JP2010028950A - Emergency power generating system and emergency power generating apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide emergency power generating system/apparatus, which is easily and speedily started, even if power of a commercial power supply is cut. <P>SOLUTION: The power generating apparatus includes a power generating part 7 generating emergency power, an energy storage part 8 supplying power for making the power generating part 7 in a standby state, a charging part 9 accumulating power in the energy storage part 8, a charging instruction monitoring part 6 monitoring a charging instruction to the energy storage part 8 and a switching part 4 which selectively switches connection with loads Z1, Z2, Z3, ..., Zn to the commercial power supply or the power generating part 7. Terminals on sides of the loads Z1, Z2, Z3, ..., Zn in the switching part 4 are connected to the charging part 9. When the charging instruction monitoring part 6 receives the charging instruction while the power generating part 7 is connected to the loads Z1, Z2, Z3, ..., Zn through the switching part 4, it starts the power generating part 7 and supplies emergency power from the power generating part 7 to the charging part 9. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an emergency power generation system and an emergency power generation apparatus that supply emergency power in an emergency.

Conventionally, when a power failure occurs in a commercial power supply, various emergency power generation systems that automatically switch from the commercial power supply and supply emergency power to a load have been used (see, for example, Patent Document 1). .
Here, for example, depending on the load, there is a thing that does not require power supply at the same time as a power failure, such as a pump in a wastewater treatment plant or an unmanned indoor lighting fixture. When supplying power for such a load at the time of a power failure, the operator manually starts the generator only when power supply is necessary in order to suppress power consumption of the fuel and battery of the generator, The power generated by this generator is supplied to a load.
JP 2004-64975 A

  However, even if the generator is manually started at the time of a power failure as described above, it is necessary to keep the generator in a standby state in order to start the generator. Standby current flows from the battery to the generator, thereby consuming battery power. Therefore, when power supply to the load becomes necessary at the time of a power failure, there is a problem that the power of the battery is insufficient and the generator cannot be started.

  The present invention has been made in view of such circumstances, and provides an emergency power generation system and an emergency power generation apparatus that can be easily and quickly started even when a commercial power supply is interrupted. With the goal.

In order to solve the above problems, the present invention provides the following means.
The present invention is a manually activated emergency power generation system that supplies emergency power to a load as needed in an emergency, and includes a power generation unit that generates the emergency power, and the power generation unit in a standby state. A power storage unit that supplies power for power storage, a charging unit that stores power in the power storage unit, a charging instruction monitoring unit that monitors a charging instruction to the power storage unit, and a connection between the load and a commercial power source or the A switching unit that can be selectively switched to the power generation unit, a load-side terminal of the switching unit and the charging unit are connected, and the charging instruction monitoring unit is configured to pass through the switching unit. When the charging instruction is received in a state where the power generation unit and the load are connected, the power generation unit is activated to supply emergency power from the power generation unit to the charging unit.

  According to the present invention, electric power can be stored in the power storage unit via the charging unit even during a power failure.

  Further, the present invention is characterized in that the charging instruction is an output from a power detection unit that monitors a lower limit value of power of the power storage unit.

  According to the present invention, even during a power failure, the power generation unit is automatically activated in accordance with a charging instruction from the power detection unit, whereby electric power can be stored in the power storage unit via the charging unit.

  Further, the present invention is characterized in that the charging instruction is an output from a timer that outputs a signal at a preset time interval.

  According to the present invention, even when a power failure occurs, electric power can be stored in the power storage unit via the charging unit by automatically starting the power generation unit in response to a charging instruction from the timer.

  Further, the present invention is characterized in that the charging instruction is input from an input unit by an operator.

  According to the present invention, even during a power failure, the power generation unit is automatically activated in accordance with a charging instruction input by an operator, whereby electric power can be stored in the power storage unit via the charging unit. .

