JP2020114160A - Control device, system, and program - Google Patents

Abstract

To provide a control device, a system, and a program, for controlling electric power supplied to a mining machine from a power source including a solar power generation device and a storage battery.SOLUTION: In a system 101, the control device includes: a remaining amount acquisition unit; a power generation information acquisition unit; a threshold value determination unit; and an instruction transmission unit. The remaining amount acquisition unit acquires a remaining battery amount of a storage battery. The power generation information acquisition unit acquires at least one of a power generation amount of a solar power generation device and estimation information for estimating a power generation amount of the solar power generation device as power generation information. The threshold value determination unit determines a first threshold value and a second threshold value based on the power generation information. The instruction transmission unit transmits an instruction to use power generated by the solar power generation device when a battery remaining amount becomes larger than the first threshold value and transmits an instruction not to use the power generated by the solar power generation device when the remaining battery power becomes smaller than the second threshold value.SELECTED DRAWING: Figure 1

Description

The present invention relates to a control device, system and program.

In recent years, virtual currency has become widespread. Most virtual currencies require a calculation process called mining. For example, Patent Document 1 describes that this mining requires a huge amount of calculation.

Japanese Patent No. 6345871

As mentioned above, mining requires a huge amount of calculation. Therefore, a mining machine that performs mining often operates under a heavy load and consumes a large amount of power.

By the way, it is a reality that most of electric power is produced by using nuclear fuel or fossil fuel, and an increase in power consumption is not preferable for the global environment.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a control device, a system, and a program that control the power supplied from a power supply including a solar power generation device and a storage battery to a mining machine. ..

According to the present invention, there is provided a control device for controlling electric power supplied to a mining machine from a power source including a solar power generation device and a storage battery, the remaining amount acquisition unit, the power generation information acquisition unit, the threshold value determination unit, and the instruction transmission unit. And the remaining power acquisition unit is configured to be able to acquire the remaining battery power of the storage battery, and the power generation information acquisition unit estimates the power generation amount of the solar power generation device and the power generation amount of the solar power generation device. At least one of the estimated information to be obtained as power generation information, and the threshold value determination unit is configured to be able to determine a first threshold value and a second threshold value based on the power generation information, and the instruction sending unit. Is configured to be capable of sending an instruction to use the electric power generated by the solar power generation device when the remaining battery level becomes larger than the first threshold value, and the remaining battery level is set to the second level. There is provided a control device configured to be able to send an instruction not to use the electric power generated by the solar power generation device when the value becomes smaller than a threshold value.

It is a figure showing composition of system 101 including control device 1 concerning an embodiment of the present invention. It is a figure showing composition of system 102 including control device 1 concerning an embodiment of the present invention. It is a figure showing composition of system 103 including control device 1 concerning an embodiment of the present invention. It is a figure showing composition of system 104 including control device 1 concerning an embodiment of the present invention. It is a figure showing composition of system 105 including control device 1 concerning an embodiment of the present invention. It is a flow chart which shows a flow of operation which control device 1 determines the 1st threshold and the 2nd threshold. 7 is a flowchart showing a flow of an operation in which the control device 1 sends a closing instruction and a disconnecting instruction. 6 is a flowchart showing a flow of an operation in which the control device 1 sends a switching instruction. It is a figure for demonstrating electric power amount (alpha). It is a figure showing the power generation characteristic of the solar power generation device 21. It is a figure for demonstrating electric energy (beta).

Embodiments of the present invention will be described below with reference to the drawings. The various features shown in the embodiments described below can be combined with each other.

1. Configuration example (1)
FIG. 1 is a diagram showing a configuration of a system 101 including a control device 1 according to an embodiment of the present invention.

As shown in the figure, the system 101 includes a control device 1, a power supply 2, a mining machine 3-1, a mining machine 3-2, a mining machine 3-n, a weather observation device 4, and a weather information distribution service 5. Further, the control device 1 includes a power generation information acquisition unit 11, a remaining amount acquisition unit 12, a threshold value determination unit 13, an instruction transmission unit 14, and a clock 15, and the power supply 2 includes a solar power generation device 21 and a storage battery 22. doing.

