Power systems and management methods

The power system with a battery management system addresses the challenges of controlling and identifying individual battery modules by enabling independent measurement and connection/disconnection, facilitating the reuse of batteries and extending their usefulness.

JP2026108564APending Publication Date: 2026-06-30THE BOEING CO

Patent Information

Authority / Receiving Office
JP · JP
Patent Type
Applications
Current Assignee / Owner
THE BOEING CO
Filing Date
2025-12-05
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Multi-module battery systems face challenges in controlling, using, and identifying the health and performance of individual battery modules, particularly when they exhibit varying or unknown characteristics, which can lead to system failure or degraded operation.

Method used

A power system with a battery management system that includes a control system, measurement circuits, and switching circuits for each battery module, allowing independent measurement and connection/disconnection of modules within the system, enabling module-specific performance parameter acquisition and management.

Benefits of technology

Enables the successful reuse of batteries at the end of their lifespan by isolating and measuring individual modules, ensuring appropriate voltage and current handling without physical dismantling, thereby extending the battery system's usefulness.

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Abstract

This provides a method for managing the operation of a power system that includes multiple battery modules. [Solution] The power system includes, for each battery module 210 of the battery system, a module interface device 212 having a switching circuit 350 that operates to connect and disconnect the battery module to the distribution network independently of other battery modules in the battery system, and a control system operably coupled to each module interface device. The control system commands the module interface devices of a first subset of battery modules to connect the first subset of battery modules to the distribution network, and commands the module interface devices of a second subset of battery modules to disconnect the second subset of battery modules from the distribution network.
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Description

Technical Field

[0004] ,

[0001]

[0001] The disclosed invention generally relates to managing the operation of a power system that includes a plurality of battery modules.

Background Art

[0002]

[0002] A battery system can incorporate a plurality of battery modules to provide an overall battery function and performance with respect to an electrical load or power source. A multi-module battery system can present significant challenges with regard to controlling, using, and identifying the health and performance of individual battery modules. Such challenges can be more significant in use cases where the battery modules of the battery system exhibit various or unknown performance. For example, a used battery with unknown health and performance can cause a failure or damage to the battery system and associated equipment, or can cause a degraded operation of the battery system and an electrical load or power source connected to the battery system.

Summary of the Invention

[0003]

[0003] In one example, a power system includes a battery system that includes a plurality of battery modules, and a power distribution network for the battery system that includes a cathode-side interface and an anode-side interface. The power system further includes, for each battery module of the battery system, a measurement circuit operable to measure one or more performance parameters of that battery module, and a switching circuit operable to connect and disconnect that battery module to and from the power distribution network independently of other battery modules of the battery system, each module interface device. The power system further includes a control system operably coupled to each module interface device.

[0004]

[0004] The control system is configured to acquire target values ​​for performance parameters for the battery system. For each battery module of the battery system, the control system is configured to acquire module-specific measurements of the performance parameters via the measurement circuit of the module interface device of that battery module. Based on the target values ​​for the performance parameters and the module-specific measurements of the performance parameters acquired for at least each battery module of a first subset of the battery modules, the control system is configured to select a first subset of battery modules of the battery system connected to the power distribution network.

[0005]

[0005] The control system is configured to instruct the module interface device of each battery module in the first subset to connect the battery module to the power distribution network via the switching circuit of the module interface device. The control system is configured to instruct the module interface device of each battery module in the second subset of battery modules of the battery system that are not included in the first subset to disconnect the battery module from the power distribution network via the switching circuit of the module interface device. [Brief explanation of the drawing]

[0006] [Figure 1]

[0006] This is a schematic diagram showing an exemplary power system. [Figure 2]

[0007] This is a schematic diagram showing several further embodiments of a portion of the power system in Figure 1. [Figure 3]

[0008] This is a schematic diagram showing several further embodiments of an exemplary module interface device for an exemplary battery module. [Figure 4A]

[0009] Figures 4A, 4B, 4C, and 4D are flowcharts illustrating exemplary methods for managing the operation of a power system. [Figure 4B] Figures 4A, 4B, 4C, and 4D are flowcharts illustrating exemplary methods for managing the operation of a power system. [Figure 4C] Figures 4A, 4B, 4C, and 4D are flowcharts illustrating exemplary methods for managing the operation of a power system. [Figure 4D] Figures 4A, 4B, 4C, and 4D are flowcharts illustrating exemplary methods for managing the operation of a power system. [Figure 5]

