standard light amount data that can be obtained as a standard at every predetermined time is stored in advance, and a display unit and Tona In the charging system, the a power generation display program running on a mobile device, the reading light quantity data stored in the light amount storage unit via the interface, the light amount data thus read out standard light quantity data storage unit A difference from the standard light amount data stored in the memory is obtained at each predetermined time , a difference between the predetermined times is summed to obtain a growth state of the plant, and a plant image corresponding to the growth state is stored in the plant information storage. An image selection process for selecting and reading out from images stored in the unit and a display process for displaying the read image on the display unit are performed by a computer.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a charging device and a portable terminal according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing the configuration of the embodiment. In this figure, the code | symbol 1 is a charging device which charges a secondary battery. Reference numeral 2 denotes a solar cell that generates power by converting light energy into electrical energy. Reference numeral 3 denotes a secondary battery that temporarily stores electric power generated by the solar battery 2. Reference numeral 4 denotes a connector for connecting to a device provided with a secondary battery to be charged. Reference numeral 5 denotes a power generation amount detection unit that detects a generated voltage of the solar cell 2 and quantizes and outputs the detection result. Reference numeral 6 denotes a control unit that performs a process for replacing the display of the power generation amount with the plant growth state. Reference numeral 7 denotes an input unit composed of a key panel or the like. Reference numeral 8 denotes a display unit composed of a liquid crystal display or the like, and at least image display is possible. Reference numeral 9 denotes a light amount storage unit that stores a light amount obtained by conversion from the power generation amount detected by the power generation amount detection unit 5 according to a change with time. Reference numeral 10 denotes a plant information storage unit in which a plurality of images for each change in plant growth are stored in advance. Reference numeral 11 is a timer that can obtain the date and time. Reference numeral 12 denotes a portable terminal that is a target to be charged by the charging device 1. Reference numeral 13 denotes a connector for connecting to the connector 4 provided in the charging apparatus 1 and receiving power supply. Reference numeral 14 denotes a secondary battery that supplies power necessary for driving the mobile terminal 12, and is charged by the charging device 1.
[0012]
Next, the operation of the charging device 1 shown in FIG. 1 will be described. First, the user performs initialization by operating the input unit 7. When this initialization operation is performed, the control unit 6 instructs the display unit 8 to select a plant when the power generation amount display is expressed by the growth of the plant. At this time, a plurality of plants are displayed on the display unit 8. Then, the user arbitrarily selects one of them. This means, for example, that a tulip bulb has been planted in the garden. And the charging device 1 is installed in the place where sunlight hits, such as a window. This means shining sunlight on the selected plant. Thereby, the solar cell 2 generates electric power according to the intensity of sunlight, and temporarily stores the obtained electric power in the secondary battery 3. On the other hand, the control unit 6 refers to the output of the timer 11 and outputs the output (the generated voltage of the solar cell 2) of the power generation amount detection unit 5 at a predetermined time (for example, 8 o'clock, 12 o'clock, 4 o'clock). Quantized value). Then, the control unit 6 stores the quantized value as the amount of received light in the light amount storage unit 9 in association with the detected date and time. The light amount storage unit has a predetermined capacity, and stores the light amount within a predetermined period (for example, one week). When the amount of light data that needs to be stored exceeds the capacity of the light amount storage unit 9, the oldest data is deleted and the newest data is stored in the light amount storage unit 9. That is, the latest light amount data corresponding to the capacity of the light amount storage unit is stored.