The mining machine 3-1 is the first mining machine, the mining machine 3-2 is the second mining machine, and the mining machine 3-n is the nth mining machine. That is, the system 101 includes n mining machines. In addition, below, when the mining machine 3-1, the mining machine 3-2, and the mining machine 3-n are not distinguished, these are called the mining machine 3.

Subsequently, the control device 1 will be described. The control device 1 controls the power supplied from the power supply 2 including the solar power generation device 21 and the storage battery 22 to the mining machine 3-1, the mining machine 3-2, and the mining machine 3-n, and the remaining amount. An acquisition unit, a power generation information acquisition unit, a threshold value determination unit, and an instruction transmission unit are provided. Specifically, the control device 1 causes a computer to execute a program, and causes the computer to function as the power generation information acquisition unit 11, the remaining amount acquisition unit 12, the threshold value determination unit 13, the instruction transmission unit 14, and the clock 15. Will be realized.

The power generation information acquisition unit 11 acquires at least one of power generation amount of the solar power generation device 21 and estimation information for estimating the power generation amount of the solar power generation device 21 as power generation information. Here, the solar power generation device 21 outputs the power generation amount as a signal, but if the solar power generation device 21 cannot output the power generation amount as a signal, the solar power generation device 21 outputs the power generation amount. A device to be measured may be connected and the power generation information acquisition unit 11 may acquire the power generation amount from the device. Further, the estimated information includes the time measured by the clock 15, the weather information observed by the weather observation device 4, the weather information received from the weather information distribution service 5, and the like.

The remaining amount acquisition unit 12 acquires the remaining battery amount of the storage battery 22. Here, the storage battery 22 outputs the remaining battery level as a signal, but if the storage battery 22 cannot output the remaining battery level as a signal, the remaining amount acquisition unit 12 outputs the remaining battery level. It may be configured to measure and acquire, or the storage battery 22 may be connected to a device that measures the remaining battery amount, and the remaining amount acquisition unit 12 may acquire the remaining battery amount from the device.

The threshold determination unit 13 determines the first threshold and the second threshold based on the power generation information. The first threshold is a value used as a condition for turning on the power of the mining machine 3, and the second threshold is a value used as a condition for turning off the power of the mining machine 3. A method of determining the first threshold value and the second threshold value by the threshold value determination unit 13 will be described later.

The instruction sending unit 14 sends an instruction to use the electric power generated by the photovoltaic power generation device 21 when the remaining battery level of the storage battery 22 becomes larger than the first threshold value, and the remaining battery level of the storage battery 22 reaches the second level. When it becomes smaller than the threshold value of 1, the instruction to not use the power generated by the solar power generation device 21 is transmitted. For example, the instruction sending unit 14 is connected to the mining machine 3 via a network, and sends a closing instruction and a disconnecting instruction via this network. Specifically, the instruction sending unit 14 sends a closing instruction to the mining machine 3 when the remaining battery level of the storage battery 22 becomes larger than the first threshold value, and the remaining battery level of the storage battery 22 reaches the second threshold value. When it becomes smaller than the above, a cutting instruction of the mining machine is sent. For example, the control device 1 gives a power-on instruction by WoL (Wake on Lan) and gives a power-off instruction by remote control.

The clock 15 keeps time.

The solar power generation device 21 uses a solar cell module to generate power. The amount of power generated by the solar power generation device 21 is not limited, but it is determined in consideration of the power consumption of the mining machine 3 and the like.

The storage battery 22 stores the electric power generated by the solar power generation device 21. The type and capacity of the storage battery 22 are not limited, but the storage battery 22 is determined in consideration of the power generation amount of the solar power generation device 21, the power consumption of the mining machine 3, and the like.

The mining machine 3 performs mining, and the mining machine 3-1, the mining machine 3-2, and the mining machine 3-n may be the same model or different models.

The meteorological observation device 4 is installed in the vicinity of the solar power generation device 21 and performs meteorological observation to acquire meteorological information. The meteorological information to be acquired preferably includes both the amount of solar radiation and the temperature, but may be general information that does not measure the amount of solar radiation, such as measuring the temperature and rainfall.