[0010] This is a schematic diagram showing an exemplary computing system that may form part of the control system shown in Figure 1. [Modes for carrying out the invention]

[0007]

[0011] As the use of battery-powered electric vehicles and other battery-powered devices increases, so too can the available supply of used batteries that can be reused before their eventual recycling or disposal. Battery reuse offers the potential to extend the lifespan of batteries and potentially delay or even avoid the need for recycling or disposal of such batteries. A market for secondary uses of used batteries may exist, including, for example, alternative energy storage systems for micro and mega power systems. Energy harvesting systems that could benefit from battery reuse include, for example, wind, solar, hydro, wave, and tidal power generation.

[0008]

[0012] Multi-module battery systems can present significant challenges in controlling, using, and identifying the health and performance of individual battery modules. These challenges may become more pronounced in use cases where the battery modules of the battery system exhibit varying or unknown performance characteristics. For example, a used battery with unknown health and performance characteristics could cause failure or damage to the battery system and associated equipment, or cause degraded operation of the battery system and any electrical loads or power supplies connected to it.

[0009]

[0013] This specification discloses a power system and a method for managing the operation of the power system that provides the possibility of successfully reusing batteries at the end of their lifespan. The power system features a module interface device that can operate to isolate individual battery modules within a battery system independently and measure the performance parameters of each individual battery module independently. Thus, battery modules of unknown and diverse health and performance can be measured and isolated within the context of a multi-module battery system, thereby potentially enabling the successful reuse of modules at the end of their lifespan. The power system and the associated battery system management method enable an operator to construct appropriate voltage and current handling of a battery installation without the physical dismantling of batteries at the end of their lifespan, thereby potentially extending the usefulness of the battery system until the last battery module in the system becomes inoperable.

[0010]

[0014] Figure 1 is a schematic diagram showing an exemplary power system 100, which includes a battery system 110 and a battery management system 112 for managing the operation of the battery system. The power system 100 may include, or interact with, a power source 114 and an electrical load 116, as schematically shown in Figure 1.

[0011]

[0015] The battery system 110 includes a plurality of battery groups identified in Figure 1 by reference no. 118. Each battery group identified by reference no. 118 may include one or more battery modules, as will be described in more detail with reference to Figure 2. The battery groups of the battery system 110 may be interconnected by the power distribution network of the power system 100. The power distribution network includes various electrical paths, including a cathode-side electrical path 124 and an anode-side electrical path 126. The power distribution system 123 may include further components that interconnect the battery groups and their battery modules, as will be described in more detail with reference to Figure 2.

[0012]

[0016] The battery management system 112 includes a control system 120 that can operate to control the operation of the battery system 110 and other components of the battery management system, as described herein. As an example, the battery management system 112 may store electrical energy 102 received from a power source 114 in the battery system 110 via one or more electrical paths 104. In this example, the power system 100 may include a power system interface 122 that can be operated by the control system 120 to guide the electrical energy 102 received from the power source 114 to the battery system 110 via the electrical paths 104 for storage via the distribution system 123. In the example in Figure 1, the power system interface 122 is electrically coupled to the battery system 110 via a cathode-side electrical path 124 and an anode-side electrical path 126 of the distribution network 123. The cathode-side electrical path 124 includes the cathode-side interface 125 of the distribution network 123, and the anode-side electrical path 126 includes the anode-side interface 127 of the distribution network.

[0013]

[0017] In another example, the battery management system 112 may supply electrical energy 106 stored in the battery system 110 to an electrical load 114 via one or more electrical paths 108 through the power system interface 122. In this example, the power system interface 122 can be operated by the control system 120 to guide the electrical energy 106 supplied by the battery system 110 via electrical paths 124 and 126 of the distribution system 123 to the electrical load 116 via the electrical path 108.

[0014]

[0018] In the example shown in Figure 1, the control system 120 includes a power system manager 130 and a group manager, identified by reference number 132, for each battery group identified by reference number 118. The power system manager 130 can control the operation of the power system interface 122 via one or more communication links 134. One or more communication links 134 may include wired and / or wireless links. Furthermore, the power system manager 130 can control the operation of the group managers identified by reference number 132 via a communication link 136. The communication link 136 may include one or more wired and / or wireless links.