  In addition, the present invention is a manually activated emergency power generation device that supplies emergency power to a load as needed in an emergency, and includes a power generation unit that generates the emergency power, and a standby for the power generation unit A power storage unit that supplies power for switching to a state; a charging unit that stores power in the power storage unit; and a charging instruction monitoring unit that monitors a charging instruction to the power storage unit, and connection to the load, The charging unit is connected to a load side terminal of a switching unit that can be selectively switched to a commercial power source or the power generation unit, and the charging instruction monitoring unit is connected via the switching unit. When the charging instruction is received in a state where the power generation unit and the load are connected, the power generation unit is activated to supply emergency power from the power generation unit to the charging unit.

  According to the present invention, electric power can be stored in the power storage unit via the charging unit even during a power failure.

  According to the present invention, by starting the power generation unit, it is possible to store electric power in the power storage unit via the charging unit. Therefore, it is possible to start up easily and quickly even when the commercial power supply is out of power.

(Embodiment 1)
Hereinafter, an emergency power generation system according to a first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows an emergency power generation system as a first embodiment of the present invention.
The emergency power generation system 1 is connected to a power system that supplies power from the commercial power source 2 to the loads Z1, Z2, Z3... Zn, and is used for emergency power in the event of a power failure of the commercial power source 2. Is provided.
The loads Z1, Z2, Z3... Zn do not necessarily require emergency power simultaneously with the power failure of the commercial power supply 2.
The emergency power generator 5 includes a control unit (charge monitoring unit) 6 that controls the overall operation.
The control unit 6 monitors a charging instruction to be described later. The control unit 6 is connected to a power generation unit 7 that generates emergency power, an input unit 11 that outputs a signal such as an activation signal, and a storage unit 12 that stores various types of information.

The power generation unit 7 includes a generator (not shown) driven by fuel such as kerosene or light oil. The power generation unit 7 is connected to a battery (power storage unit) 8. The battery 8 supplies the power generation unit 7 with power (standby current) for setting the power generation unit 7 in a standby state. The battery 8 is connected to the charging unit 9. The charging unit 9 stores power in the battery 8. Further, the battery 8 is connected to a battery power detection unit (power detection unit) 10 that detects the power stored in the battery 8.
The battery power detection unit 10 is connected to the control unit 6, and outputs the detection result of the power stored in the battery 8 to the control unit 6 as a detection signal (charging instruction).

  The input unit 11 is for an operator to input a charging instruction, and includes, for example, a start button, a stop button, and an input button. When the start button is pressed by the operator, the input unit 11 outputs a start signal (charging instruction) to the control unit 6, whereby the control unit 6 starts the power generation unit 7. That is, the power generation unit 7 is manually activated by an operator's operation. Further, when the stop button is pressed by the operator, the input unit 11 outputs a stop signal to the control unit 6, whereby the control unit 6 stops the activated power generation unit 7. Further, when the input button is pressed by the operator, the input unit 11 outputs a threshold signal indicating an upper limit threshold or a lower limit threshold of the stored power of the battery 8 to the control unit 6. The unit 12 stores an upper limit threshold and a lower limit threshold.

The emergency power generation system 1 includes a commercial power detection unit 3 that detects the power of the commercial power source 2 and a changeover switch (switching unit) that can selectively switch the connection to the loads Z1, Z2, Z3,. 4).
In the changeover switch 4, the commercial power source 2 and the power generation unit 7 are connected to the switch connection units 4 a and 4 b that can be switched. Further, loads Z1, Z2, Z3,... Zn are connected in parallel to the non-switchable fixed connection portion 4c. Furthermore, the fixed connection part 4c is connected to the charging part 9 via the load Z1.

