JP2019080394A - Power supply system - Google Patents

Abstract

To provide a power supply system in which, when a power source is supplied from a storage battery to a load, reduction in the time for supplying the power source can be suppressed.SOLUTION: A power supply system 1 includes a storage battery 11, a main circuit 13 on which a voltage conversion device 12 capable of changing the voltage of a power source supplied from the storage battery is disposed, a bypass circuit 14 capable of supplying a power source of the storage battery to a load not via the voltage conversion device, and a controller 15 capable of selecting a path through which the power source of the storage battery is supplied to the load, wherein, when the output voltage of the storage battery falls within a predetermined voltage, the controller selects the path such that the power source of the storage battery is supplied to the load via the bypass circuit.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power supply system.

  As described in Patent Document 1, it is known to perform power supply from a storage battery to a load through a voltage conversion device such as a converter. For example, when supplying the surplus of solar light to the storage battery and supplying the power energy stored in the storage battery to the load at night or during a power failure, the energy stored in the storage battery is suitable for the load by the voltage conversion device Convert to voltage.

JP, 2013-247780, A

  The voltage conversion device internally includes a step-down circuit and a step-up circuit. When electricity passes through the coils in these circuits, energy is lost due to the resistance value of the coils and the like. Such energy loss occurs even without step-down or step-up. That is, when power is supplied to the load via the voltage conversion device, energy is lost regardless of whether or not voltage conversion is performed. Therefore, the energy consumption of the storage battery is greater than the load usage. As a result, the possibility of a power failure is high.

  The inventor of the present case tried to solve the problem by earnestly examining this point. An object of the present invention is to provide a power supply system capable of suppressing a decrease in supply time of power when supplying power from a storage battery to a load.

  In order to solve the above problems, it is possible to supply the storage battery power to the load without passing through the storage battery and the voltage conversion device capable of changing the voltage of the power supply supplied from the storage battery. The controller includes: a bypass circuit; and a controller capable of selecting a path through which the power of the storage battery is supplied to the load, wherein the controller supplies the power of the storage battery to the load through the bypass circuit if the output voltage of the storage battery is within a predetermined voltage. Power supply system to select the route as

  Preferably, the primary circuit switch is provided on the primary side of the voltage conversion device, and the controller controls the main circuit switch to turn off if the output voltage of the storage battery is within a predetermined voltage.

  Preferably, the controller is configured to control to shut off both the main circuit and the bypass circuit when the output voltage of the storage battery is lower than a predetermined voltage.

  Further, the controller is preferably configured to control to shut off both the main circuit and the bypass circuit during a time zone in which the operation of the load is unnecessary.

  Moreover, it is preferable to set it as the structure provided with the setting part which sets at least one of a predetermined voltage and discharge termination voltage in a controller.

  In the present invention, when power is supplied from the storage battery to the load, the generation of energy loss by the voltage conversion device can be suppressed, and the power supply time of the storage battery can be extended. Therefore, it becomes possible to set it as the power supply system which can prevent that the power supply to a load stops.

In the power supply system in an embodiment, it is a figure showing the state where the main circuit switch is OFF and the bypass circuit is ON. In addition, the situation of the main part in this state is described in the table. However, this is in the case where the load allowable voltage is 11V to 13V. It is a block diagram showing the structure of a controller. The power supply system in embodiment WHEREIN: The output voltage of a storage battery is a figure showing the state a little smaller than load allowable voltage. In addition, the situation of the main part in this state is described in the table. However, this is in the case where the load allowable voltage is 11V to 13V. The power supply system in embodiment WHEREIN: The output voltage of a storage battery is a figure showing the state larger than load allowable voltage. In addition, the situation of the main part in this state is described in the table. However, this is in the case where the load allowable voltage is 11V to 13V. The power supply system in embodiment WHEREIN: The output voltage of a storage battery is the figure showing the state below the discharge termination voltage. In addition, the situation of the main part in this state is described in the table. However, this is in the case where the load allowable voltage is 11V to 13V.

  Hereinafter, modes for carrying out the invention will be described. As understood from what is shown in FIG. 1 and FIG. 2, in the power supply system 1 of the present embodiment, the storage battery 11 and the voltage conversion device 12 capable of changing the voltage of the power supply supplied from the storage battery 11 are A controller capable of selecting a path through which the power supply of the storage battery 11 is supplied to the load 2 and a bypass circuit 14 capable of supplying the power supply of the storage battery 11 to the load 2 without passing through the voltage conversion device 12 It has 15 and. Further, when the output voltage of the storage battery 11 is within the predetermined voltage, the controller 15 selects a path such that the power supply of the storage battery 11 is supplied to the load 2 through the bypass circuit 14. Therefore, when supplying power from the storage battery 11 to the load 2, the power supply time can be extended, and the power supply to the load 2 can be prevented from being stopped. It becomes possible.