[0015]

[0019] The battery groups of the battery system 110 may be arranged in series and / or parallel configurations. For example, the battery system 110 may include battery groups 118-1.1 to 118-1.N arranged in a first series configuration 140-1 between the cathode-side electrical path 124 and the anode-side electrical path 126. In this case, the term "N" in the identifier "1.N" may refer to any appropriate number of battery groups in the first series configuration 140-1. For example, the term "N" in the identifier "1.N" may refer to multiple battery groups in the first series configuration 140-1. For example, the first series configuration 140-1 may include two, three, four, five or more, ten or more, twenty or more, and so on. As another example, the first series configuration 140-1 may include a single battery group represented in Figure 1 as battery group 118-1.1.

[0016]

[0020] Furthermore, in this example, the battery system 110 may include battery groups 118-2.1 to 118-2.N arranged in a second series configuration 140-2 between the cathode-side electrical path 124 and the anode-side electrical path 126. In this case, the term "N" in the identifier "2.N" may refer to any appropriate number of battery groups in the second series configuration 140-2. For example, the term "N" in the identifier "2.N" may refer to multiple battery groups in the second series configuration 140-2. For example, the second series configuration 140-2 may include two, three, four, five or more, ten or more, twenty or more, and so on. As another example, the second series configuration 140-2 may include a single battery group represented in Figure 1 as battery group 118-2.1. It will be understood that the number of battery groups in the second series configuration 140-2 may be the same as or different from the number of battery groups in the first series configuration 140-1. For example, the second series configuration 140-2 may contain more or fewer battery groups compared to the first series configuration 140-1.

[0017]

[0021] Furthermore, in this example, the battery system 110 may include battery groups 118-M.1 to 118-MN arranged in a series configuration 140-M between the cathode-side electrical path 124 and the anode-side electrical path 126. In this case, the term "N" in the identifier "MN" may refer to any appropriate number of battery groups in the series configuration 140-M. For example, the term "N" in the identifier "MN" may refer to multiple battery groups in the series configuration 140-M. For example, the series configuration 140-M may include two, three, four, five or more, ten or more, twenty or more, and so on. As another example, the series configuration 140-M may include a single battery group represented in Figure 1 as battery group 118-M.1. Again, it will be understood that the number of battery groups in the Mth series configuration 140-M may be the same as, or different from, the number of battery groups in the first series configuration 140-1 and the second series configuration 140-2.

[0018]

[0022] Further, in this example, the first series configuration 140-1 of battery groups 118-1.1 to 118-1.N, the second series configuration 140-2 of battery groups 118-2.1 to 118-2.N, and the Mth series configuration 140-M of battery groups 118-M.1 to 118-M.N are arranged in a parallel configuration 142 between the cathode-side electrical path 124 and the anode-side electrical path 126. In that case, the term "M" in the identifier "M.N" can refer to any suitable number of series configurations of battery groups arranged in the parallel configuration 142-M.

[0019]

[0023] In some examples, the battery system 110 can include a single series configuration of one or more battery groups identified as the first series configuration 140-1 in FIG. 1. In this example, the second series configuration 140-2 and the Mth series configuration 140-M can be omitted. Further, in this example, there is no parallel configuration 142 because the battery system 110 includes a single series configuration of battery groups (e.g., 140-1).

[0020]

[0024] Each battery group of the battery system 110 can be associated with a respective group manager of that battery group, a cathode-side interface device 150, and an anode-side interface 152. For example, battery group 118-1.1 is associated with group manager 132-1.1, cathode-side interface device 150, and anode-side interface 152. Collectively, each battery group, and the respective group manager, cathode-side interface device 150, and anode-side interface associated with that battery group form a module unit 144. An example of an instance of the module unit 144 is shown in FIG. 1 with respect to battery group 118-1.1.

[0021]

[0025] The operation of each battery group in the battery system 110 can be managed, at least partially, by the respective group manager of its module unit 144. For example, the operation of battery group 118-1.1 can be managed, at least partially, by group manager 132-1.1. Each group manager can communicate with its respective battery group via one or more electrical links 154 and selectively exchange electrical energy. One or more electrical links 154 may include one or more communication links and one or more electrical paths, as will be described in more detail herein with reference to Figure 2. As further examples, the operation of battery group 118-1.1 may be managed at least partially by group manager 132-1.1, the operation of battery group 118-2.1 may be managed at least partially by group manager 132-2.1, the operation of battery group 118-1.N may be managed at least partially by group manager 132-1.N, the operation of battery group M.1 may be managed at least partially by group manager 132-M.1, and the operation of battery group 118-MN may be managed at least partially by group manager 132-MN.

