JP6335665B2 - Power storage system - Google Patents

Description

  The present invention relates to a power storage system including a connected or separated power conditioner and a storage battery unit.

  Generally, a power storage system having a power storage function performs AC / DC power conversion that converts AC power supplied from a power system into DC power at night when power demand is low. Then, the power storage system charges the storage battery built in the power storage system using the DC power. The power storage system performs DC / AC power conversion for converting DC power charged in the storage battery into AC power during the daytime when power demand is high. And the electrical storage system returns the said alternating current power to the electric power system of a house via the switchboard in a house. As a result, power supply and demand are leveled.

  In some conventional power storage systems, an integrated power conditioner and a storage battery unit (storage battery) are configured to be separable. The power conditioner has a function of performing DC / AC power conversion and AC / DC power conversion. The storage battery is, for example, a lithium ion battery. The storage battery unit is a unit for controlling the storage battery.

  Patent Document 1 discloses a technique (hereinafter also referred to as “Related Art A”) for relaxing restrictions on the place of use of a power storage device (storage battery unit). Specifically, in Related Technology A, a caster is attached to the power storage device. In this configuration, the power storage device is separated from the power conditioner by moving the power storage device.

  Patent Document 2 discloses a technology (hereinafter also referred to as “Related Technology B”) in which a power storage device (storage battery unit) is separable from a power supply device (power conditioner) and can be carried. Has been. Thereby, for example, in outdoor leisure, the power storage device can be used.

  Note that in an electronic device such as a power conditioner, a detachable housing cover is generally provided in order to perform maintenance of the electronic device. Patent Document 3 discloses a technique (hereinafter, also referred to as “Related Technology C”) for improving the safety of maintenance work when the housing cover is removed. Specifically, Related Art C discloses a configuration that reliably shuts off the power output of the power supply device when the housing cover is removed. In this configuration, the open / close detection unit and the control circuit related to power shutdown are multiplexed. Thereby, fail safe can be ensured.

JP 2013-009584 A JP 11-098711 A JP 2000-021744 A

  As described above, in some conventional power storage systems, an integrated power conditioner and storage battery unit are configured to be separable. The power storage system is used in various installation environments. Specifically, the power storage system is used in either a connected state in which the power conditioner and the storage battery unit are connected or a non-connected state in which the power conditioner and the storage battery unit are separated depending on the installation environment of the power storage system. Is done. Therefore, it is desired to control the supply of electric power to the power conditioner according to the installation environment of the power storage system. That is, it is desired to control the power supply to the power conditioner in consideration of the connected state and the unconnected state that are the configuration states of the power storage system.

  In Related Technologies A, B, and C, control of power supply to the power conditioner in consideration of the configuration state of the power storage system is not disclosed.

  The present invention has been made to solve such problems, and provides a power storage system capable of controlling power supply to a power conditioner in consideration of the configuration state of the power storage system. Objective.

In order to achieve the above object, a power storage system according to one embodiment of the present invention includes a storage battery unit having a function of charging and a function of discharging, a function of charging the storage battery unit, and a function of discharging the storage battery unit. The power conditioner and the storage battery unit, the power conditioner and the storage battery unit are connected to each other in a connected state in which the power conditioner and the storage battery unit are connected, and the power conditioner and the storage battery unit. Is connected, and the power storage system further includes a first detection that selectively detects the connected state and the disconnected state that are the configuration states. Based on the configuration state detected by the switch and the first detection switch. There are, and a control unit that performs processing for controlling the supply of power to the power conditioner, the first detection switch is provided in the power conditioner, the first detection switch further, the non In a connected state, a first cover for protecting the inside of the power conditioner is attached to the power conditioner, and in a non-connected state, the first cover is attached to the power conditioner. The first non-attached state is selectively detected .

  According to the present invention, the first detection switch selectively detects the connected state and the unconnected state, which are the configuration states of the power storage system. A control part performs the process for controlling supply of the electric power to the said power conditioner based on the said configuration state which the said 1st detection switch detected.

  Thereby, it is possible to control the supply of electric power to the power conditioner in consideration of the configuration state of the power storage system.

It is a block diagram which shows the structure of the power distribution system which concerns on Embodiment 1 of this invention. 1 is an exploded perspective view of a power storage system according to Embodiment 1 of the present invention. It is a figure for demonstrating the structure of the housing | casing which concerns on Embodiment 1 of this invention. 4 is a diagram for explaining a state of a power storage system in a connected state X. FIG. 5 is a flowchart of power control processing S.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same components are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof may be omitted.

  It should be noted that the dimensions, materials, shapes, relative arrangements, and the like of the constituent elements exemplified in the embodiments are appropriately changed depending on the configuration of the apparatus to which the present invention is applied and various conditions. It is not limited to those examples. Moreover, the dimension of each component in each figure may differ from an actual dimension.

<Embodiment 1>
FIG. 1 is a block diagram showing a configuration of a power distribution system 2000 according to Embodiment 1 of the present invention. Referring to FIG. 1, a power distribution system 2000 includes a system power supply 2, a load distribution board 3, a solar cell 4, a connection box 5, a power storage system 1000, a power distribution board 10, and a general load. 11 and the like.

  The power storage system 1000 is connected to the solar cell 4 via the connection box 5. The solar cell 4 generates direct-current power when the solar cell 4 is irradiated with sunlight. The power storage system 1000 is connected to the system power supply 2 via the load distribution board 3. The system power source 2 is a power source that supplies AC power. The power storage system 1000 is connected to the general load 11 through the power distribution board 10. The general load 11 is, for example, a household appliance that operates with AC power.

  The power storage system 1000 includes a power conditioner 100 and a storage battery unit 200. The storage battery unit 200 has a function of charging and a function of discharging. Specifically, the storage battery unit 200 includes a battery control unit 8 and a storage battery 9. The storage battery 9 is a battery having a function of charging and a function of discharging. The storage battery 9 is, for example, a lithium ion battery. The battery control unit 8 controls the storage battery 9.

  The power conditioner 100 has a function of performing AC / DC power conversion and DC / AC power conversion. The power conditioner 100 has a function of charging the storage battery unit 200 and a function of discharging the storage battery unit 200. Specifically, the power conditioner 100 performs a process for charging the storage battery 9 and a process for discharging the storage battery 9 via the battery control unit 8. The power conditioner 100 performs, for example, a process of charging the storage battery 9 by using surplus power at night when the power demand is low and a process of supplying the power stored in the storage battery 9 to the outside during the day when the power demand is large.

  Next, the operation of the power distribution system 2000 will be briefly described. AC power supplied from the system power supply 2 is supplied to the power storage system 1000 via the load distribution board 3. The power conditioner 100 performs AC / DC power conversion for converting the AC power into DC power. And the power conditioner 100 controls the battery control part 8 so that the storage battery 9 is charged using the said direct-current power.

  Further, the DC power generated by the solar cell 4 is supplied to the power storage system 1000 through the connection box 5. The power conditioner 100 performs DC / DC power conversion that changes the level of the DC power. And the power conditioner 100 controls the battery control part 8 so that the storage battery 9 is charged using the direct-current power in which the level changed.