The meteorological information distribution service 5 is a service that distributes meteorological information using the Internet or a broadcasting network, and distributes actual measured values and predicted values of weather and temperature, sunrise time and sunset time, and the like as meteorological information.

2. Configuration example (2)
FIG. 2 is a diagram showing a configuration of the system 102 including the control device 1 according to the embodiment of the present invention.

As shown in the figure, the system 102 includes a control device 1, a power supply 2, a mining machine 3-1, a mining machine 3-2, a mining machine 3-n, a weather observation device 4, a weather information distribution service 5, and a management device 6. Is included. Further, the control device 1 includes a power generation information acquisition unit 11, a remaining amount acquisition unit 12, a threshold value determination unit 13, an instruction transmission unit 14, and a clock 15, and the power supply 2 includes a solar power generation device 21 and a storage battery 22. doing.

Since the system 102 is different from the above-described system 101 only in a part of the configuration, only the part different from the system 101 will be described and the other description will be omitted.

The system 102 is different from the system 101 in that it has a management device 6. The management device 6 is a device that manages the mining machine 3, and particularly manages the power supply of the mining machine 3. Therefore, unlike the case of the system 101, the instruction sending unit 14 sends the insertion instruction and the disconnection instruction to the management device 6 that manages the mining machine 3.

The instruction sending unit 14 sends a closing instruction to the mining machine 3 when the battery remaining amount of the storage battery 22 becomes larger than the first threshold value, and the battery remaining amount of the storage battery 22 becomes smaller than the second threshold value. In this case, the cutting instruction of the mining machine is sent.

The management device 6 is connected to the mining machine 3 via the network, and when receiving the input instruction from the instruction sending unit 14, sends the input instruction to the mining machine 3 via the network and disconnects from the instruction sending unit 14. When the instruction is received, the disconnection instruction is sent to the mining machine 3 via the network. For example, the management device 6 gives a power-on instruction by WoL (Wake on Lan) and gives a power-off instruction by remote control.

The management device 6 may be configured to mechanically control the power supply of the mining machine 3 without making a network connection with the mining machine 3. For example, a movable mechanism that can press the power switch is installed near the power switch of each mining machine 3, and the management device 6 controls the movable mechanism. The power switch of each mining machine 3 can be controlled by pressing the power switch 3 of the min. 3 for a short time and pressing the power switch of each mining machine 3 for a long time when the power is turned off.

3. Configuration example (3)
FIG. 3 is a diagram showing a configuration of the system 103 including the control device 1 according to the embodiment of the present invention.

As shown in the figure, the system 103 includes a control device 1, a power supply 2, a mining machine 3-1, a mining machine 3-2, a mining machine 3-n, a weather observation device 4, a weather information distribution service 5, and a management device 6. And a measuring device 7. Further, the control device 1 includes a power generation information acquisition unit 11, a remaining amount acquisition unit 12, a threshold value determination unit 13, an instruction transmission unit 14, and a clock 15, and the power supply 2 includes a solar power generation device 21 and a storage battery 22. doing.

Since the system 103 is different from the above-described system 102 only in part of the configuration, only the part different from the system 102 will be described and the other description will be omitted.

The system 103 differs from the system 102 in that it has a measuring device 7. The measurement device 7 is a device that measures the power generation amount of the solar power generation device 21 and the battery remaining amount of the storage battery 22, and outputs the measurement result as a signal. Therefore, unlike the case of the system 102, the power generation information acquisition unit 11 acquires the power generation amount of the solar power generation device 21 from the measurement device 7. Similarly, the remaining amount acquisition unit 12 acquires the remaining battery amount of the storage battery 22 from the measuring device 7.

The measurement device 7 can be configured to measure only one of the power generation amount of the solar power generation device 21 and the battery remaining amount of the storage battery 22. In this case, the amount of power generation or the remaining battery level not measured by the measuring device 7 is acquired by the power generation information acquisition unit 11 or the remaining amount acquisition unit 12 in the same manner as in the case of the system 102.