  The power supply system 1 of the embodiment is for discharging from the storage battery 11 at night or at the time of commercial power failure and supplying power to a load 2 such as an LED light, a surveillance camera, a broadcast system and the like. In the embodiment, the power supplied from the solar cell 3 is supplied to the storage battery 11 and the load 2. For this reason, the first voltage conversion device 12 which adjusts to the voltage which load 2 accepts, and the 2nd voltage conversion device 18 which adjusts to the voltage which storage battery 11 accepts are provided. The first voltage conversion device 12 is disposed between the storage battery 11 and the load 2, and the second voltage conversion device 18 is disposed between the storage battery 11 and the solar cell 3.

  The second voltage conversion device 18 may be anything that converts the commercial power source or the solar battery 3 into an appropriate voltage to charge the storage battery 11, and an AC / DC converter or a DC / DC converter may be used. . In the present embodiment, a power supply system 1 using a solar cell 3 will be described.

  In the embodiment, the first voltage conversion device 12 is a DC / DC converter, and the power supply from the solar cell 3 through the second voltage conversion device 18 or the power supply from the storage battery 11 is suitable for the load 2 Convert to a stable voltage. In addition, the storage battery 11 has a fluctuation | variation of an output voltage by use time or temperature rise.

  In the embodiment, since the power supply to the first voltage conversion device 12 can be performed as needed, the first voltage conversion device 12 is added to the main circuit 13 including the first voltage conversion device 12. The bypass circuit 14 creates a route for supplying power from the storage battery 11 to the load 2 without passing through. Further, the main circuit 13 is provided with a main circuit switch 16 capable of switching on and off, and the bypass circuit 14 is also provided with a bypass switch 17 capable of switching on and off. The main circuit switch 16 and the bypass switch 17 are operated by the controller 15. The controller 15 of the embodiment measures the voltage between the storage battery 11 and the first voltage conversion device 12 with the storage battery voltage detection unit 33. The control unit 34 having received the measurement result determines whether to turn on or off both the main circuit switch 16 and the bypass switch 17. According to the contents determined by the control unit 34, an output is made from the output unit 38 toward the main circuit switch 16 and the bypass switch 17.

  Here, a specific operation will be described by way of example in which the output voltage of the storage battery 11 is 11 to 13 V as the load allowable voltage (predetermined voltage). As shown in FIG. 1, if the voltage value measured by the controller 15 as the output voltage of the storage battery 11 is 11 to 13 V, in order to send power to the load 2 without passing through the first voltage conversion device 12, the main The circuit switch 16 is turned off and the bypass switch 17 is turned on. In this way, energy loss due to passing through the voltage conversion device can be prevented.

  Further, as shown in FIG. 3, if the voltage value measured by the controller 15 as the output voltage of the storage battery 11 is 10 to 10.9 V, the voltage is boosted by the first voltage conversion device 12 and then the power is sent to the load 2 The main circuit switch 16 is turned on and the bypass switch 17 is turned off.

  In addition, as shown in FIG. 4, if the voltage value measured by the controller 15 is 13.1 V or more as the output voltage of the storage battery 11, the voltage is reduced by the first voltage conversion device 12 and then the power is sent to the load 2. Therefore, the main circuit switch 16 is turned on and the bypass switch 17 is turned off. In addition, the storage battery 11 of the rated voltage corresponding to the inside of load allowable voltage is normally used for the storage battery 11. As the storage time of the storage battery 11 increases, the output voltage decreases. That is, at first, the power supply from the storage battery 11 is sent to the load 2 via the bypass circuit 14, but if the usage time becomes longer and the load voltage becomes lower than that, the first voltage converter 12 boosts it and supplies the load 2 Therefore, no energy loss occurs because the power is sent to the load without passing through the first voltage conversion device 12 within the load allowable voltage, and the operating time of the storage battery 11 within the load allowable voltage can be extended. It is possible.

  Here, the charging voltage from the second voltage conversion device 18 to the storage battery 11 is set higher than the storage battery rated voltage. Therefore, when the output from the second voltage conversion device 18 is sent to the load as it is, the voltage is equal to or higher than the load allowable voltage, and thus the first voltage conversion device 12 steps down and sends power to the load 2. When the storage battery 11 uses a rated voltage higher than the allowable load voltage, the first voltage conversion device 12 first reduces the voltage and sends power to the load 2.