  The power conditioner 100 performs DC / AC power conversion for converting the DC power into AC power. The power conditioner 100 controls the distribution board 10 for power storage so that the AC power is supplied to the general load 11.

  Further, the power conditioner 100 acquires the DC power stored in the storage battery 9 via the battery control unit 8. The power conditioner 100 performs DC / AC power conversion for converting the DC power into AC power. The power conditioner 100 controls the distribution board 10 for power storage so that the AC power is supplied to the general load 11.

  As described above, in the power distribution system 2000, the storage battery 9 is charged using AC power from the system power supply 2 in the night time zone when the power rate is low. Moreover, in the power distribution system 2000, the direct-current power stored in the storage battery 9 is supplied to the general load 11 provided indoors during the daytime when the amount of power used is large. Further, in the power distribution system 2000, the DC power generated by the solar cell 4 is converted into AC power. Then, the AC power is supplied to the general load 11. Moreover, in the power distribution system 2000, the storage battery 9 is charged using the DC power obtained by converting the AC power.

  Next, a detailed configuration of the power storage system 1000 will be described. FIG. 2 is an exploded perspective view of power storage system 1000 according to Embodiment 1 of the present invention. In FIG. 2, the X, Y, and Z directions are orthogonal to each other. The X, Y, and Z directions shown in the following figures are also orthogonal to each other. Hereinafter, a direction including the X direction and the direction opposite to the X direction (−X direction) is also referred to as “X axis direction”. In the following, the direction including the Y direction and the direction opposite to the Y direction (−Y direction) is also referred to as “Y-axis direction”. Hereinafter, a direction including the Z direction and a direction opposite to the Z direction (−Z direction) is also referred to as a “Z-axis direction”.

  Hereinafter, a plane including the X-axis direction and the Y-axis direction is also referred to as an “XY plane”. Hereinafter, a plane including the X-axis direction and the Z-axis direction is also referred to as an “XZ plane”. Hereinafter, a plane including the Y-axis direction and the Z-axis direction is also referred to as a “YZ plane”.

  With reference to FIGS. 1 and 2, power storage system 1000 includes power conditioner 100 and storage battery unit 200 as described above.

  The power conditioner 100 includes a control unit 110. The control unit 110 controls each unit in the power conditioner 100. The control unit 110 is, for example, a CPU (Central Processing Unit). In addition, the control unit 110 controls the load distribution board 3, the connection box 5, and the electricity storage distribution board 10.

  The power conditioner 100 further includes a housing 20 and a substrate 23. The case 20 accommodates each part (for example, the board | substrate 23) in the power conditioner 100. FIG. The housing 20 is, for example, a PCS storage box.

  FIG. 3 is a diagram for explaining the configuration of the housing 20 according to the first embodiment of the present invention. FIG. 3A is a plan view showing the configuration of the housing 20. With reference to FIG. 1 and FIG. 3A, the housing 20 includes a case 21 and a door 22. The case 21 and the door 22 are members for protecting the inside of the power conditioner 100. The door 22 is attached to the power conditioner 100. The door 22 is configured to be openable and closable. Specifically, the door 22 is attached to the case 21 so that the door 22 can be opened and closed. The door 22 is provided so as to protect the substrate 23 from the left side surface of the housing 20.

  Hereinafter, the state in which the door 22 is open is also referred to as “open state P”. Hereinafter, the state where the door 22 is closed is also referred to as a “closed state NP”. When the state of the door 22 is the open state P, the operator can perform maintenance or the like on the substrate 23 or the like.

  The case 21 includes a front portion 21a and a back plate 21b. The front portion 21 a forms the front surface of the case 21 and the right side surface of the case 21. The back plate 21b is a plate for fixing the housing 20 (power conditioner 100) to a wall surface or the like (not shown) with screws or the like.

  The board | substrate 23 is a board | substrate which controls each part in the power conditioner 100. FIG. Further, the above-described control unit 110 is provided on the substrate 23, for example. The power lines L1 and L2 are connected to the substrate 23.

  The power conditioner 100 is connected to the connection box 5 described above by the power line L1. Specifically, the substrate 23 is connected to the connection box 5 by the power line L1.

  The storage battery unit 200 includes a housing 50 and a substrate 53. The housing 50 accommodates each part (for example, the board | substrate 53, the storage battery 9, etc.) in the storage battery unit 200. FIG. The substrate 53 is provided with the battery control unit 8 described above. The battery control unit 8 has a function of controlling each unit in the storage battery unit 200. The substrate 53 is connected to the storage battery 9.

  The housing 50 includes a case 51 and a door 52. The case 51 forms the front surface of the housing 50 and the right side surface of the housing 50. The case 51 and the door 52 are members for protecting the inside of the storage battery unit 200. The door 52 is configured to be openable and closable. Specifically, the door 52 is attached to the case 51 so that the door 52 can be opened and closed. The door 52 is provided so as to protect the substrate 53 from the left side surface of the housing 50.

  Hereinafter, the state in which the door 52 is open is also referred to as “open state”. Hereinafter, the state in which the door 52 is closed is also referred to as a “closed state”. When the state of the door 52 is an open state, the operator can perform maintenance etc. with respect to the board | substrate 53 grade | etc.,.

  The door 52 has an opening H5. The opening H5 is an opening (wiring port) for passing a power line or the like. In addition, a waterproof structure (not shown) for preventing entry of rain and the like from the outer surface of the door 52 to the inside of the storage battery unit 200 is formed in the periphery of the opening H5 in the door 52. For example, when the storage battery unit 200 is installed on the floor, the storage battery unit 200 is installed on the floor using a fixing member or the like (not shown) for fixing the housing 50 to the floor. In addition, the storage battery unit 200 is firmly fixed by a fixing member so that the storage battery unit 200 does not fall down due to shaking caused by an earthquake or the like.

  Moreover, the power conditioner 100 is connected with the storage battery unit 200 by the power line L2. The power line L <b> 2 is a power line for transmitting DC power between the power conditioner 100 and the storage battery unit 200. Specifically, the power line L2 connected to the power conditioner 100 is connected to the inside of the storage battery unit 200 through the opening H5 of the door 52.

  The substrate 23 of the power conditioner 100 is connected to the substrate 53 of the storage battery unit 200 by the power line L2. As described above, the battery control unit 8 described above is provided on the substrate 53. Specifically, the substrate 23 is connected to the battery control unit 8 through the power line L2. Battery control unit 8 is connected to storage battery 9.

  The DC power generated by the power conditioner 100 is sent to the substrate 53 via the power line L2. The battery control unit 8 of the substrate 53 performs processing for charging the storage battery 9 using the DC power. Moreover, the battery control part 8 performs the process which sends the direct-current power stored in the storage battery 9 to the power conditioner 100 via the power line L2 as needed.