4. Configuration example (4)
FIG. 4 is a diagram showing a configuration of the system 104 including the control device 1 according to the embodiment of the present invention.

As shown in the figure, the system 104 includes a control device 1, a power supply 2, a mining machine 3-1, a mining machine 3-2, a mining machine 3-n, a weather observation device 4, a weather information distribution service 5, and a management device 6. And a measuring device 7. Further, the control device 1 includes a power generation information acquisition unit 11, a remaining amount acquisition unit 12, a threshold value determination unit 13, an instruction transmission unit 14, and a clock 15, and the power supply 2 includes a solar power generation device 21 and a storage battery 22. doing.

The system 104 basically has the same configuration as the system 103 described above, but the power source 2 other than the control device 1, the mining machine 3-1, the mining machine 3-2, the mining machine 3-n, and the meteorological observation device. 4. The weather information distribution service 5, the management device 6, and the measuring device 7 are arranged at the base 8, and the base 8 and the control device 1 are connected by a network NT such as the Internet.

Further, the system 104 connects a plurality of bases 8 (all of which have the same configuration as the base 8) to the control device 1 via the network NT, and one control device 1 connects the mining machines 3 of the plurality of bases 8. It is possible to control the power supply of.

In addition, in FIG. 4, each of the power generation information acquisition unit 11, the remaining amount acquisition unit 12, and the instruction transmission unit 14 is shown to be connected to the network NT, but actually, via a communication unit (not shown) or the like. Then, each of the power generation information acquisition unit 11, the remaining amount acquisition unit 12, and the instruction transmission unit 14 is connected to the network NT.

Similarly, in FIG. 4, each of the meteorological observation device 4, the management device 6, and the measurement device 7 is shown to be connected to the network NT. However, in reality, the meteorological observation device is connected via a gateway or the like (not shown). The device 4, the management device 6 and the measuring device 7 are each connected to the network NT.

5. Configuration example (5)
FIG. 5 is a diagram showing a configuration of the system 105 including the control device 1 according to the embodiment of the present invention.

As shown in the figure, the system 105 includes a control device 1, a power supply 2, a mining machine 3-1, a mining machine 3-2, a mining machine 3-n, a weather observation device 4, and a weather information distribution service 5. Further, the control device 1 includes a power generation information acquisition unit 11, a remaining amount acquisition unit 12, a threshold value determination unit 13, an instruction transmission unit 14, and a clock 15, and the power supply 2 is a solar power generation device 21, a storage battery 22, and a switching device. And 23.

Since the system 105 is different from the above-described system 101 only in a part of the configuration, only the part different from the system 101 will be described and the other description will be omitted.

The system 105 is different from the system 101 in that the power supply 2 has a switching device 23. The switching device 23 switches the power supply source of the power supplied to the mining machine 3 to either the storage battery 22 or a commercial power supply.
The instruction sending unit 14 issues a switching instruction to the switching device 23 to switch the power supply source of the power supplied to the mining machine 3 from the commercial power source to the storage battery 22 when the remaining battery level of the storage battery 22 becomes larger than the first threshold value. When the remaining battery level of the storage battery 22 becomes smaller than the second threshold value, a switching instruction for switching the power supply source of the power supplied to the mining machine 3 from the storage battery 22 to the commercial power source is sent to the switching device 23.
In each of the system 102 (see FIG. 2), the system 103 (see FIG. 3), and the system 104 (see FIG. 4) described above, the power supply 2 is provided with the switching device 23, and the instruction sending unit 14 switches the switching device 23. It is also possible to send the switching instruction.

6. Operation of Control Device 1 Next, the operation of the control device 1 will be described. The operation of the control device 1 is roughly classified into an operation of determining a first threshold value and a second threshold value and an operation of sending a closing instruction and a disconnection instruction. Here, each operation will be described.

FIG. 6 is a flowchart showing a flow of an operation in which the control device 1 determines the first threshold value and the second threshold value.

(S101)
The power generation information acquisition unit 11 acquires power generation information.