Moreover, the commercial power detection unit 3 includes a storage unit (not shown) in which a threshold value at the time of power failure determination of the commercial power source 2 is stored. Then, when the detection result of the power of the commercial power source 2 becomes smaller than the threshold value stored in the storage unit (not shown), the commercial power detection unit 3 determines that there is a power failure, and loads Z1, Z2 via the changeover switch 4. , Z3... Zn is switched from the commercial power source 2 to the emergency power generator 5. That is, the commercial power detection unit 3 connects the switching connection unit 4b and the fixed connection unit 4c. Further, the commercial power detection unit 3 is connected to the control unit 6, and outputs a power failure signal to the control unit 6 when the commercial power source 2 fails.
Furthermore, when the detection result becomes larger than the threshold value after the power failure, the commercial power detection unit 3 determines that the power failure has been canceled, switches the changeover switch 4, and outputs a power failure cancellation signal to the control unit 6.

Next, the operation of the emergency power generation system 1 in the present embodiment configured as described above will be described.
Normally, the switching connection portion 4a and the fixed connection portion 4c are connected, and commercial power is supplied from the commercial power source 2 to the loads Z1, Z2, Z3,. In this case, a part of the commercial power is supplied to the charging unit 9 via the load Z1. Therefore, at any time, the charging unit 9 can supply power to the battery 8, and the stored power of the battery 8 does not become insufficient. Moreover, the electric power of the battery 8 is supplied to the power generation unit 7, and the power generation unit 7 is in a standby state.

On the other hand, at the time of a power failure of the commercial power source 2, the changeover switch 4 is switched. When the operator presses the start button of the input unit 11 when emergency power is required, the input unit 11 outputs a start signal to the control unit 6. The control unit 6 activates the power generation unit 7. And the emergency electric power from the electric power generation part 7 is supplied to load Z1, Z2, Z3 ... Zn. Further, a part of the emergency power is supplied to the charging unit 9 through the load Z1, whereby the battery 8 stores the power.
And when emergency electric power becomes unnecessary, when the operator presses the stop button of the input unit 11, the input unit 11 outputs a stop signal to the control unit 6, and the control unit 6 stops the power generation unit 7. .

Here, in a state where the power generation unit 7 is not activated at the time of a power failure, the supply of power to the charging unit 9 is stopped, so that power is not stored in the battery 8, and thus the power generation unit 7 is put into a standby state. In this case, the stored power of the battery 8 is consumed and reduced. As a result, when the power generation unit 7 needs to be activated, the stored power of the battery 8 does not remain, and the power generation unit 7 may not be activated.
In the emergency power generation system 1 in the present embodiment, electric power is stored in the battery 8 in the following manner at the time of a power failure.

FIG. 2 is a flowchart showing the operation of the emergency power generation system 1 at the time of a power failure of the commercial power supply 2.
The commercial power detection unit 3 determines whether the commercial power source 2 has failed. That is, the commercial power detection unit 3 detects power from the commercial power source 2 and compares the detection result with a threshold value stored in a storage unit (not shown). When the commercial power detection unit 3 determines that the detection result is greater than the threshold (step S1; NO), the commercial power detection unit 3 detects the power from the commercial power source 2 again, and repeats the process of step S1. Thereby, the commercial power detection unit 3 monitors whether the commercial power source 2 has failed.

On the other hand, when the commercial power detection unit 3 determines that the detection result is smaller than the threshold (step S1; YES), the commercial power detection unit 3 switches the changeover switch 4 (step S2). That is, the commercial power detection unit 3 connects the switching connection unit 4b and the fixed connection unit 4c. Thereby, the emergency power generator 5 and the loads Z1, Z2, Z3,... Zn are connected.
Furthermore, the commercial power detection unit 3 outputs a power failure signal to the control unit 6 (step S3).
The control part 6 will read the output of the battery electric power detection part 10, if a power failure signal is received. And the control part 6 will compare with the detection result of the battery power detection part 10, and the lower limit threshold value memorize | stored beforehand by the memory | storage part 12, and will determine with a detection result being larger than a lower limit threshold value (step S4; NO) The standby state of the power generation unit 7 is continued (step S5).