[0013]
Next, the user performs a predetermined operation from the input unit 7 at an arbitrary timing, and gives an instruction to display the growth status of the selected plant. In response to this, the control unit 6 reads the current state value of the plant from the plant information storage unit 10. At this time, since the bulb is planted, the state value is “0”. And the control part 6 reads light quantity data from the light quantity memory | storage part 9, and calculates the growth point of a plant based on this read light quantity data. The control unit 6 stores standard light quantity data as shown in FIG. The standard light quantity data is defined as light quantity data (a value obtained by quantizing the generated voltage of the solar cell 2) that can be obtained in standard time by sunlight. The growth point is obtained as follows based on the standard light quantity data and the actually obtained light quantity data. When the ratio (actual measurement / standard) of the measured light quantity data and the standard light quantity data is 0.7 to 1.0, the growth point is set to “+1”. When the ratio (actual measurement / standard) between the actually measured light amount data and the standard light amount data is 0.4 to less than 0.7, the growth point is set to “0”. When the ratio (actual measurement / standard) between the actually measured light amount data and the standard light amount data is 0 to less than 0.4, the growth point is set to “−1”. Subsequently, the control unit 6 clears the content of the light amount storage unit 9.
[0014]
Next, the control unit 6 sums the growth points obtained for each actually measured light quantity data. Then, this total value is added to the previously read state value, and the obtained result becomes a new state value. This state value is a value indicating that the growth of the plant is progressing as the numerical value increases. This new state value is stored in the plant information storage unit 10. Subsequently, the control unit 6 reads an image corresponding to the obtained state value from the plant information storage unit 10 and displays it on the display unit 8. The image displayed here is an image of a plant that has grown according to the amount of power generation. If the amount of power generation is large, an image of the plant that has grown well is displayed. If the amount of power generation is small, the plant has poor growth or has withered. Is displayed.
[0015]
In this way, the action of exposing the solar cell 2 to the sun so as to affect the growth of the plant depending on the degree of irradiation of the solar cell 2 with sunlight is the power generation amount display that is regarded as an act of growing the plant. It is possible to encourage the plant to radiate sunlight so that it grows well. As a result, since sunlight is actively applied to the solar cell 2, it is possible to efficiently perform temporary charging of the secondary battery 3 provided in the charging device 1, and the secondary battery 3 to be charged Charging can be performed in a short time. Moreover, since it can be known that the amount of power generation varies depending on the irradiation angle of sunlight with respect to the solar cell 2, it is possible to encourage efficient charging by devising the direction and angle of the solar cell 2. Become.
[0016]
It is to be noted that commands indicating “watering”, “fertilizer”, “pest control”, etc. are input to the plant from the input unit 7, and the plant grows according to the number and timing of this command. You may make it increase / decrease a point. By doing in this way, it becomes possible to construct a plant breeding game that is more suitable for actual flower cultivation, and it is possible to provide a power generation amount display environment with more excellent game characteristics.
[0017]
Further, when the growth of one plant is completed and the flower blooms, the image data of the plant, the pollen having the characteristics of the grown plant, and the data of the seed may be stored. Further, these data may be exchanged with data in a charging device owned by another person so that plants can be crossed. Thus, since the frequency of hitting the solar cell 2 against the sun is improved by improving the game performance of the power generation amount display, it is possible to further improve the charging efficiency.
[0018]
Next, another embodiment will be described with reference to FIG. FIG. 2 is a block diagram illustrating configurations of a charging device and a portable terminal according to another embodiment. In this figure, the same parts as those in the embodiment shown in FIG. The device shown in this figure is different from the embodiment shown in FIG. 1 in that the charging device 15 includes a solar battery 2, a secondary battery 3, a timer 11, a power generation amount detection unit 5, a light quantity storage unit 9, and an interface 16. The mobile terminal 12 is provided with a control unit 17, an input unit 18, a display unit 19, a timer 20, and a plant information storage unit 21. The secondary battery 14 supplies power to the mobile terminal 12. Further, in FIG. 2, only the configuration requirements related to the present invention are shown, and the configuration requirements inherent to the mobile terminal 12 are omitted. Note that the control unit 17, the input unit 18, the display unit 19, and the timer 20 also share what the mobile terminal 12 originally has.
