Abstract: According to one embodiment, a simulation-signal generation device includes a charge/discharge-condition acquirer to acquire a charge/discharge condition of an energy-storage system; a signal-characteristic-amount acquirer to acquire a plurality of charge/discharge-signal characteristic amounts for the energy-storage system; a characteristic-signal generation processor to generate a plurality of characteristic signals respectively having the plurality of charge/discharge signal characteristic amounts, based on the plurality of charge/discharge signal characteristic amounts; and a simulation-signal generator to synthesize the plurality of characteristic signals to generate a simulation signal serving as a command signal of charge/discharge for the energy-storage system.

Abstract: Disclosed is a battery pack that is mountable in a vehicle. The battery pack includes a plurality of battery modules, and a battery case that accommodates the battery modules. The battery case includes a first frame, a second frame provided across the battery modules from the first frame, and a connection portion that connects the first frame and the second frame. The second frame is provided with a protrusion that protrudes in a direction from the first frame toward the second frame.

Abstract: An electricity storage system includes a plurality of chargeable and dischargeable battery boards, a plurality of PCSs connected to the respective battery boards, and charging and discharging the connected batteries, and a battery controller distributing a charging and discharging power value of the entire system as an instruction value to each of the PCSs at a constant cycle or at an arbitrary timing. The battery controller gives a charging and discharging instruction for a predefined test charging and discharging to the selected battery board, and distributes, to all the battery boards except the selected battery board, a value obtained by subtracting a charging and discharging power value for the test charging and discharging from a charging and discharging power value for the entire system.

Abstract: A secondary battery system and a method of arranging battery modules capable of recovering and maintaining the system performance are provided. A secondary battery system includes a battery cabinet group including a plurality of battery cabinets each comprising a plurality of battery modules connected to each other, the battery module being a replacement unit, a PCS connected to the battery cabinet group and is controlling charging and discharging thereof, and a battery controller connected to the PCS. The battery controller includes a deterioration inspecting block obtaining a characteristic of the battery modules, a numbering block numbering the battery modules in an ascending order based on the characteristics, and a re-arrangement determining block determining a re-arrangement position of the battery modules in a way that the numbers given by the numbering block are in sequence in the same battery cabinet.

Abstract: A battery monitoring device according to an embodiment monitors a state of a secondary battery block including parallel cell blocks connected in series each of which includes battery cells connected in parallel. A calculator calculates direct-current internal resistance values of the parallel cell blocks based on a differential current between first and second current values detected by a current detector, voltages of the parallel cell blocks corresponding to the first and second current values detected by a voltage detector. A determiner performs anomaly determination for the parallel cell blocks from the direct-current internal resistance values of the parallel cell blocks and a maximum value of the direct-current internal resistance values of the parallel cell blocks.

Abstract: According to one embodiment, a storage battery management device includes a chargeable/dischargeable capacity table, a controller, and a communication controller. The chargeable/dischargeable capacity table stores therein in advance a chargeable/dischargeable capacity corresponding to a temperature, a state of charge (SOC), a required charge rate or discharge rate, and a battery degradation rate of a secondary battery. The controller calculates an actual chargeable/dischargeable capacity by referring to the chargeable/dischargeable capacity table based on the temperature, the SOC, the required charge rate or discharge rate, and the battery degradation rate of the secondary battery. The communication controller informs a host device about the chargeable/dischargeable capacity of the secondary battery.

Abstract: Synchronous measuring terminals 5 synchronously measure phasor quantity D101 of a voltage/current at respective measurement points 1 and 2. A data-set creating block 91 of a short-circuit capacity monitoring device 7 creates, for each measurement cycle ?t, a data set D102 containing n pieces of data based on the phasor quantities D101 of voltage and current. A phase correcting block 92 performs a phase correction on the phasor quantity using the data set D102 to create a data set D102?, and a backward impedance estimating block 93 estimates a backward impedance D103 using the data set D102?.

Abstract: In one embodiment, a temperature management device is provided with a plurality of battery cells, power sensor(s) each of which detects the charge/discharge power of battery cell(s) at a prescribed time interval, a power representative value calculation section which calculates a power representative value of a time lapse data of the charge/discharge power(s) detected by the power sensor, temperature sensor(s) each of which detects the temperature of battery cell(s) at a prescribed time interval, a temperature representative value calculation section which calculates a temperature representative value of a time lapse data of temperature(s) detected by the temperature sensor, a radiation characteristic identification section which identifies a radiation characteristic from the temperature representative value and the power representative value, and an air conditioning setting calculation section which calculates an air conditioning setting for the battery cell(s) corresponding to the power representative value

Abstract: An electric power storage device includes an electric power storage module including a unit electric power storage portion, and a fixing member fixed to the electric power storage module. The electric power storage module includes a first exhaust port configured to discharge gas discharged from the unit electric power storage portion. The fixing member includes a fixing member body fixed to the electric power storage module and a cover member disposed on the fixing member body. The cover member is disposed on a surface of the fixing member body facing the electric power storage module. An exhaust passage, into which the gas discharged from the first exhaust port flows, is formed by the fixing member body and the cover member.

Abstract: Disclosed is a battery pack that is mountable in a vehicle. The battery pack includes a plurality of battery modules, and a battery case that accommodates the battery modules. The battery case includes a first frame, a second frame provided across the battery modules from the first frame, and a connection portion that connects the first frame and the second frame. The second frame is provided with a protrusion that protrudes in a direction from the first frame toward the second frame.