[0022]

[0026] The power system manager 130 may be operably coupled to each group manager via one or more electrical links, identified by reference no. 136 in Figure 1, which coordinate the operation of the battery groups of the battery system 110, and which may include one or more communication links and one or more electrical paths, as will be described in more detail herein with reference to Figure 2. In some examples, the power system manager 130 may be operably coupled to group manager 132-1.1 via electrical link 136-1.1, to group manager 132-1.N via electrical link 136-1.N, to group manager 132-2.1 via electrical link 136-2.1, to group manager 132-2.N via electrical link 136-2.N, to group manager 132-M.1 via electrical link 136-MN, and to group manager 132-MN via electrical link 136-MN.

[0023]

[0027] Further, each group manager may manage the operation of its associated cathode-side interface device 150 and anode-side interface 152 of the module unit 144. For example, each group manager may communicate with its respective cathode-side interface device 150 via one or more communication links 156 and may communicate with its respective anode-side interface 152 via one or more communication links 158. The communication links 156 and 158 may each include a wired and / or wireless communication link.

[0024]

[0028] In each series configuration of the battery groups (e.g., 140-1 to 140-M), the first battery group of the series configuration is electrically coupled to the cathode-side electrical path 124 via the cathode-side interface device 150 of the module unit 144, and the last battery group of the series configuration is electrically coupled to the anode-side interface path 126 via the anode-side interface 152 of the module unit 144. In each series configuration of a battery group (e.g., 140-1 to 140-M) including a plurality of battery groups, as will be described in more detail with reference to FIG. 2, each adjacent pair of battery groups is electrically coupled to each other via the anode-side interface 152 and the cathode-side interface device 150.

[0025]

[0029] FIG. 2 is a schematic diagram showing in more detail an exemplary portion 200 of the power system of FIG. 1. The portion 200 includes an example of the first series configuration 140-1 of FIG. 1. This includes two battery groups, namely, battery group 118-1.1 and battery group 118-1.2. In this example, battery group 118-1.2 is an example of battery group 118-1.N of FIG. 1. In that case, the term "N" refers to the second battery group of the series configuration 140-1.

[0026]

[0030] Battery group 118-1.1 includes multiple battery modules. In this example, the multiple battery modules include battery modules 210-1.1, 210-1.2, 210-1.3 through 210-1.N. Here, the term "N" in the identifier "1.N" can refer to any appropriate number of battery modules in battery group 118-1.1. Battery group 118-1.2 includes multiple battery modules. In this example, the multiple battery modules include battery modules 210-2.1, 210-2.2, 210-2.3 through 210-2.N. Here, the term "N" in the identifier "2.N" can refer to any appropriate number of battery modules in battery group 118-2.1. Battery group 118-2.1 may have the same or a different number of battery modules as battery group 118-1.1. The total number of battery modules in a series configuration of a battery group, such as series configuration 140-1, may be selected to provide a target voltage or at least a target voltage between the cathode-side electrical path 124 and the anode-side electrical path 126 of the power distribution network 123 in Figure 1, for a given battery module voltage or set of battery module voltages.

[0027]

[0031] As will be further described with reference to Figure 3, for each battery module of the battery system, each module interface device identified by reference no. 212 is electrically coupled to the cathode and anode terminals of that battery module. The module interface devices described herein form part of the battery management system 112 in Figure 1. For example, with respect to battery group 118-1.1, module interface device 212-1.1 is electrically coupled to battery module 210-1.1, module interface device 212-1.2 is electrically coupled to battery module 210-1.2, module interface device 212-1.3 is electrically coupled to battery module 210-1.3, and module interface device 212-1.N is electrically coupled to battery module 210-1.N. Similarly, with respect to battery group 118-1.2, module interface device 212-2.1 is electrically coupled to battery module 210-2.1, module interface device 212-2.2 is electrically coupled to battery module 210-2.2, module interface device 212-2.3 is electrically coupled to battery module 210-2.3, and module interface device 212-2.N is electrically coupled to battery module 210-2.N.