(S102)
The threshold value determination unit 13 determines the first threshold value.

(S103)
The threshold value determination unit 13 determines the second threshold value.

The operations of S101 to S103 are repeated at predetermined intervals. The interval does not have to be constant, but may be constant.

FIG. 7 is a flowchart showing a flow of an operation in which the control device 1 sends a closing instruction and a cutting instruction. Note that the operation described here is not applied to the control device 1 of the system 105 (see FIG. 5).

(S201)
The remaining amount acquisition unit 12 acquires the remaining battery amount of the storage battery 22.

(YES in S202, YES in S203, S204)
If the target mining machine 3 is stopped and the value of the remaining battery level of the storage battery 22 is larger than the first threshold value, the instruction sending unit 14 sends a throwing instruction to the mining machine 3 or the management device 6.

(YES in S202, NO in S203)
Even if the target mining machine 3 is stopped, if the value of the remaining battery level of the storage battery 22 is less than or equal to the first threshold value, no processing is performed.

(NO in S202, YES in S205, YES in S206, S207)
If the target mining machine 3 is operating and the value of the remaining battery level of the storage battery 22 is smaller than the second threshold value, the instruction sending unit 14 sends a disconnection instruction to the mining machine 3 or the management device 6.

(NO in S202, YES in S205, NO in S206)
Even if the target mining machine 3 is in operation, if the value of the remaining battery level of the storage battery 22 is greater than or equal to the second threshold value, no processing is performed.

FIG. 8 is a flowchart showing the flow of the operation in which the control device 1 sends the switching instruction. The operation described here corresponds to the control device 1 of the system 105.

(S301)
The remaining amount acquisition unit 12 acquires the remaining battery amount of the storage battery 22.

(YES in S302, YES in S303, S304)
If the power supply to the mining machine 3 is performed from the commercial power supply and the value of the remaining battery level of the storage battery 22 is larger than the first threshold value, the instruction sending unit 14 sets the power supply source to the mining machine 3 to the commercial power supply. From the storage battery 22 to the switching device 23.

(YES in S302, NO in S303)
Even if power is supplied to the mining machine 3 from the commercial power source, if the value of the remaining battery level of the storage battery 22 is equal to or less than the first threshold value, no processing is performed.

(NO in S302, YES in S305, YES in S306, S307)
If the storage battery 22 is supplying power to the mining machine 3 and the value of the remaining battery level of the storage battery 22 is smaller than the second threshold value, the instruction sending unit 14 sets the power supply source to the mining machine 3 to the storage battery 22. From the power source to the commercial power source is sent to the switching device 23.

(NO in S302, YES in S305, NO in S306)
Even if power is supplied to the mining machine 3 from the storage battery 22, if the value of the remaining battery level of the storage battery 22 is equal to or greater than the second threshold value, no processing is performed.

7. First Threshold Next, an example of a method of determining the first threshold will be described. Here, regarding the respective examples of the case where the power generation information acquired by the power generation information acquisition unit 11 uses only the amount of power generation, only weather information, only time, and a plurality of information explain.

When determining the first threshold value based only on the power generation amount, if the acquired power generation amount is less than or equal to the power consumption of the mining machine 3, the threshold value determination unit 13 sets the first threshold value to the power-off process of the mining machine 3. It is a value obtained by adding a predetermined power amount α to the required power amount. As the power consumption of the mining machine 3, either a rated value or a value measured in advance can be used. Further, the electric power amount α is, for example, as shown in FIG. 9, electric power that can move the mining machine 3 for a fixed time (3 hours in FIG. 9). The reason for considering the amount of electric power α is to prevent a situation in which the mining machine 3 is powered off immediately after the mining machine 3 is powered on. The electric energy α can be set arbitrarily.

Further, when determining the first threshold value based only on the power generation amount, if the acquired power generation amount is larger than the power consumption of the mining machine 3, the threshold value determination unit 13 sets the first threshold value to the power-off of the mining machine 3. The amount of power required for processing. When the power generation amount of the solar power generation device 21 is larger than the power consumption of the mining machine 3, the storage battery 22 is in the charging state even when the mining machine 3 is operating, and therefore it is not necessary to consider the power amount α. .. Even when the power generation amount of the solar power generation device 21 is larger than the power consumption of the mining machine 3, a value obtained by adding the power amount α or a power amount smaller than α to the power amount required for the power-off process of the mining machine 3 is used. It can also be the first threshold.