On the other hand, if the control part 6 determines with a detection result being smaller than a lower limit threshold value (step S4; YES), the electric power generation part 7 will be started automatically (step S6). As a result, emergency power from the power generation unit 7 is supplied to the charging unit 9 via the load Z <b> 1, and the power is stored in the battery 8.
Furthermore, when the control unit 6 reads the output of the battery power detection unit 10 and determines that the detection result is smaller than the upper limit threshold stored in advance in the storage unit 12 (step S7; NO), the control unit 6 The output is read again and the process of step S7 is repeated. On the other hand, if the control part 6 determines with a detection result being larger than an upper limit threshold value (step S7; YES), it will stop the electric power generation part 7 (step S8).

Next, when the commercial power detection unit 3 compares the detection result with the threshold value and determines that the detection result is smaller than the threshold value (step S9; NO), the commercial power detection unit 3 does not output the power failure cancellation signal. 1 repeats the processing from step S4 to step S9.
On the other hand, when the commercial power detection unit 3 determines that the detection result is larger than the threshold (step S9; YES), the commercial power detection unit 3 switches the changeover switch 4 (step S10) and outputs a power failure cancellation signal to the control unit 6 (step S11). ). Thereby, the control part 6 stops the repetition of the process of step S4 to step S8, and the process of the emergency power generation system 1 is complete | finished.

As described above, according to the emergency power generation system 1 in the present embodiment, electric power can be stored in the battery 8 via the charging unit 9 by manually starting the power generation unit 7 even during a power failure. Therefore, even when the commercial power source 2 is out of power, the power generation unit 7 can be started up easily and quickly.
In addition, even during a power failure, power can be stored in the battery 8 via the charging unit 9 by automatically starting the power generation unit 7 according to the detection result of the battery power detection unit 10.

(Embodiment 2)
Next, a second embodiment of the present invention will be described.
3 and 4 show a second embodiment of the present invention.
3 and 4, the same parts as those shown in FIGS. 1 and 2 are denoted by the same reference numerals, and the description thereof is omitted.
This embodiment and the first embodiment have the same basic configuration, and different points will be mainly described here.

The emergency power generator 5a in the present embodiment is provided with a timer 15 instead of the battery power detection unit 10 of the first embodiment. The timer 15 is connected to the control unit 6a and starts timing in response to a timing start signal from the control unit 6a. When a predetermined time elapses, the timer 15 sends a timing end signal (charging instruction) to the control unit 6a. Output.
When the control unit 6a receives the time measurement end signal from the timer 15, the control unit 6a activates the power generation unit 7.
The time measured by the timer 15 is set to an arbitrary time input in advance by the operator via the input unit 11. When the timer 15 starts measuring time, the timer 15 periodically outputs a time measuring end signal at an arbitrary time interval set in advance.

FIG. 4 is a flowchart showing the operation of the emergency power generation system 1a at the time of a power failure of the commercial power source 2.
When receiving the power failure signal from the commercial power detection unit 3, the control unit 6a outputs a time measurement start signal and starts the timer 15 (step S20).
When the timer 15 receives a timing start signal from the control unit 6a, the timer 15 starts timing, and outputs a timing end signal to the control unit 6a when a preset time has elapsed. When the control unit 6a reads the output of the timer 15 and determines that the time measurement end signal is not output (step S21; NO), the control unit 6a reads the output of the timer 15 again and repeats the process of step S21.
On the other hand, if it determines with the control part 6a having output the time measurement end signal from the timer 15 (step S22; YES), the electric power generation part 7 will be started (step S22).

  And the control part 6a stops the electric power generation part 7 after predetermined time progress, after starting the electric power generation part 7 (step S23). Here, it is possible to estimate in advance how much the stored power of the battery 8 is reduced according to the time interval set in the timer 15, so it is also possible to estimate in advance the time during which the reduced power is stored. it can. Therefore, the startup time estimated from the startup of the power generation unit 7 to the stop thereof is input by the operator via the input unit 11 and stored in the storage unit 12. That is, after starting the power generation unit 7, the control unit 6 a stops the power generation unit 7 after the startup time stored in advance in the storage unit 12 has elapsed.