  The power conditioner 100 and the storage battery unit 200 are configured to be freely connectable. Hereinafter, a state where the power conditioner 100 and the storage battery unit 200 are connected is also referred to as a “connected state X”. In the following, the state where the power conditioner 100 and the storage battery unit 200 are separated is also referred to as a “non-connected state NX”.

  In the unconnected state NX, the power conditioner 100 and the storage battery unit 200 can be installed in different places. For example, in the unconnected state NX, the power conditioner 100 is installed outdoors, and the storage battery unit 200 is installed indoors. In this case, the power conditioner 100 can be operated by connecting the power conditioner 100 and the storage battery unit 200 by the power line L2.

  Further, the power conditioner 100 and the storage battery unit 200 will be described in detail later, but a connection structure (hereinafter referred to as “connection” for setting the configuration state of the power storage system 1000 to one of the connection state X and the non-connection state NX. Structure CN ”).

  Next, the configuration of the power conditioner 100 and the storage battery unit 200 in the unconnected state NX will be described. First, the power conditioner 100 in the unconnected state NX will be described.

  The casing 20 of the power conditioner 100 has a configuration in which the cover BC1 can be attached to the lower part of the casing 20 when the door 22 is in the closed state NP. With this configuration, when the power conditioner 100 is used in the non-connected state NX, the cover BC1 of FIG. 2 is attached to the lower portion of the power conditioner 100 in which the door 22 is in the closed state NP. That is, the cover BC1 is attached to the lower portion of the housing 20 in which the door 22 is in the closed state NP. The cover BC1 is a dedicated cover (bottom cover) for protecting the inside of the power conditioner 100 in the unconnected state NX.

  Hereinafter, the state in which the cover BC1 is attached to the power conditioner 100 (housing 20) in the unconnected state NX is also referred to as “attached state A”. In the following, the state where the cover BC1 is not attached to the power conditioner 100 (housing 20) in the non-connected state NX is also referred to as “non-attached state NA”.

  An opening H3 is formed in the cover BC1. The opening H3 is an opening (wiring port) for passing a power line or the like. In addition, a waterproof structure (not shown) for preventing rain, dust, and the like from entering the inside of the power conditioner 100 from the outer surface of the cover BC1 is formed around the opening H3 in the cover BC1. In the unconnected state NX, when the cover BC1 is fixed to the lower part of the housing 20, the power lines L1 and L2 connected to the substrate 23 are connected to the outside through the opening H3.

  Further, the cover BC1 is provided with a locking portion K1a and a hole H1b. The shape of the locking portion K1a is, for example, an L shape (key shape). Further, a hole H1a is provided in the lower portion of the case 21 of the power conditioner 100. The locking portion K1a is provided to face the hole H1a of the case 21. The locking portion K1a of the cover BC1 is configured to engage with the peripheral portion of the hole H1a in the case 21 in the attachment state A.

  Further, a locking portion K1b is attached to the lower portion (bottom surface side) of the case 21 of the power conditioner 100. The shape of the locking portion K1b is, for example, an L shape (key shape). The locking portion K1b is configured to engage with the peripheral portion of the hole H1b in the cover BC1 in the attached state A. The locking portion K1a engages with the peripheral portion of the hole H1a in the case 21, and the locking portion K1b engages with the peripheral portion of the hole H1b in the cover BC1, so that the cover BC1 Is installed.

  Next, the storage battery unit 200 in the unconnected state NX will be described. The housing 50 of the storage battery unit 200 has a configuration in which the cover TC1 can be attached to the top of the housing 50 when the door 52 is in the closed state. With this configuration, when the storage battery unit 200 is used in the unconnected state NX, the cover TC1 of FIG. 2 is attached to the upper part of the storage battery unit 200 in which the door 52 is closed. That is, the cover TC1 is attached to the upper part of the housing 50 in which the door 52 is closed. The cover TC1 is a dedicated cover (top cover) for protecting the inside of the storage battery unit 200 in the unconnected state NX.

  Hereinafter, the state in which the cover TC1 is attached to the storage battery unit 200 in the unconnected state NX is also referred to as “attached state B”. In the following, the state where the cover TC1 is not attached to the storage battery unit 200 in the non-connected state NX is also referred to as “non-attached state NB”.

  A waterproof packing (not shown) is provided at a portion where the cover TC1 and the housing 50 are in contact (fitted) in the attachment state B. With this configuration, when the storage battery unit 200 is installed outdoors with the cover TC1 attached to the storage battery unit 200 (housing 50), rainwater or the like can be prevented from entering the storage battery unit 200.

  Locking portions K2a and K2b are provided on the back surface of the cover TC1. Each shape of the latching | locking part K2a and K2b is L shape (key shape), for example. The storage battery unit 200 is provided with holes H2a and H2b. Specifically, holes H2a and H2b are provided in the upper part (upper surface side) of the case 51 (housing 50).

  The locking portions K2a and K2b are provided to face the holes H2a and H2b, respectively. The locking portion K2a is configured to engage with the peripheral portion of the hole H2a in the case 51 in the attachment state B. The locking portion K2b is configured to engage with the peripheral portion of the hole H2b in the case 51 in the attachment state B.

  The locking portion K2a engages with the peripheral portion of the hole H2a in the case 51, and the locking portion K2b engages with the peripheral portion of the hole H2b in the case 51, so that the cover TC1 is formed on the upper portion of the housing 50. Is installed.

  Next, the connection structure CN for connecting the power conditioner 100 and the storage battery unit 200 will be described. As described above, the storage battery unit 200 is provided with the hole H2b. Specifically, as described above, the hole H2b is provided in the upper portion of the case 51 (housing 50). The power conditioner 100 is provided with a locking portion K1b. Specifically, as described above, the locking portion K1b is provided in the lower portion of the case 21 of the power conditioner 100. The locking portion K1b is a member that engages with the storage battery unit 200 using the hole H2b in order to change the configuration state of the power storage system 1000 to the connected state X.

  Specifically, the locking portion K1b engages with the peripheral portion of the hole H2b in the case 51. Thereby, the power conditioner 100 and the storage battery unit 200 are connected in the Z-axis direction. That is, a part of the connection structure CN includes the hole H2b and the locking portion K1b.

  As described above, the hole H1a is provided in the lower portion of the case 21 of the power conditioner 100. At the upper part of the case 51 of the storage battery unit 200, a locking portion K3 is provided. The power conditioner 100 and the storage battery unit 200 are connected by inserting the locking portion K3 into the hole H1a. Another part of the connection structure CN includes a hole H1a and a locking portion K3.

  FIG. 4 is a diagram for explaining the state of the power storage system 1000 in the connected state X. 4A is a cross-sectional view along the XZ plane of the power storage system 1000 in the connected state X. FIG. In the connected state X, the power conditioner 100 is disposed on the storage battery unit 200.

  In the power storage system 1000 in the connected state X, the power line L1 connected to the connection box 5 is connected to the substrate 23 of the power conditioner 100 through the opening H5 of the door 52 and the inside of the housing 50. Further, the power line connected to the load distribution board 3 and the power line connected to the storage distribution board 10 are connected to the power conditioner 100 via the opening H5 of the door 52 and the inside of the housing 50. Connected to the substrate 23.