By the way, the threshold value determination unit 13 determines the first threshold value at a predetermined interval, as described with reference to FIG. Therefore, the threshold value determination unit 13 stores the amount of power generation that the power generation information acquisition unit 11 has acquired in the past, determines whether the amount of power generation has an upward tendency or a downward tendency, and based on the determination result, the power It is also possible to increase or decrease the value of the quantity α.

When determining the first threshold value based only on the weather information, the threshold value determination unit 13 first calculates the predicted value of the power generation amount of the photovoltaic power generation device 21 based on the weather information acquired by the power generation information acquisition unit 11. To do. Since the solar power generation device 21 has the power generation characteristics as shown in FIG. 10, it is possible to calculate the predicted value of the power generation amount from the weather information, for example, the weather and the temperature. The power generation characteristic shown in FIG. 10 is an example, and the actual power generation characteristic varies depending on the temperature, region, and day.

If the calculated predicted value of the power generation amount is less than or equal to the power consumption of the mining machine 3, the threshold value determination unit 13 adds the predetermined power amount α to the power amount required for the power-off process of the mining machine 3 as the first threshold value. The value.

If the predicted value of the calculated power generation amount is larger than the power consumption of the mining machine 3, the first threshold value is the power amount required for the power-off process of the mining machine 3. Even if the predicted value of the calculated power generation amount is larger than the power consumption of the mining machine 3, the value obtained by adding the power amount α or the power amount smaller than α to the power amount required for the power-off processing of the mining machine 3 is The threshold value may be 1.

When the weather information includes weather forecast information, the value of the power amount α can be increased or decreased based on the weather forecast information.

When determining the first threshold value based only on the time, the threshold value determination unit 13 sets the first threshold value to the power off of the mining machine 3 during the time period when the power generation amount of the solar power generation device 21 is expected to be equal to or higher than a certain amount. The amount of electric power required for the processing is set, and in the other time zones, the first threshold value is a value obtained by adding a predetermined amount of electric power α to the amount of electric power required for the power-off processing of the mining machine 3.

Also when determining the first threshold value based on a plurality of information, if the power generation amount or its predicted value is less than or equal to the power consumption of the mining machine 3, the first threshold value is the power amount required for the power-off process of the mining machine 3. If the power generation amount or its predicted value is larger than the power consumption of the mining machine 3, the first threshold value is the power amount required for the power-off process of the mining machine 3.

Further, when determining the first threshold value based on the amount of power generation and time or when determining the first threshold value based on weather information and time, the time zone in which the mining machine 3 is desired to operate is designated, It is possible to give priority to the operation of the mining machine 3 in that time zone. This is because the success rate of mining fluctuates depending on the number of competitors, so that it is possible to specify an advantageous time zone for mining.

When designating the time zone in which the mining machine 3 operates, if the power generation amount or the predicted value thereof is less than or equal to the power consumption of the mining machine 3, the threshold value determination unit 13 sets the first threshold value to the power-off processing of the mining machine 3. It is a value obtained by adding a predetermined power amount α and a predetermined power amount β to the required power amount. The amount of electric power β is, for example, as shown in FIG. 11, electric power that can move the mining machine 3 for a designated time (from 14:00 to 22:00 in FIG. 11).

Further, in the case of designating the time zone in which the mining machine 3 operates, if the power generation amount or the predicted value thereof is larger than the power consumption of the mining machine 3, the threshold value determination unit 13 sets the first threshold value to the power source of the mining machine 3. It is a value obtained by adding a predetermined power amount β to the power amount required for the disconnection process.

The method of determining the first threshold value described here is an example, and the first threshold value may be determined by another method.

8. Second Threshold Next, an example of a method of determining the second threshold will be described. Here, an example of a case corresponding to each of the above-described first threshold value determination methods will be described.