[0028]

[0032] The module interface devices of each battery group may be electrically coupled in series with each other by an intermodule interconnect 214, as will be described in more detail with reference to Figure 3. The first module interface device on the cathode side of each battery group may be electrically coupled with the cathode interface device 150 by a cathode interconnect 216. The last module interface device on the anode side of each battery group may be electrically coupled with the anode interface device 152 by an anode interconnect 218. The cathode interface device 150 of the first battery group in series configuration 140-1 (e.g., 118-1.1) may be electrically coupled with the cathode electrical path 124 by a cathode interconnect 220. The last battery group in series configuration 140-1 (e.g., 118-1.2) may be electrically coupled with the anode electrical path 126 by an anode interconnect 222. Between two battery groups in series configuration 140-1, the anode-side interface device 152 of the first battery group (e.g., 118-1.1) can be electrically coupled to the cathode-side interface device 150 of the second battery group (118-1.2) by the interconnect 224.

[0029]

[0033] Each group manager is operably coupled to its corresponding battery group module interface device via a set of one or more electrical connections identified by reference numeral 230 in Figure 2. As will be described in more detail herein, each module interface device includes a switching circuit and a measurement circuit. The switching circuit and measurement circuit are operable by the group manager of the module interface device via the set of electrical connections 230. Each group manager may, via the set of electrical connections 230 to the module interface device, instruct the switching circuit of its battery group module interface device to connect or disconnect the battery module of the module interface device to the power distribution network 123 in Figure 1. Furthermore, each group manager may, via the set of electrical connections 230 to the module interface device, instruct the measurement circuit of its battery group module interface device to measure one or more performance parameters of the battery module of the module interface device.

[0030]

[0034] For example, in Figure 2, group manager 132-1.1 is operably coupled to module interface device 212-1.1 by set of electrical connections 230-1.1, to module interface device 212-1.2 by set of electrical connections 230-1.2, to module interface device 212-1.3 by set of electrical connections 230-1.3, and to module interface device 212-1.N by set of electrical connections 230-1.N. Similarly, group manager 132-1.2 is operably coupled to module interface device 212-2.1 by set of electrical connections 230-2.1, to module interface device 212-2.2 by set of electrical connections 230-2.2, to module interface device 212-2.3 by set of electrical connections 230-2.3, and to module interface device 212-2.N by set of electrical connections 230-2.N.

[0031]

[0035] Furthermore, each group manager is operably coupled to the cathode-side interface device 150 of its corresponding battery group via one or more sets of electrical connections identified by reference number 232. For example, group manager 132-1.1 is operably coupled to the cathode-side interface device 150 of battery group 118-1.1 via set of electrical connections 232-1.1, and group manager 132-1.2 is operably coupled to the cathode-side interface device 150 of battery group 118-1.2 via set of electrical connections 232-1.2. The cathode-side interface device 150 may include switches operable to connect and disconnect the battery groups to and from the power distribution network 123 in Figure 1. For example, each group manager may, via a set of electrical connections 232 between the cathode-side interconnect 214 and either the cathode-side interconnect 220 or the interconnect group 224, instruct the cathode-side interface device 150 of the corresponding battery group to the power distribution system to connect or disconnect the battery group.

[0032]

[0036] Furthermore, each group manager is operably coupled to the anode-side interface device 152 of its corresponding battery group via one or more sets of electrical connections identified by reference number 234. For example, group manager 132-1.1 is operably coupled to the anode-side interface device 152 of battery group 118-1.1 via set of electrical connections 234-1.1, and group manager 132-1.2 is operably coupled to the anode-side interface device 152 of battery group 118-1.2 via set of electrical connections 234-1.2. The anode-side interface device 152 may include switches operable to connect and disconnect the battery groups to and from the power distribution network 123 in Figure 1. For example, each group manager may, via set of electrical connections 234 between the anode-side interconnect 218 and either the anode-side interconnect 222 or the interconnect 224, instruct the anode-side interface device 152 of its corresponding battery group to connect or disconnect the battery groups to the power distribution system.

[0033]

[0037] Figure 3 is a schematic diagram showing further multiple embodiments of the module interface device and battery module of Figures 1 and 2, as will be explained with reference to the module interface device 212-1.1 electrically coupled to the battery module 210-1.1.