  Moreover, in the electrical storage system 1000 in the connection state X, the board | substrate 23 of the power conditioner 100 and the board | substrate 53 of the storage battery unit 200 are connected by the shortest distance with the electric power line L2. Further, when the door 22 and the door 52 are closed, the power line L2 cannot be seen from the outside.

  Note that in the power storage system 1000 in the connected state X, the door 22 and the door 52 are configured such that the lower surface of the door 22 covers the outer surface of the upper portion of the door 52 in the open state. Therefore, after each of the power lines L1 and L2 is connected to a predetermined position, the door 52 is closed and then the door 22 is closed. Therefore, when the state of the door 22 is the closed state NP, the state of the door 52 is a closed state.

  Next, a configuration for detecting the connection state X, the attachment state A, the attachment state B, the open state P, and the like described above will be described. Here, FIG.4 (b) is an enlarged view of area | region R21 of Fig.4 (a). FIG. 4C is an enlarged view of the region R22 in FIG. FIG. 4D is an enlarged view of the region R23 in FIG.

  First, a configuration for detecting the connection state X will be described. Referring to FIG. 4, power storage system 1000 further includes detection switches 70a and 70c. Although details will be described later, each of the detection switches 70 a and 70 c selectively detects the connected state X and the disconnected state NX that are the configuration states of the power storage system 1000.

  First, the detection switch 70a will be described. As shown in FIG. 4, the detection switch 70 a is provided in the power conditioner 100. Referring to FIGS. 2 and 4, specifically, detection switch 70 a is provided in the periphery of hole H <b> 1 a in housing 20.

  The detection switch 70a is, for example, a lever type switch. The detection switch 70a includes a lever 72a and a detection circuit 71a. The lever 72a is attached to the detection circuit 71a so that the lever 72a is rotatable.

  The lever 72a is configured to contact the locking portion K3 in the connected state X and not to contact the locking portion K3 in the non-connected state NX. The lever 72a receives pressure from the locking portion K3 by contacting the locking portion K3. Thereby, the lever 72a rotates. Hereinafter, a state in which no pressure is applied to the lever 72a is also referred to as a “zero pressure state”.

  The detection circuit 71a detects the rotation state (rotation angle) of the lever 72a. The detection circuit 71a detects a zero pressure state based on whether or not the rotation angle of the lever 72a is 0 degrees. The detection circuit 71a detects the connection state X when the lever 72a is in contact with the locking portion K3. Specifically, the detection circuit 71a detects the connection state X when the lever 72a is rotating due to contact of the lever 72a with the locking portion K3.

  Further, the detection circuit 71a detects the unconnected state NX when the lever 72a is not in contact with the locking portion K3. Specifically, when the lever 72a is not in contact with the locking portion K3, the detection circuit 71a detects a zero pressure state, that is, a non-connected state NX. That is, the detection switch 70a (detection circuit 71a) selectively detects the connected state X and the disconnected state NX.

  The detection circuit 71a has an on state and an off state as operation states. When the detection circuit 71a detects the connection state X, the detection circuit 71a is turned on. Moreover, the detection circuit 71a will be in an OFF state, when the non-connection state NX is detected.

  Next, the detection switch 70c will be described. As shown in FIG. 4, the detection switch 70 c is provided in the storage battery unit 200. Referring to FIGS. 2 and 4, specifically, detection switch 70 c is provided in the periphery of hole H <b> 2 b in housing 50.

  The detection switch 70c is, for example, a lever type switch. The detection switch 70c includes a lever 72c and a detection circuit 71c. The lever 72c is attached to the detection circuit 71c so that the lever 72c is rotatable.

  The lever 72c is configured to contact the locking portion K1b of the case 21 in the connected state X and not to contact the locking portion K1b in the non-connected state NX. The lever 72c receives pressure from the locking portion K1b by contacting the locking portion K1b. Thereby, the lever 72c rotates. Hereinafter, the state where no pressure is applied to the lever 72c is also referred to as a “zero pressure state”.

  Similarly to the detection circuit 71a, the detection circuit 71c detects a zero pressure state depending on whether or not the rotation angle of the lever 72c is 0 degree. The detection circuit 71c detects the connection state X when the lever 72c is in contact with the locking portion K1b. Specifically, the detection circuit 71c detects the connection state X when the lever 72c is rotating due to contact of the lever 72c with the locking portion K1b.

  Further, the detection circuit 71c detects the non-connected state NX when the lever 72c is not in contact with the locking portion K1b. Specifically, when the lever 72c is not in contact with the locking portion K1b, the detection circuit 71c detects a zero pressure state, that is, a non-connected state NX. That is, the detection switch 70c (detection circuit 71c) selectively detects the connected state X and the disconnected state NX.

  The detection circuit 71c has an on state and an off state as operation states. The detection circuit 71c is turned on when the connection state X is detected. Moreover, the detection circuit 71c will be in an OFF state, when the non-connection state NX is detected.

  Next, a configuration for detecting the attachment state A will be described. As described above, the attachment state A is a state in which the cover BC1 is attached to the power conditioner 100 (housing 20) in the unconnected state NX. The attachment state A is detected by the detection switch 70a (detection circuit 71a).

  The detection switch 70a has a function of selectively detecting the attachment state A and the non-attachment state NA in addition to the function of selectively detecting the connection state X and the non-connection state NX. The non-attached state NA is a state in which the cover BC1 is not attached to the power conditioner 100 (housing 20) in the non-connected state NX as described above.

  Specifically, the lever 72a of the detection switch 70a is further configured to contact the locking portion K1a in the attached state A and not to contact the locking portion K1a in the non-attached state NA. The lever 72a receives pressure from the locking portion K1a by contacting the locking portion K1a. Thereby, the lever 72a rotates.

  Further, the detection circuit 71a detects the attachment state A when the lever 72a is rotating due to the lever 72a coming into contact with the locking portion K1a. When the lever 72a is not in contact with the locking portion K1a, the detection circuit 71a detects the zero pressure state, that is, the non-attached state NA. That is, when the lever 72a is not in contact with the locking portion K3 or the locking portion K1a, the detection circuit 71a (detection switch 70a) detects the non-attached state NA in addition to the non-connected state NX.

  The detection circuit 71a is turned on when the attachment state A is detected. The detection circuit 71a is turned off when the non-attached state NA is detected.

  Next, a configuration for detecting the attachment state B will be described. As described above, the attachment state B is a state in which the cover TC1 is attached to the storage battery unit 200 in the non-connected state NX.

  Referring to FIG. 4, power storage system 1000 further includes detection switch 70b. The detection switch 70b is provided in the storage battery unit 200. Referring to FIGS. 2 and 4, specifically, detection switch 70 b is provided in the periphery of hole H <b> 2 a in housing 50.