Abstract: According to one embodiment, a storage battery evaluation device includes a charging/discharging controller and a deterioration evaluator. The charging/discharging controller acquires a charging/discharging power command value, performs control to charge and discharge an energy storage device according to the charging/discharging power command value, sets a dead zone in which the charging and discharging is not performed when an absolute value of the charging/discharging power command value is equal to or smaller than a threshold, and performs control to stop the charging and discharging when the charging/discharging command value enters the dead zone. The deterioration evaluator measures a response characteristic of a voltage of the energy storage device at a time when the charging and discharging is stopped from a state in which the energy storage device is charged and discharged and evaluates a deterioration state of the energy storage device on a basis of the response characteristic.

Abstract: According to one embodiment, a storage battery device in which a plurality of battery boards are connected in parallel, each of the battery boards including a plurality of cell modules connected in series, and each of the cell modules including a battery cell, includes a performance value acquisition unit and an information generator. The performance value acquisition unit acquires a performance value of the cell module. The information generator generates rearrangement information. The rearrangement information is information for performing rearrangement of the cell module between the plurality of battery boards based on the acquired performance value of the cell module to reduce a variation in the performance value of the cell module after being rearranged in one battery board than before being rearranged.

Abstract: An electricity storage system includes a plurality of chargeable and dischargeable battery boards, a plurality of PCSs connected to the respective battery boards, and charging and discharging the connected batteries, and a battery controller distributing a charging and discharging power value of the entire system as an instruction value to each of the PCSs at a constant cycle or at an arbitrary timing. The battery controller gives a charging and discharging instruction for a predefined test charging and discharging to the selected battery board, and distributes, to all the battery boards except the selected battery board, a value obtained by subtracting a charging and discharging power value for the test charging and discharging from a charging and discharging power value for the entire system.

Abstract: A storage system includes a storage battery, a first deriver, a second deriver, and a corrector. The storage battery performs charging and discharging of electricity. The first deriver derives a first state of charge (SOC) based on a voltage of the storage battery when a current is not flowing to the storage battery. The second deriver derives a second SOC based on a battery capacity of the storage battery and an integrated value of a current flowing to the storage battery. The corrector corrects the battery capacity of the storage battery which is used by the second deriver based on a difference between the second SOC derived by the second deriver and the first SOC derived by the first deriver after the derivation of the second SOC. Furthermore, the corrector changes a correction quantity of the correction in accordance with a state of the storage battery.

Abstract: According to one embodiment, there is provided a battery apparatus including a battery management device configured to receive voltages and temperatures of cells, and detection data of a current sensor, and a measuring computer configured to calculate a characteristic value of each cell or cell module, based on the detection data acquired from the battery management device at first time intervals, and to send, the acquired detection data or the calculated characteristic value to a control device at second time intervals which are longer than the first time intervals.

Abstract: A protective frame structure includes: a lower frame; an intermediate frame that is interlinked with the lower frame and is situated above the lower frame; and an upper frame that is interlinked with the intermediate frame and is situated abobe the intermediate frame, wherein a mounting space in which a battery module is configured to be mounted is formed between the lower frame and the intermediate frame, an upper space is formed between the intermediate frame and the upper frame, and the intermediate frame is deformed upward when an external load has been applied to the protective frame structure.

Abstract: A battery pack structure includes a chamber, a cooling duct arranged outside the pack case, and a connector that communicates the chamber and the cooling duct with each other. The connector includes a first opening, which is connected with the chamber in a state of being sealed by a first sealing member, a second opening, which is connected with a cooling duct in a state of being sealed by a second sealing member, a first sealing surface, which is formed in a peripheral part of the first opening and is either a tube-shaped surface or a plane that faces a chamber inlet surface though the first sealing member, and a second sealing surface, which is formed in a peripheral part of the second opening and is a tube-shaped surface or a plane that faces a duct outlet surface through the second sealing member.

Abstract: A battery pack includes a plurality of battery modules that includes a plurality of battery cells, a battery cell holder, a second-electrode assembly including a plurality of second-electrode bus bar plates, a first-electrode assembly, and a cover. The first-electrode assembly includes a plurality of first-electrode bus bar plates, a first-electrode terminal, a second-electrode terminal connected to one of the plurality of second-electrode bus bar plates, and an inter-electrode bus bar connecting the second-electrode bus bar plate and one of the first-electrode bus bar plate and the first-electrode terminal. The first-electrode assembly is in a first pattern or a second pattern. An arrangement of the first-electrode terminal and the second-electrode terminal in the battery module differs according to the pattern of the first-electrode assembly.

Abstract: It is left to a communication terminal side to judge whether to switch communication, and appropriate switching is not performed if a communication terminal does not have a function to switch communication based on the quality of communication. A communication apparatus comprises: a data signal transmitting unit that transmits a data signal to a communication terminal; a control signal transmitting unit that transmits a control signal for establishing communication with the communication terminal; and an area control unit that restricts, to a partial area within a communication possible area that a radio wave including the data signal can reach, a communication establishment possible area that a radio wave including the control signal can reach.

Abstract: A protective frame structure includes: a lower frame; an intermediate frame that is interlinked with the lower frame and is situated above the lower frame; and an upper frame that is interlinked with the intermediate frame and is situated abobe the intermediate frame, wherein a mounting space in which a battery module is configured to be mounted is formed between the lower frame and the intermediate frame, an upper space is formed between the intermediate frame and the upper frame, and the intermediate frame is deformed upward when an external load has been applied to the protective frame structure.