[0034]

[0038] Each battery module includes one or more sets of battery cells 302, with reference to battery module 210-1.1, as schematically shown in Figure 3. Each battery module includes a cathode terminal 310 and an anode terminal 312.

[0035]

[0039] Each module interface device includes a battery-side cathode interface 320 and a battery-side anode interface 322, as schematically shown in Figure 3 with reference to module interface device 212-1.1. The module interface device is electrically coupled to the cathode terminal 310 of the battery module via the battery-side cathode interface 320. The module interface device is electrically coupled to the anode terminal 312 of the battery module via the battery-side anode interface 322.

[0036]

[0040] Each module interface device further includes a system-side cathode interface 330 and a system-side anode interface 332. The system-side cathode interface 330 is electrically coupled to the module-side cathode terminal 310, for example, by the cathode bus 334 of the module interface device. The system-side cathode interface 330 of the module interface device is electrically coupled to either the intermodule interconnect 214 or the cathode-side interconnect 216, as previously described with reference to Figure 2. The system-side anode interface 332 is electrically coupled to the module-side anode terminal 322, for example, by the anode bus 336 of the module interface device. The system-side anode interface 332 of the module interface device is electrically coupled to either the intermodule interconnect 214 or the anode-side interconnect 218, as previously described with reference to Figure 2.

[0037]

[0041] Each module interface device further includes a measurement circuit 340 and a switching circuit 350. The measurement circuit 340 is operable by the control system 120 in Figure 1 to independently acquire module-specific measurements of the battery module's performance parameters. The module interface device is electrically coupled to the battery module. For example, the measurement circuit 340 is electrically coupled between the cathode bus 334 and the anode bus 336, thereby enabling the measurement circuit to measure the battery module's performance parameters between the cathode terminal 310 and the anode terminal 312. In some examples, the measurement circuit 340 may include one or more electrical components (e.g., resistors) that indicate resistance. The battery module's performance parameters can be measured across the resistor. Several examples of module-specific performance parameters that can be measured by the measurement circuit 340 with respect to a battery module include stored energy, energy storage capacity, voltage, current, and power. As an example, a group manager (e.g., 132-1.1 in Figure 2) is operably coupled to a module interface device 212-1.1 via one or more electrical connections 342 of a set of electrical connections 230-1.1. This allows the group manager to instruct a measurement circuit 340 of the module interface device to acquire module-specific measurements of performance parameters. The performance parameters of the battery module measured by the measurement circuit 340 can be acquired by the group manager via one or more electrical connections 342. Such measurements can be acquired by the power system manager 130 of the control system 120 via a communication link 136. Alternatively or further, the communication link 136 may take the form of an electrical path in this example. The electrical path enables the power system manager 130 to measure or acquire measurements of the performance parameters of the battery module.

[0038]

[0042] The switching circuit 350 is operable by the control system 120 in Figure 1 to independently connect and disconnect the battery module from the power distribution network 123 in Figure 1. For example, a group manager (e.g., 132-1.1 in Figure 2) is operably coupled to the module interface device 212-1.1 via one or more electrical connections 352 of a set of electrical connections 230-1.1. This allows the group manager to instruct the switching circuit 350 of the module interface device to connect or disconnect the battery module from the power distribution network. For example, the switching circuit 350 is located along a cathode bus 334 between the module-side cathode terminal 310 and the system-side cathode terminal 330. The switching circuit 350 can connect and disconnect the module-side cathode terminal to the system-side cathode terminal by switching the cathode bus open and closed. Alternatively, the switching circuit 350 is located along an anode bus 336 between the module-side anode terminal 312 and the system-side anode terminal 332. The switching circuit 350 can open and close the anode bus switch to connect and disconnect the module-side anode terminal to the system-side anode terminal.

[0039]

[0043] Figure 3 schematically shows an exemplary electrical routing configuration 390 of the module interface device 212-1.1 when the switching circuit 350 is operated to disconnect the battery module 210-1.1 from the distribution network 123 in Figure 1, and an exemplary electrical routing configuration 392 of the module interface device 212-1.1 when the switching circuit 350 is operated to connect the battery module 210-1.1 to the distribution network 123. When the battery module 210-1.1 is disconnected from the distribution network 123, the electrical routing configuration 390 may include or utilize an electrical routing 394 between the system-side cathode interface 330 and the system-side anode interface 332 that bypasses the battery module 210-1.1. As schematically shown with respect to the electrical path configuration 390, the electrical path 394 may allow battery module 210-1.1 to be disconnected from the distribution network 123 and other battery modules in the battery group including battery module 210-1.1, while other battery modules in the battery group are electrically connected to each other and to the distribution network 123 across the module interface device 212-1.1. When battery module 210-1.1 is connected to the distribution network 123, the electrical path configuration 392 may include or utilize a cathode bus 334 that electrically connects the system-side cathode interface 330 to the cathode terminal 310, and an anode bus 336 that electrically connects the system-side anode interface 332 to the anode-side terminal 312.