  The detection switch 70b has a function of selectively detecting the attachment state B and the non-attachment state NB. As described above, the non-attached state NB is a state in which the cover TC1 is not attached to the storage battery unit 200 in the non-connected state NX.

  The detection switch 70b is, for example, a lever type switch. The detection switch 70b includes a lever 72b and a detection circuit 71b. The lever 72b is attached to the detection circuit 71b so that the lever 72b is rotatable. The lever 72b is configured to contact the locking portion K2a of the cover TC1 in the attached state B and not to contact the locking portion K2a in the non-attached state NB.

  The lever 72b receives pressure from the locking portion K2a by contacting the locking portion K2a. Thereby, the lever 72b rotates. Hereinafter, a state in which no pressure is applied to the lever 72b is also referred to as a “zero pressure state”.

  Similar to the detection circuit 71a, the detection circuit 71b detects a zero pressure state depending on whether or not the rotation angle of the lever 72b is 0 degree. The detection circuit 71b detects the attachment state B when the lever 72b is rotating due to the lever 72b coming into contact with the locking portion K2a. Further, when the lever 72b is not in contact with the locking portion K2a, the detection circuit 71b detects a zero pressure state, that is, a non-attached state NB.

  The detection circuit 71b has an on state and an off state as operation states. The detection circuit 71b is turned on when the attachment state B is detected. Moreover, the detection circuit 71b will be in an OFF state, when the non-attached state NB is detected.

  The attachment state B is also detected by the detection switch 70c. That is, the detection switch 70c has a function of selectively detecting the attachment state B and the non-attachment state NB in addition to the function of selectively detecting the connection state X and the non-connection state NX.

  Specifically, the lever 72b of the detection switch 70b is further configured to contact the locking portion K2b in the attached state B and not to contact the locking portion K2b in the non-attached state NB. The lever 72b receives pressure from the locking portion K2b by contacting the locking portion K2b. Thereby, the lever 72b rotates.

  The detection circuit 71b further detects the attachment state B when the lever 72b is rotating by the lever 72b coming into contact with the locking portion K2b. When the lever 72b is not in contact with the locking portion K2b, the detection circuit 71b detects the zero pressure state, that is, the non-attached state NB. That is, when the lever 72b is not in contact with the locking portion K1b or the locking portion K2b, the detection circuit 71b (detection switch 70b) detects the non-attached state NB in addition to the non-connected state NX.

  The detection circuit 71b is turned on when the attachment state B is detected. Moreover, the detection circuit 71b will be in an OFF state, when the non-attached state NB is detected.

  Next, a configuration for detecting the open state P will be described. The open state P is a state in which the door 22 is open in the housing 20 as described above. FIG. 3B is an enlarged view of the region R12 of FIG.

  Referring to FIGS. 2 and 3, power storage system 1000 further includes detection switch 70d. The detection switch 70d selectively detects the open state P and the closed state NP. The closed state NP is a state in which the door 22 is closed in the housing 20 as described above. As shown in FIGS. 2 and 3, the door 22 is provided with a protrusion 22 x.

  The detection switch 70d is, for example, a lever type switch. The detection switch 70d is provided at a position facing the protrusion 22x. The detection switch 70d includes a lever 72d and a detection circuit 71d. The lever 72d is attached to the detection circuit 71d so that the lever 72d is rotatable. The lever 72d is configured to contact the protrusion 22x of the door 22 in the closed state NP and not to contact the protrusion 22x in the open state P.

  The lever 72d receives pressure from the protrusion 22x by contacting the protrusion 22x. As a result, the lever 72d rotates. Hereinafter, a state in which no pressure is applied to the lever 72d is also referred to as a “zero pressure state”.

  Similarly to the detection circuit 71a, the detection circuit 71d detects a zero pressure state depending on whether or not the rotation angle of the lever 72d is 0 degree. The detection circuit 71d detects the closed state NP when the lever 72d is rotating due to the lever 72d coming into contact with the protrusion 22x. The detection circuit 71d detects a zero pressure state, that is, an open state P when the lever 72d is not in contact with the protrusion 22x.

  The detection circuit 71d has an on state and an off state as operation states. The detection circuit 71d is turned on when the closed state NP is detected. The detection circuit 71d is turned off when the open state P is detected.

  The control unit 110 of the power conditioner 100 is configured to be able to communicate with each of the detection switches 70a, 70b, 70c, and 70d. Specifically, the control unit 110 is configured to be able to communicate with each of the detection circuits 71a, 71b, 71c, and 71d. Thereby, the control part 110 always grasps | ascertains each operation state of detection circuit 71a, 71b, 71c, 71d.

  Next, a process of controlling power supply (hereinafter also referred to as “power control process”) based on the configuration state of the power storage system 1000 will be described. The power conditioner 100 has a normal mode and a standby mode as operation modes. The normal mode is a mode in which the power conditioner 100 is supplied with sufficient power necessary for performing the above-described AC / DC power conversion, for example.

  The standby mode is a mode in which a minimum power is supplied to the power conditioner 100 so that only a part of the circuits can operate. The part of the circuit is, for example, the control unit 110, the detection circuits 71a, 71b, 71c, and 71d. For example, the power conditioner 100 in the standby mode is not supplied with power necessary for performing the above-described AC / DC power conversion or the like.

  Hereinafter, the power control process for supplying power to the power conditioner 100 in the standby mode is also referred to as “power control process S”. In the following description, the power control process for stopping the supply of power to the power conditioner 100 in the normal mode in the connected state X is also referred to as “power control process Z”. First, the power control process S will be described.

  FIG. 5 is a flowchart of the power control process S. The power control process S is started, for example, when an operation for setting the operation mode of the power conditioner 100 to the normal mode is performed. The operation for switching to the normal mode is an operation in which the operator presses a power button (not shown) provided on the power conditioner 100, for example.

  In step S110, it is determined whether the configuration state of the power storage system 1000 is the connected state X or the unconnected state NX. Specifically, control unit 110 determines the configuration state of power storage system 1000 by referring to the operation states of detection circuits 71a and 71c.

  When both the detection circuit 71a and the detection circuit 71c are in the on state, the control unit 110 determines that the configuration state is reliably the connected state X. When both the detection circuit 71a (detection switch 70a) and the detection circuit 71c (detection switch 70c) detect the connection state X, both the detection circuit 71a and the detection circuit 71c are in the on state. Further, when both the detection circuit 71a and the detection circuit 71c are in the on state, the power conditioner 100 and the storage battery unit 200 are securely connected.

  In addition, when at least one of the detection circuit 71a and the detection circuit 71c is in the off state, the control unit 110 determines that the configuration state is the unconnected state NX. When the detection circuit 71a (detection switch 70a) detects the disconnected state NX, the state of the detection circuit 71a is an off state. Further, when the detection circuit 71c (detection switch 70c) detects the non-connected state NX, the state of the detection circuit 71c is an off state.