  By the way, if the storage battery 11 continues to be used at a voltage value lower than a certain level, the life is reduced. This voltage is called a discharge termination voltage. For this reason, it is preferable that the controller 15 performs control so as to shut off both paths of the main circuit 13 and the bypass circuit 14 when the output voltage of the storage battery 11 is equal to or less than a predetermined voltage. In this way, it is not necessary to separately provide a monitor for the discharge end voltage. In the embodiment, the controller 15 monitors the discharge termination voltage and shuts off the main circuit 13 and the bypass circuit 14. Therefore, as shown in FIG. 5, if the voltage value measured by the controller 15 as the output voltage of the storage battery 11 is 9.9 V or less, the main circuit switch 16 is turned off in order to shut off the path for supplying power to the load 2. At the same time, the bypass switch 17 is turned off.

  Further, it is preferable that the controller 15 be provided with a setting unit 37 that sets at least one of the predetermined voltage and the discharge termination voltage. More specifically, the controller 15 preferably includes a setting unit 37 that sets at least one of the allowable voltage of the load 2 and the discharge termination voltage. Thus, it is possible to freely set a predetermined voltage such as the allowable voltage of load 2 or the discharge termination voltage of storage battery 11. The controller 15 of the embodiment is provided with a setting unit 37 capable of manually setting the allowable voltage. The controller 15 compares the output voltage of the storage battery 11 with the control unit 34 based on the value of the set allowable voltage. In addition, the controller 15 according to the embodiment includes the input unit 36 connectable to the outside, and can reflect the information input to the input unit 36 in the setting unit 37. The allowable voltage may be automatically set by using the input unit 36 or the like. In this case, for example, ± 10% of the rating may be used as an allowable voltage, and automatic setting may be performed on this. In the present embodiment, although the load 2 has been described as having a load allowable voltage of 11 to 13 V, the present invention is not limited to the load which is the load allowable voltage.

  The main circuit switch 16 is provided on the primary side of the voltage conversion device 12, and the controller 15 is controlled to turn off the main circuit switch 16 if the output voltage of the storage battery 11 is within the load allowable voltage. Is preferred. This is because the energy consumed by the voltage conversion device 12 is suppressed when the main circuit switch 16 is turned off as compared with the case where the main circuit switch 16 is disposed on the secondary side of the voltage conversion device 12.

  Further, it is preferable that the controller 15 performs control to shut off both paths of the main circuit 13 and the bypass circuit 14 in a time zone in which the operation of the load 2 is unnecessary. By monitoring the time when the operation of the load 2 is unnecessary by timer setting, unnecessary use of the storage battery 11 can be suppressed. In the embodiment, the timer unit 35 is provided, and the setting of the timer unit 35 manages the time when the operation of the load 2 is unnecessary. In addition, since the main circuit switch 16 is formed on the primary side of the first voltage conversion device 12, power is not supplied to the first voltage conversion device 12 at a time when the operation of the load 2 is unnecessary. Is prevented from occurring.

  The controller 15 includes a power supply unit 32 that receives power from the solar battery 3 and the storage battery 11. The power supply unit 32 supplies power to the control unit 34. In addition, the battery unit 31 is connected to the power supply unit 32, and even when power can not be supplied from the solar cell 3 or the storage battery 11, the power supply can be temporarily supplied to the control unit 34. There is.

  The present invention has been described above by taking the embodiment as an example, but the present invention is not limited to the above embodiment, and various aspects can be made. For example, it is also possible to operate the storage battery voltage detection unit even when the storage battery is not used, and to allow the bypass circuit to pass electricity when the load allowable voltage is reached.

DESCRIPTION OF SYMBOLS 1 power supply system 2 load 11 storage battery 13 main circuit 14 bypass circuit 15 controller 16 main circuit switch

Claims (5)

  A storage battery, a main circuit in which a voltage conversion device capable of changing a voltage of a power supply supplied from the storage battery is disposed, a bypass circuit capable of supplying power of the storage battery to a load without passing through the voltage conversion device, a power supply of the storage battery A controller capable of selecting a path to be supplied to the load, wherein the controller selects the path so that the battery power is supplied to the load through the bypass circuit if the output voltage of the storage battery is within a predetermined voltage Power supply system.   The power supply system according to claim 1, further comprising a main circuit switch on the primary side of the voltage conversion device, and controlling the controller to turn off the main circuit switch if the output voltage of the storage battery is within a predetermined voltage.   The power supply system according to claim 1 or 2, wherein the controller controls to shut off both paths of the main circuit and the bypass circuit when the output voltage of the storage battery is lower than a predetermined voltage.   The power supply system according to any one of claims 1 to 3, wherein the controller performs control to shut off both paths of the main circuit and the bypass circuit in a time zone in which the operation of the load is unnecessary.   The power supply system according to any one of claims 1 to 4, further comprising a setting unit configured to set at least one of a predetermined voltage and a discharge termination voltage in the controller.