[0040]

[0044] Figures 4A, 4B, 4C, and 4C are flowcharts illustrating exemplary methods 400 for managing the operation of a power system, such as the power system 100 in Figure 1. For example, methods 400 and various operations of the methods may be performed by a computing system of one or more computing devices forming part of the control system 120 in Figure 1, as will be described in more detail with reference to Figure 5.

[0041]

[0045] Referring to Figure 4A, in 402, the method may include establishing power system profile data for the power system. As will be described in more detail with reference to Figure 5, the power system profile data established in 402 may be stored in a data storage machine that can be accessed by the control system 120 in Figure 1. As part of establishing the power system profile data in 402, the method may include performing operations 404 to 434 in Figure 4A.

[0042]

[0046] In 404, the method may include identifying a system configuration of a power system, including a battery system (e.g., 110 in Figure 1) and its components, a battery management system (e.g., 112 in Figure 1) and its components, and a power distribution system (e.g., 123 in Figure 1) and its components. As an example, a series configuration of battery groups (e.g., 140-1 to 140-M), a parallel configuration of battery groups (e.g., 142), electrical interconnections between battery groups and battery modules, a cathode-side electrical path 124, a cathode-side interface 125, an anode-side electrical path 126, and an anode-side interface 127 may be identified.

[0043]

[0047] In some examples, the system components identified in 404 may include a data representation of the nodal network of the power system. In this case, a node represents a component including battery groups, battery modules, and interfaces 125, 127, 150, and 152, and the electrical paths of the distribution network 123 are represented by interconnections between or within the nodes. Furthermore, the system configuration identified in 404 may include a data representation of the nodal network of logical components. In this case, a node represents a component of the battery management system 112, including module interface devices, battery group manager 132, interfaces 150 and 152, power system interface 122, and power system manager 130. The system configuration identified in 404 may be stored as data that forms part of the power system profile data for the power system.

[0044]

[0048] In some cases, the system configuration may be identified in 404 based on user input received via the operator interface. For example, power system personnel may define multiple aspects of the system configuration identified in 404. Furthermore or alternatively, the control system 120 may be configured to programmatically identify multiple aspects of the system configuration, such as by performing a network trace of the distribution network 123 and / or the logical network. These networks operably connect the module interface devices, the group manager, and the power system manager of the battery management system.

[0045]

[0049] In 406, the method may include identifying each battery group of a battery system. For example, each battery group of a power system may be identified within the system configuration identified in 404. In some examples, each battery group within the system configuration of a power system can be identified using user input received via an operator interface. For example, a power system worker may provide user input via an operator interface that defines multiple embodiments of each battery group.

[0046]

[0050] In 408, the method may include establishing a battery group identifier for each battery group of the battery system identified in 406. Each battery group identified in 406 and each battery group identifier established in 408 may be stored as data that forms part of the power system profile data for the power system. For example, each battery group identifier may be associated with a node representing that battery group in the system configuration. For example, power system personnel may provide user input via an operator interface to associate each battery group identifier with each battery group of the power system.

[0047]

[0051] In 410, the method may include identifying a group manager for each battery group in the battery system. For example, a group manager may be identified for each battery group identified in 406. In some examples, a group manager for each battery group can be identified using user input received via an operator interface. For example, a power system worker may provide user input via an operator interface linking each battery group to its respective group manager.

[0048]

[0052] In 412, the method may include establishing a group manager identifier for each group manager identified in 410. Each group manager identified in 410 and each group manager identifier established in 412 may be stored as data that forms part of the power system profile data for the power system. For example, each group manager identifier may be associated with a node representing a group manager within a system component. For instance, power system personnel may provide user input via an operator interface to associate each group manager identifier with each group manager in the power system.