  For example, when the state of the detection circuit 71a is on and the state of the detection circuit 71c is off, the control unit 110 determines that the power conditioner 100 and the storage battery unit 200 are not normally connected. When the state of the detection circuit 71a is on and the state of the detection circuit 71c is off, for example, the locking portion K1b is not normally engaged with the peripheral portion of the hole H2b in the case 51. That is, there is a problem in the engaged state of the locking portion K1b.

  If the configuration state is certainly the connected state X, the process proceeds to step S120. Note that, when the configuration state is surely the connected state X, both the detection circuit 71a and the detection circuit 71c detect the connected state X. On the other hand, when the configuration state is the unconnected state NX, the process proceeds to step S211.

  In step S120, control unit 110 determines whether door 22 is in the closed state NP. In the connected state X, when the door 22 is in the closed state NP, the door 52 is in the closed state. Further, as described above, when the detection circuit 71d (detection switch 70d) detects the closed state NP, the state of the detection circuit 71d is an on state.

  Specifically, the control unit 110 refers to whether or not the state of the detection circuit 71d is an on state. If YES in step S120, the process proceeds to step S130. In the case of YES in step S120, the power conditioner 100 and the storage battery unit 200 are securely connected, the door 22 is in the closed state NP, and the door 52 is in the closed state. That is, if YES in step S120, it is safe to supply power to the power conditioner 100 in the standby mode.

  On the other hand, if NO in step S120, that is, if the state of the detection circuit 71d is off, the power control process S ends.

  In step S130, a power supply control process S is performed. In the power supply control process S, the control unit 110 performs a process for supplying power to the power conditioner 100. Specifically, in the power supply control process S, the control unit 110, for example, loads the load so that AC power from the system power supply 2 is supplied to the power conditioner 100 via the load distribution board 3. The distribution board 3 is controlled. In addition, the control part 110 may control the said connection box 5 so that the direct-current power from the solar cell 4 may be supplied to the power conditioner 100 via the connection box 5. FIG.

  With the power supply control process S described above, the operation mode of the power conditioner 100 becomes the normal mode. Then, the power control process S ends.

  In addition, by performing steps S110, S120, and S130, the control unit 110, when the detection switches 70a and 70c detect the connection state X and the detection switch 70d detects the closed state NP, returns to the power conditioner 100. Processing for supplying power is performed. In other words, the control unit 110 performs processing for controlling the supply of power to the power conditioner 100 based on the configuration state detected by the detection switches 70a and 70c.

  If it is determined in step S110 described above that the configuration state is the unconnected state NX, the process proceeds to step S211.

  In step S211, it is determined whether or not there is a top cover. That is, it is determined whether or not the cover TC1 is attached to the housing 50 (storage battery unit 200). Specifically, the control unit 110 refers to whether or not the state of the detection circuit 71b is an on state. As described above, when the detection circuit 71b (detection switch 70b) detects the attachment state B, the detection circuit 71b is in the on state.

  If YES in step S211, the process proceeds to step S212. On the other hand, if NO in step S211, the power control process S ends.

  The power control process S may be configured such that the process of step S211 is not performed. In the case of this configuration, when it is determined in step S110 that the configuration state is the disconnected state NX, the process proceeds to step S212.

  In step S212, it is determined whether there is a bottom cover. That is, it is determined whether or not the cover BC1 is attached to the housing 20 (power conditioner 100). Specifically, the control unit 110 refers to whether or not the state of the detection circuit 71a is on. As described above, when the detection circuit 71a (detection switch 70a) detects the attachment state A, the detection circuit 71a is in an on state.

  If YES in step S212, the process proceeds to step S213. On the other hand, if NO in step S212, the power control process S ends.

  In step S213, control unit 110 determines whether or not the state of door 22 is a closed state NP. Since the process of step S213 is the same as the process of step S120, detailed description will not be repeated. That is, the control unit 110 refers to whether or not the state of the detection circuit 71d is an on state.

  If YES in step S213, the process proceeds to step S230. On the other hand, if NO in step S213, the power control process S ends.

  In step S230, a power supply control process S is performed. Since the power supply control process S is the same as the power supply control process S in step S130, detailed description will not be repeated.

  With the power supply control process S described above, the operation mode of the power conditioner 100 becomes the normal mode. Then, the power control process S ends.

  By performing steps S110, S212, S213, and S230, the control unit 110 detects that the detection switches 70a and 70c detect the unconnected state NX, the detection switch 70a detects the attachment state A, and When the detection switch 70d detects the closed state NP, a process for supplying power to the power conditioner 100 is performed. In other words, the control unit 110 performs processing for controlling the supply of power to the power conditioner 100 based on the configuration state detected by the detection switches 70a and 70c.

  Next, the power control process Z will be described. The power control process Z is a power control process for stopping the supply of power to the power conditioner 100 in the normal mode in the connected state X as described above. The power control process Z is performed, for example, when the operation mode of the power conditioner 100 is the normal mode in the connected state X by the power control process S described above.

  Here, it is assumed that the following situation A occurs. The situation A is a situation in which, for example, the power storage system 1000 in the connected state X is shaken by an earthquake or the like, and the connection between the power conditioner 100 and the storage battery unit 200 is disconnected.

  When the situation A occurs, in the power control process Z, when at least one of the detection switches 70a and 70c detects the unconnected state NX, the control unit 110 prevents power from being supplied to the power conditioner 100. Power supply stop processing is performed.

  As described above, when the detection circuit 71a (detection switch 70a) detects the unconnected state NX, the state of the detection circuit 71a is an off state. Further, when the detection circuit 71c (detection switch 70c) detects the non-connected state NX, the state of the detection circuit 71c is an off state.

  Specifically, in the power control process Z, when the control unit 110 confirms that at least one of the detection circuits 71a and 71c is in an off state, the control unit 110 supplies power to the power conditioner 100. A power supply stop process is performed so as not to be interrupted.

  In the power supply stop process, for example, the control unit 110 controls the load distribution board 3 so that AC power from the system power supply 2 is not supplied to the power conditioner 100 via the load distribution board 3. To do. Moreover, the control part 110 controls the said connection box 5 so that the direct-current power from the solar cell 4 is not supplied to the power conditioner 100 via the connection box 5. FIG. As a result, the supply of power to the power conditioner 100 is stopped.

  As described above, for example, when the power storage system 1000 is shaken and the connection between the power conditioner 100 and the storage battery unit 200 is disconnected, the power control process Z for stopping the supply of power to the power conditioner 100 in the normal mode is performed. . Thereby, the safety | security of the electrical storage system 1000 can be ensured.

  The power control process Z may be performed, for example, when the door 22 is in the open state P in the power conditioner 100 in the normal mode.

  As described above, according to the present embodiment, detection switches 70a and 70c selectively detect connected state X and disconnected state NX, which are the configuration states of power storage system 1000. The control unit 110 performs a process for controlling the supply of power to the power conditioner 100 based on the configuration state detected by the detection switches 70a and 70c.

  Thereby, it is possible to control power supply to the power conditioner 100 in consideration of the configuration state of the power storage system 1000.