[0019]
Next, operations of the charging device 15 and the mobile terminal 12 illustrated in FIG. 2 will be described. First, the user connects the charging device 15 and the portable terminal 12 with the connector 4 and the connector 13. Then, initialization is performed by operating the input unit 18. When this initialization operation is performed, the control unit 17 instructs the display unit 19 to select a plant when the power generation amount display is represented by plant growth. At this time, a plurality of plants are displayed on the display unit 19. Then, the user arbitrarily selects one of them. This means, for example, that a tulip bulb has been planted in the garden. And the portable terminal 12 is removed from the charging device 15, and the charging device 15 is installed in the place where sunlight, such as a window, hits. This means shining sunlight on the selected plant. Thereby, the solar cell 2 generates electric power according to the intensity of sunlight, and temporarily stores the obtained electric power in the secondary battery 3. On the other hand, the power generation amount detection unit 5 refers to the output of the timer 11 and outputs a value obtained by quantizing the generated voltage of the solar cell 2 at a predetermined time (for example, 8 o'clock, 12 o'clock, 4 o'clock). Store in the storage unit 9.
[0020]
Next, the user connects the charging device 15 and the portable terminal 12 at an arbitrary timing, and performs a predetermined operation from the input unit 7 to charge the secondary battery 14 provided in the portable terminal 12. At this timing, the control unit 17 reads the current state value of the plant from the plant information storage unit 21. At this time, since the bulb is planted, the state value is “0”. And the control part 17 reads light quantity data from the light quantity memory | storage part 9, and calculates the growth point of a plant based on this read light quantity data. The plant growth point calculation is as described above.
[0021]
Next, the control part 17 totals the growth points calculated | required for every measured light quantity data. Then, this total value is added to the previously read state value, and the obtained result becomes a new state value. This state value is a value indicating that the growth of the plant is progressing as the numerical value increases. The new state value is stored in the plant information storage unit 21. Subsequently, the control unit 17 reads an image corresponding to the obtained state value from the plant information storage unit 21 and displays it on the display unit 19.
[0022]
In this way, the plant information storage unit 21 that requires a large storage capacity is provided in the mobile terminal 12, and the control unit 17, the input unit 18, and the display unit 19 are shared with what the mobile terminal 12 originally has. Therefore, the configuration of the charging device 15 can be simplified.
[0023]
The program for realizing the functions of the processing units in FIGS. 1 and 2 is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read by the computer system and executed to generate power. Display processing may be performed. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer system” includes a WWW system having a homepage providing environment (or display environment). The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Further, the “computer-readable recording medium” refers to a volatile memory (RAM) in a computer system that becomes a server or a client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. In addition, those holding programs for a certain period of time are also included.
[0024]
The program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the “transmission medium” for transmitting the program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, and what is called a difference file (difference program) may be sufficient.
[0025]
【The invention's effect】
As described above, according to the present invention, depending on the degree of irradiation of sunlight on the solar cell, the growth of the plant is affected, and the act of exposing the solar cell to sunlight is the act of growing the plant. Since the power generation amount is regarded as being displayed, there is an effect that it is possible to urge the solar cell to irradiate sunlight so that the plant grows well. As a result, sunlight is actively applied to the solar cell, so that it is possible to efficiently perform temporary charging of the secondary battery provided in the charging device, and the charging of the secondary battery to be charged can be shortened. It can be done in time. In addition, since it is possible to know that the amount of power generation varies depending on the irradiation angle of sunlight with respect to the solar cell, it is possible to encourage efficient charging by devising the direction and angle of the solar cell.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an embodiment of the present invention.
FIG. 2 is a block diagram showing a configuration of another embodiment of the present invention.