When determining the second threshold value based only on the power generation amount, the threshold value determination unit 13 sets the second threshold value as the power amount required for the power-off process of the mining machine 3.

When determining the second threshold value based only on the weather information, the threshold value determination unit 13 sets the second threshold value as the amount of power required for the power-off process of the mining machine 3.

When determining the second threshold value based only on the time, the threshold value determination unit 13 sets the second threshold value as the power amount required for the power-off process of the mining machine 3.

When determining the second threshold value based on a plurality of pieces of information, the threshold value determination unit 13 sets the second threshold value to the power-off processing of the mining machine 3 except when the operating time zone of the mining machine 3 is designated. The amount of electricity required for

When the second threshold is determined based on a plurality of pieces of information, and when the time zone in which the mining machine 3 operates is designated, the threshold determination unit 13 mines the second threshold in the designated time zone. The power amount required for the power-off process of the machine 3 is set, and the threshold value determination unit 13 adds the second threshold value to the power amount required for the power-off process of the mining machine 3 by a predetermined power amount β except the designated time period. Value.

The method of determining the second threshold value described here is an example, and the second threshold value may be determined by another method.

With the configuration and processing described above, by using the control device 1, it is possible to cut off the power supply of the mining machine 3 in an appropriate procedure even when the power generated by solar power is used.

Further, as a result, it is possible to obtain the effect that the mining machine 3 can be moved without installing a power receiving facility for a commercial power source.

<Other>
The present invention can also be implemented in the following modes.

A system for supplying power to a mining machine,
It is equipped with a solar power generation device, a storage battery, and a control device,
The control device includes a remaining amount acquisition unit, a power generation information acquisition unit, a threshold value determination unit, and an instruction transmission unit,
The remaining amount acquisition unit is configured to be able to acquire the battery remaining amount of the storage battery,
The power generation information acquisition unit is configured to be able to acquire at least one of power generation amount of the solar power generation device and estimation information for estimating the power generation amount of the solar power generation device as power generation information,
The threshold value determination unit is configured to be able to determine a first threshold value and a second threshold value based on the power generation information,
The instruction sending unit is configured to be able to send an instruction to use the power generated by the solar power generation device when the battery remaining amount becomes larger than the first threshold value, and the battery remaining amount is When it is smaller than the second threshold value, it is configured to be able to send an instruction not to use the power generated by the photovoltaic power generation device,
system.

A program that causes a computer to function as a control device that controls electric power supplied to a mining machine from a power supply including a solar power generation device and a storage battery,
The control device includes a remaining amount acquisition unit, a power generation information acquisition unit, a threshold value determination unit, and an instruction transmission unit,
The remaining amount acquisition unit is configured to be able to acquire the battery remaining amount of the storage battery,
The power generation information acquisition unit is configured to be able to acquire at least one of power generation amount of the solar power generation device and estimation information for estimating the power generation amount of the solar power generation device as power generation information,
The threshold value determination unit is configured to be able to determine a first threshold value and a second threshold value based on the power generation information,
The instruction sending unit is configured to be able to send an instruction to use the power generated by the solar power generation device when the battery remaining amount becomes larger than the first threshold value, and the battery remaining amount is When it is smaller than the second threshold value, it is configured to be able to send an instruction not to use the power generated by the photovoltaic power generation device,
program.

Further, it may be provided as a computer-readable non-transitory recording medium that stores the above program.

1: Control device 11: Power generation information acquisition unit 12: Remaining amount acquisition unit 13: Threshold value determination unit 14: Instruction transmission unit 15: Clock 2: Power supply 21: Photovoltaic power generation device 22: Storage battery 23: Switching device 3: Mining machine 3 -1: Mining machine 3-2: Mining machine 3-n: Mining machine 4: Meteorological observation device 5: Meteorological information distribution service 6: Management device 7: Measuring device 8: Base 101: System 102: System 103: System 104: System NT: Network α: Electric energy β: Electric energy

Claims (11)