  Further, according to the present embodiment, the control unit 110 supplies power to the power conditioner 100 when the detection switches 70a and 70c detect the connection state X and the detection switch 70d detects the closed state NP. Process. That is, when the configuration state of the power storage system is the connected state X and the state of the door 22 is the closed state NP, the control unit 110 performs a process for supplying power to the power conditioner 100. Thereby, electric power can be supplied to the power conditioner 100 in a state in which the safety of the power conditioner 100 is ensured.

  Further, according to the present embodiment, for example, when the power storage system 1000 in the connected state X is shaken and the connection between the power conditioner 100 and the storage battery unit 200 is disconnected, power is supplied to the power conditioner 100 in the normal mode. A power control process Z for stopping is performed. Thereby, the safety | security of the electrical storage system 1000 can be ensured.

  Further, for example, in the power conditioner 100 in the normal mode, when the door 22 is in the open state P, the power control process Z is performed, so that the safety of the operator can be ensured.

  In power storage system 1000 according to the present embodiment, in addition to the function of selectively detecting connected state X and unconnected state NX, a function of selectively detecting attached state A and non-attached state NA Is used. Thereby, the number of detection switches required for the power storage system 1000 can be reduced. Therefore, the cost of the power storage system 1000 can be reduced.

  Moreover, according to this Embodiment, according to the state of the installation environment of the electrical storage system 1000, the power conditioner 100 and the storage battery unit 200 can be installed. For example, the installation space of the power storage system 1000 can be reduced by installing the connected power conditioner 100 and the storage battery unit 200 on the floor. Further, by installing the separated power conditioner 100 and the storage battery unit 200 in different places, the restriction on the place where the power storage system 1000 is installed can be relaxed.

  Further, according to the present embodiment, the detection switches 70a, 70b, 70c, and 70d are used to detect the installation state of the power conditioner 100 and the storage battery unit 200, the attachment state of the cover TC1 and the cover BC1, and the like. Then, power supply is controlled based on each detected state. Thereby, the safety | security of the maintenance work by an operator can be improved.

  Conventionally, in a power storage system with a large power storage capacity for supplying residential power, it is necessary to do as follows according to the installation environment of the house. For example, in the power storage system, it is necessary to determine in advance which of a configuration in which a power conditioner and a storage battery unit are integrated and a configuration in which the power conditioner and the storage battery unit are separated. And it is common to operate the said electrical storage system in the determined structure.

  For this reason, conventionally, after installing the power storage system, the storage battery unit and the power conditioner are separated and installed, or the storage battery unit and the power conditioner are integrated and changed. There was a problem that it was not possible.

  Conventionally, a storage system in which a storage battery having a small storage capacity can be detached from the main body has the following problems. For example, in the power storage system, when the storage battery is attached to the main body in order to charge the storage battery, there is a problem that charging cannot be performed if the connection between the storage battery and the main body is incomplete. Moreover, in the said electrical storage system, when the housing | casing cover was opened in the energized state, there existed a problem that an operator accidentally touched the live part.

  Further, in the above-described related art C, in order to increase the safety of the maintenance work, the opening / closing detection unit of the housing cover and the control circuit related to power shutdown are multiplexed. Therefore, it is necessary to provide a plurality of control circuits for each housing cover. Therefore, when there are a plurality of housing covers, it is necessary to provide multiple control circuits for each housing cover. Therefore, there is a problem that the configuration becomes complicated.

  Therefore, since the present embodiment is configured as described above, each of the above problems can be solved.

(Modification of Embodiment 1)
In the above-described first embodiment, the power storage system 1000 is a system including one power conditioner 100 and one storage battery unit 200, but is not limited thereto.

  For example, when the power conditioner 100 and the storage battery unit 200 are installed separately, the power storage system 1000 may be composed of one power conditioner 100 and a plurality of storage battery units 200. That is, the number of power conditioners 100 included in the power storage system 1000 according to the present modification is 1, and the number of storage battery units 200 included in the power storage system 1000 is two or more.

  In the present modification, the number of storage battery units 200 can be increased or decreased to reduce restrictions on the location where the power storage system 1000 is installed. Moreover, the electrical storage system 1000 according to the capacity | capacitance of demand electric power can be comprised by increasing / decreasing the number of the storage battery units 200. FIG.

(Other variations)
The power distribution system and the power storage system according to the present invention have been described based on the embodiments. However, the present invention is not limited to these embodiments. The present invention also includes modifications made to the present embodiment by those skilled in the art without departing from the scope of the present invention. That is, within the scope of the invention, the present invention can be freely combined with the embodiments and the modified examples of the embodiments, or can be appropriately modified and omitted with the modified examples of the embodiments and the embodiments. is there.

  For example, the power storage system 1000 may not include all the components shown in FIGS. 1 and 2. That is, the power storage system 1000 may include only the minimum components that can realize the effects of the present invention.

  In addition, the present invention may be realized as a power control method in which the operation of characteristic components included in power storage system 1000 is a step. In the present invention, a computer may execute each step included in the power control method. The present invention may also be realized as a program that causes a computer to execute each step included in such a power control method. Further, the present invention may be realized as a computer-readable recording medium that stores such a program. The program may be distributed via a transmission medium such as the Internet.

  All the numerical values used in the above-mentioned embodiment are examples of numerical values for specifically explaining the present invention. That is, the present invention is not limited to the numerical values used in the above embodiments.

  The power control method according to the present invention corresponds to the power control process S or the power control process Z in FIG. The order in which each process in the power control method is executed is an example for specifically explaining the present invention, and may be in an order other than the above. Also, part of the processing in the power control method and other processing may be executed in parallel independently of each other.

  It should be noted that within the scope of the invention, the present invention can be freely combined with the embodiments and modifications of the embodiments, or can be appropriately modified and omitted with reference to the embodiments and modifications of the embodiments. is there.

  For example, the connecting structure CN described above is configured by the hole H2b and the locking portion K1b, and the hole H1a and the locking portion K3, but is not limited thereto. The connection structure CN may be configured, for example, from a set of holes and locking portions (hereinafter also referred to as “deformed configuration A”).

  In the modified configuration A, the connection structure CN may be configured by only the hole H2b and the locking portion K1b, for example. That is, in the modified configuration A, all of the connection structures CN are configured by the holes H2b and the locking portions K1b. In this configuration, the hole H2b and the locking portion K1b are provided, for example, in the central portion in the X-axis direction of the power storage system 1000 in FIG.

  Further, for example, the shapes of the locking portions K1a, K1b, K2a, K2b are not limited to the L shape (key shape), and may be other shapes. For example, when the shape of the hole H2b is circular, the shape of the locking portion K1b may be a columnar shape for being inserted into the hole H2b.

  Further, for example, in the power storage system 1000, the detection switches 70a, 70b, 70c, and 70d, that is, four detection switches are provided, but the configuration is not limited thereto. The number of detection switches provided in the power storage system 1000 may be 1 to 3, or 5 or more.