FIG. 3 is an explanatory diagram showing standard light quantity data.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Charging apparatus 2 ... Solar cell 3 ... Secondary battery 5 ... Electric power generation amount detection part 6, 17 ... Control part,
7, 18 ... input unit 8, 19 ... display unit 9 ... light quantity storage unit 10, 21 ... plant information storage unit 11 ... timer 12 ... portable terminal

Claims (4)

A solar cell that generates electricity according to the amount of light irradiated;
A secondary battery that temporarily stores electric power generated by the solar battery in order to charge the secondary battery to be charged;
A power generation amount detection unit that detects and outputs the power generation amount of the solar cell;
A light amount storage unit that converts the power generation amount output from the power generation amount detection unit at a predetermined time into irradiated light amount data and stores it at each time;
A plant information storage unit in which an image of each plant growth situation is stored in advance;
A standard light quantity data storage unit in which standard light quantity data that can be obtained as standard is stored in advance at each predetermined time;
The difference between the light amount data stored in the light amount storage unit and the standard light amount data stored in the standard light amount data storage unit is obtained at each predetermined time, and the difference at each predetermined time is summed to determine the plant A control unit for obtaining a growth situation, and selecting and reading out a plant image corresponding to the growth situation from an image stored in the plant information storage unit;
A charging device comprising: a display unit that displays an image read by the control unit. A charging system comprising a mobile terminal and a charging device for charging a secondary battery provided in the mobile terminal,
The charging device is:
A solar cell that generates electricity according to the amount of light irradiated;
A secondary battery that temporarily stores electric power generated by the solar battery in order to charge the secondary battery to be charged;
A power generation amount detection unit that detects and outputs the power generation amount of the solar cell;
A light amount storage unit that converts the power generation amount output from the power generation amount detection unit at a predetermined time into irradiated light amount data and stores it at each time;
An interface for performing connection processing for reading light amount data stored in the light amount storage unit in response to a request from the mobile terminal ,
The portable terminal is
A plant information storage unit in which an image of each plant growth situation is stored in advance;
A standard light quantity data storage unit in which standard light quantity data that can be obtained as standard is stored in advance at each predetermined time;
The light amount data stored in the light amount storage unit is read out via the interface, and the difference between the read light amount data and the standard light amount data stored in the standard light amount data storage unit is determined at each predetermined time. Determining, summing up the difference at each predetermined time to determine the growth status of the plant, and selecting and reading out a plant image corresponding to this growth status from the image stored in the plant information storage unit;
A display unit for displaying an image read by the control unit;
A charging system comprising: A solar cell that generates electricity according to the amount of light irradiated, a secondary battery that temporarily stores the power generated by the solar cell to charge the secondary battery to be charged, and the growth status of the plant A plant information storage unit in which each image is stored in advance, a standard light amount data storage unit in which standard light amount data that can be obtained as a standard at every predetermined time, and a light amount storage unit in which the light amount data is stored And a power generation amount display program that operates on a charging device including a display unit ,
A power generation amount detection process for detecting and outputting the power generation amount of the solar cell;
A light amount storage process for converting the power generation amount obtained by the power generation amount detection process at a predetermined time into irradiated light amount data and storing it in the light amount storage unit at each time,
Obtains the difference between the standard light quantity data stored light amount data stored in the light amount storage unit in the standard light quantity data storage unit for each of the predetermined time, the plants by summing the difference between each the predetermined time An image selection process for obtaining a growth situation, selecting and reading out a plant image corresponding to the growth situation from images stored in the plant information storage unit ,
A power generation amount display program causing a computer to perform display processing for displaying the read image on the display unit . A solar cell that generates electricity in response to the amount of illumination light being, said temporarily storing the secondary battery electric power generated by the solar cell to charge the secondary battery to be charged, the solar cell A power generation amount detection unit that detects and outputs a power generation amount; a light amount storage unit that converts the power generation amount output from the power generation amount detection unit at a predetermined time into irradiation light amount data; A charging device including an interface for performing connection processing for reading light amount data stored in the light amount storage unit in response to a request from the portable terminal ;
A plant information storage unit in which images for each plant growth state are stored in advance, a standard light amount data storage unit in which standard light amount data that can be obtained in a standard manner is stored in advance at a predetermined time, and a display unit Equipped mobile device and
In the charging system comprising: a power generation amount display program that operates on the mobile terminal,
The light amount data stored in the light amount storage unit is read out via the interface, and the difference between the read light amount data and the standard light amount data stored in the standard light amount data storage unit is determined at each predetermined time. Determining, and summing up the differences at each predetermined time to obtain a growth state of the plant, and selecting and reading out a plant image corresponding to the growth state from images stored in the plant information storage unit ; ,
A power generation amount display program causing a computer to perform display processing for displaying the read image on the display unit .

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