A control device for controlling electric power supplied to a mining machine from a power source including a solar power generation device and a storage battery,
A remaining amount acquisition unit, a power generation information acquisition unit, a threshold value determination unit, and an instruction transmission unit,
The remaining amount acquisition unit is configured to be able to acquire the battery remaining amount of the storage battery,
The power generation information acquisition unit is configured to be able to acquire at least one of power generation amount of the solar power generation device and estimation information for estimating the power generation amount of the solar power generation device as power generation information,
The threshold value determination unit is configured to be able to determine a first threshold value and a second threshold value based on the power generation information,
The instruction sending unit is configured to be able to send an instruction to use the power generated by the solar power generation device when the battery remaining amount becomes larger than the first threshold value, and the battery remaining amount is When it is smaller than the second threshold value, it is configured to be able to send an instruction not to use the power generated by the photovoltaic power generation device,
Control device. The power supply further comprises a switching device that switches the power supplied to the mining machine between the power stored in the storage battery and the power supplied from a commercial power supply,
The instruction sending unit is configured to be able to send an instruction to switch the power supply source from a commercial power source to a storage battery to the switching device when the remaining battery capacity becomes larger than the first threshold value, and the battery The control device according to claim 1, wherein an instruction to switch a power supply source from a storage battery to a commercial power source can be sent to the switching device when the remaining amount becomes smaller than the second threshold value. The instruction sending unit is configured to be able to send an instruction to turn on the power to the mining machine when the remaining battery level is larger than the first threshold value, and the remaining battery level is the second battery level. It is configured to be able to send a power-off instruction to the mining machine when it becomes smaller than a threshold value,
The control device according to claim 1. The estimated information is time,
The control device according to claim 1. The estimated information is weather information,
The control device according to claim 1. The instruction sending unit sends the throwing instruction and the cutting instruction to a management device that manages the mining machine,
The control device according to any one of claims 3 to 5. The instruction sending unit is connected to the mining machine via a network, and sends the input instruction and the disconnection instruction via the network.
The control device according to any one of claims 3 to 5. The remaining amount acquisition unit measures and acquires the remaining battery amount of the storage battery,
The control device according to any one of claims 1 to 7. The remaining amount acquisition unit acquires from a measuring device that measures the remaining battery amount of the storage battery,
The control device according to any one of claims 1 to 7. A system for supplying power to a mining machine,
It is equipped with a solar power generation device, a storage battery, and a control device,
The control device includes a remaining amount acquisition unit, a power generation information acquisition unit, a threshold value determination unit, and an instruction transmission unit,
The remaining amount acquisition unit is configured to be able to acquire the battery remaining amount of the storage battery,
The power generation information acquisition unit is configured to be able to acquire at least one of power generation amount of the solar power generation device and estimation information for estimating the power generation amount of the solar power generation device as power generation information,
The threshold value determination unit is configured to be able to determine a first threshold value and a second threshold value based on the power generation information,
The instruction sending unit is configured to be able to send an instruction to use the power generated by the solar power generation device when the battery remaining amount becomes larger than the first threshold value, and the battery remaining amount is When it is smaller than the second threshold value, it is configured to be able to send an instruction not to use the power generated by the photovoltaic power generation device,
system A program that causes a computer to function as a control device that controls electric power supplied to a mining machine from a power supply including a solar power generation device and a storage battery,
The control device includes a remaining amount acquisition unit, a power generation information acquisition unit, a threshold value determination unit, and an instruction transmission unit,
The remaining amount acquisition unit is configured to be able to acquire the battery remaining amount of the storage battery,
The power generation information acquisition unit is configured to be able to acquire at least one of power generation amount of the solar power generation device and estimation information for estimating the power generation amount of the solar power generation device as power generation information,
The threshold value determination unit is configured to be able to determine a first threshold value and a second threshold value based on the power generation information,
The instruction sending unit is configured to be able to send an instruction to use the power generated by the solar power generation device when the battery remaining amount becomes larger than the first threshold value, and the battery remaining amount is When it is smaller than the second threshold value, it is configured to be able to send an instruction not to use the power generated by the photovoltaic power generation device,
program.