  For example, each of the detection switches 70a, 70b, 70c, and 70d is not limited to a lever type switch, and may be a switch of another type. Each of the detection switches 70a, 70b, 70c, and 70d may be a switch that detects the state of the locking portion using light, for example.

  Further, for example, the power storage system 1000 may have a configuration in which the doors 22 and 55 are not provided (hereinafter, also referred to as “modified configuration B”). In the modified configuration B, for example, the shapes of the housing 20 and the housing 50 are box-shaped.

  A configuration in which the modified configuration A is combined with the modified configuration B (hereinafter, also referred to as “deformed configuration C”) may be employed. In the modified configuration C, for example, only the detection switch 70c is provided in the power storage system 1000. In this case, in the power control process S to which the modified configuration C is applied, for example, when the detection switch 70c detects the connection state X, the control unit 110 performs a process for supplying power to the power conditioner 100. Do.

  9 Battery, 20, 50 Case, 22, 52 Door, 22x Protrusion, 23, 53 Substrate, 70a, 70b, 70c, 70d Detection switch, 71a, 71b, 71c, 71d Detection circuit, 72a, 72b, 72c, 72d Lever, 100 power conditioner, 110 control unit, 200 storage battery unit, 1000 power storage system, 2000 power distribution system, BC1, TC1 cover, H1a, H1b, H2a, H2b hole, K1a, K1b, K2a, K2b, K3 locking unit.

Claims (17)

A power storage system,
A storage battery unit having a function of charging and a function of discharging;
A power conditioner having a function of charging the storage battery unit and a function of discharging the storage battery unit;
The power conditioner and the storage battery unit may be any one of a configuration state of the power storage system, a connected state in which the power conditioner and the storage battery unit are connected, and a disconnected state in which the power conditioner and the storage battery unit are separated. Having a connection structure for setting
The power storage system further includes:
A first detection switch that selectively detects the connected state and the disconnected state that are the configuration states;
A control unit that performs processing for controlling supply of electric power to the power conditioner based on the configuration state detected by the first detection switch ;
The first detection switch is provided in the power conditioner,
The first detection switch further includes a first cover in which a first cover for protecting the inside of the power conditioner is attached to the power conditioner in the non-connected state, and the first detection switch in the non-connected state. A power storage system that selectively detects a first non-attached state in which the first cover is not attached to the power conditioner . The storage battery unit is provided with a hole,
The power conditioner is provided with a locking portion that engages with the storage battery unit using the hole in order to change the configuration state of the power storage system to the connected state.
The power storage system according to claim 1, wherein a part or all of the connection structure includes the hole and the locking portion. The first detection switch is
A lever configured to contact the locking portion in the connected state and not to contact the locking portion in the non-connected state;
A first detection circuit that detects the connected state when the lever is in contact with the locking portion and detects the non-connected state when the lever is not in contact with the locking portion. The power storage system described in 1. The storage battery unit is provided with a second detection switch,
In the unconnected state, the second detection switch includes a second attachment state in which a second cover for protecting the inside of the storage battery unit is attached to the storage battery unit, and a second cover in the unconnected state. The power storage system according to any one of claims 1 to 3 , wherein the cover selectively detects a second non-attached state in which the cover is not attached to the storage battery unit. The power storage system according to any one of claims 1 to 4 , wherein when the first detection switch detects the connected state, the control unit performs a process for supplying power to the power conditioner. The power conditioner is provided with a door for protecting the inside of the power conditioner,
The door is configured to be openable and closable,
The power storage system further includes:
A third detection switch for selectively detecting an open state in which the door is open and a closed state in which the door is closed;
The control unit performs a process for supplying power to the power conditioner when the first detection switch detects the connection state and the third detection switch detects the closed state. The power storage system according to any one of 1 to 4 . The power conditioner is provided with a door for protecting the inside of the power conditioner,
The door is configured to be openable and closable,
The power storage system further includes:
A third detection switch for selectively detecting an open state in which the door is open and a closed state in which the door is closed;
The control unit detects that the first detection switch detects the unconnected state, the first detection switch detects the first attachment state, and the third detection switch detects the closed state. when power storage system according to claim 1 for performing a process for electric power is supplied to the power conditioner. Wherein, when the first detection switch detects the non-connection state, in any one of 4 claims 1 to perform processing so that is not performed supply of power to the power conditioner The electricity storage system described. A power storage system,
A storage battery unit having a function of charging and a function of discharging;
A power conditioner having a function of charging the storage battery unit and a function of discharging the storage battery unit;
The power conditioner and the storage battery unit may be any one of a configuration state of the power storage system, a connected state in which the power conditioner and the storage battery unit are connected, and a disconnected state in which the power conditioner and the storage battery unit are separated. Having a connection structure for setting
The power storage system further includes:
A first detection switch that selectively detects the connected state and the disconnected state that are the configuration states;
A control unit that performs processing for controlling supply of electric power to the power conditioner based on the configuration state detected by the first detection switch ;
The storage battery unit is provided with a second detection switch,
In the unconnected state, the second detection switch includes a second attachment state in which a second cover for protecting the inside of the storage battery unit is attached to the storage battery unit, and a second cover in the unconnected state. A power storage system that selectively detects a second non-attached state in which the cover is not attached to the storage battery unit . The storage battery unit is provided with a hole,
The power conditioner is provided with a locking portion that engages with the storage battery unit using the hole in order to change the configuration state of the power storage system to the connected state.
The power storage system according to claim 9 , wherein a part or all of the connection structure includes the hole and the locking portion. The first detection switch is
A lever configured to contact the locking portion in the connected state and not to contact the locking portion in the non-connected state;
Detecting the connected state when the lever is in contact with the locking portion, claim 10 in which the lever comprises a first detection circuit for detecting a case where the non-connected state not in contact with the locking portion The power storage system described in 1. The power storage system according to claim 11 , wherein the first detection switch is provided in the storage battery unit. The first detection switch is provided in the power conditioner,
The first detection switch further includes a first cover in which a first cover for protecting the inside of the power conditioner is attached to the power conditioner in the non-connected state, and the first detection switch in the non-connected state. The power storage system according to any one of claims 9 to 11 , wherein the first cover selectively detects a first non-attached state in which the first cover is not attached to the power conditioner. The power storage system according to any one of claims 9 to 13 , wherein when the first detection switch detects the connected state, the control unit performs a process for supplying power to the power conditioner. The power conditioner is provided with a door for protecting the inside of the power conditioner,
The door is configured to be openable and closable,
The power storage system further includes:
A third detection switch for selectively detecting an open state in which the door is open and a closed state in which the door is closed;
The control unit performs a process for supplying power to the power conditioner when the first detection switch detects the connection state and the third detection switch detects the closed state. The power storage system according to any one of 9 to 13 . Wherein, when the first detection switch detects the non-connection state, in any one of claims 9 to 13 for processing in order to the power conditioner power supply to is not performed The electricity storage system described. The power storage system according to any one of claims 1 to 16 , wherein the number of the power conditioners included in the power storage system is one, and the number of the storage battery units included in the power storage system is two or more.

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