When the commercial power detection unit 3 compares the detection result with the threshold value and determines that the detection result is smaller than the threshold value (step S9; NO), the commercial power detection unit 3 does not output the power failure cancellation signal. 1a repeats the processing from step S21 to step S9. That is, when the timer 15 receives the timing start signal, the timer 15 continuously outputs a timing end signal at a preset time interval, so that the power generation unit 7 is activated at a preset time interval during a power failure.
And the control part 6a will stop the timer 15, if the power failure cancellation | release signal from the commercial power detection part 3 is received (step S24), and, thereby, the process of the emergency power generation system 1a is complete | finished.

  As described above, according to the emergency power generation system 1 in the present embodiment, the operator can periodically start the power generation unit 7 at a predetermined time interval, so the operator can specify the time interval according to the situation. By doing, the electric power generation part 7 can be started rapidly and reliably.

In the present embodiment, it is assumed that the activation time from when the control unit 6a activates the power generation unit 7 to when it is stopped is input in advance. However, the present invention is not limited to this, and is based on the time interval set in the timer 15. Then, the control unit 6a may calculate the activation time and store it in the storage unit 12.
A battery power detection unit 10 may be provided. Thereby, after starting the electric power generation part 7, when the detection result of the battery power detection part 10 becomes larger than the preset threshold value, the control part 6a may be made to stop the electric power generation part 7.
The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.

1 is a system configuration diagram showing a first embodiment of an emergency power generation system according to the present invention. It is a flowchart which shows operation | movement of the emergency power generation system of FIG. It is a system configuration figure showing a 2nd embodiment of an emergency power generation system concerning the present invention. It is a flowchart which shows operation | movement of the emergency power generation system of FIG.

Explanation of symbols

1, 1a Emergency power generation system 2 Commercial power supply 4 Changeover switch (switching part)
5, 5a Emergency power generator 6, 6a Control unit (charging instruction monitoring unit)
7 Power generation unit 8 Battery (power storage unit)
9 Charging unit 10 Battery power detection unit (power detection unit)
11 Input unit 15 Timer

Claims (5)

A manually activated emergency power generation system that supplies emergency power to the load as needed during an emergency.
A power generation section for generating the emergency power;
A power storage unit for supplying electric power for placing the power generation unit in a standby state;
A charging unit for storing electric power in the power storage unit;
A charge instruction monitoring unit for monitoring a charge instruction to the power storage unit;
A switching unit that can selectively switch the connection with the load to a commercial power source or the power generation unit,
The terminal on the load side of the switching unit and the charging unit are connected,
The charging instruction monitoring unit
When the charging instruction is received in a state where the power generation unit and the load are connected via the switching unit, the power generation unit is activated to supply emergency power from the power generation unit to the charging unit. An emergency power generation system characterized by that.   The emergency power generation system according to claim 1, wherein the charging instruction is an output from a power detection unit that monitors a lower limit value of the power of the power storage unit.   The emergency power generation system according to claim 1, wherein the charging instruction is an output from a timer that outputs a signal at a preset time interval.   The emergency power generation system according to any one of claims 1 to 3, wherein the charging instruction is input from an input unit by an operator. It is a manually activated emergency power generator that supplies emergency power to the load as needed during an emergency.
A power generation section for generating the emergency power;
A power storage unit for supplying electric power for placing the power generation unit in a standby state;
A charging unit for storing electric power in the power storage unit;
A charging instruction monitoring unit that monitors a charging instruction to the power storage unit,
The connection with the load is connected to a terminal on the load side of the switching unit that can be selectively switched to a commercial power source or the power generation unit, and the charging unit,
The charging instruction monitoring unit
When the charging instruction is received in a state where the power generation unit and the load are connected via the switching unit, the power generation unit is activated to supply emergency power from the power generation unit to the charging unit. An emergency power generator characterized by that.

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