[0049]

[0053] In 414, the method may include associating each group manager identifier for a group manager with a corresponding battery group identifier for a group of batteries managed by that group manager. For example, each group manager identifier may be associated with a corresponding battery group identifier in power system profile data. In some examples, a group manager identifier may be associated with a corresponding battery group identifier based on user input received from power system personnel via an operator interface.

[0050]

[0054] In 416, the method may include establishing battery group profile data for each battery group identified in 406. As part of establishing the battery group profile data in 416, the method may include performing operations 418 to 434 in Figure 4A.

[0051]

[0055] In 418, the method may include identifying the battery group configuration of each battery group in the battery system. For example, each battery group configuration may include one or more battery modules. The battery group configuration may indicate the number of battery modules in the battery group and the respective order of the battery modules within the battery group between the cathode-side interface and the anode-side interface of the battery group. The battery group configuration identified in 418 may be stored in the battery group profile data established in 416 as data that forms part of the power system profile data established in 402. In some examples, user input from power system personnel may be provided via an operator interface to identify each battery group configuration in 418.

[0052]

[0056] In 420, the method may include identifying each battery module in each battery group of a battery system. In 422, the method may include establishing a battery module identifier for each battery module in a battery system. The battery module identifier may be associated with a node representing a battery module in the battery group configuration identified in 418 and / or the system configuration identified in 404.

[0053]

[0057] In 424, the method may include associating each battery module identifier of a battery module with the corresponding battery group identifier of the battery group to which the battery module is a member. For example, each battery module identifier may be associated with the corresponding battery group identifier in battery group profile data. In some examples, battery module identifiers may be associated with the corresponding battery group identifier based on user input received from power system personnel via an operator interface.

[0054]

[0058] In 426, the method may include identifying a module interface device corresponding to each battery module. In some examples, the module interface device may be identified in 426 based on user input received from power system personnel via an operator interface for a battery module. In 428, the method may include establishing a module interface device identifier for each module interface device in the power system. The module interface device identifier may be associated with a node representing that module interface device in the battery group configuration identified in 418 and / or the system configuration identified in 404.

[0055]

[0059] In 430, the method may include associating each module interface device identifier with a corresponding battery module identifier for the battery module to which the module interface device is operably coupled. For example, each module interface device identifier may be associated with a corresponding battery module identifier in battery group profile data. In some examples, a module interface device identifier may be associated with a corresponding battery group identifier based on user input received from power system personnel via an operator interface.

[0056]

[0060] In 432, the method may include obtaining a battery module performance specification for each battery module of a battery system. The battery module performance specification may identify the battery chemical category and / or values ​​of the performance parameters of the battery module. Several examples of battery chemical categories include lithium ions, lithium iron phosphate, cobalt oxide, lithium manganese oxide, lithium nickel manganese cobalt oxide, lithium nickel cobalt oxide, lithium nickel cobalt aluminum oxide, lithium titanate, lead acid, lead acid (sealed), lead acid (flood), lead acid (absorbent glass mat), lead acid (gel / silica), etc. The values ​​of performance parameters that may form part of the battery module performance specification may take the form of ratings or stated values ​​for the battery module provided by the battery module manufacturer. Several examples of performance parameters that may form part of the battery module performance specification include energy storage capacity rating, voltage rating, current rating, power rating, etc. It will be understood that further or alternative forms of performance specifications may be obtained for battery modules in 446. In some cases, the battery module performance specifications acquired in 432 may be received as user input from power system personnel via the operator interface. The battery module performance specifications acquired in 432 may be stored as data that forms part of the battery group profile data 416.

[0057]

[0061] In 434, the method may include associating a battery module performance specification for each battery module with the battery module identifier of that battery module. For example, each battery module performance specification may be associated with a corresponding battery module identifier in battery group profile data. In some examples, the battery module performance specification may be associated with a corresponding battery module identifier based on user input received from power system personnel via an operator interface.

[0058]

[0062] Referring to Figure 4B, after establishing the power system profile data in 402 of Figure 4A, the method may include measuring one or more performance parameters of the battery system in 436. Performance parameters may be measured at the individual battery module level as module-specific measurements, at the individual group level as group-specific measurements, and at the system-wide level as system-wide measurements. Several examples of performance parameters that may be measured in 436 include stored energy, energy storage capacity, voltage, current, and power. Measuring the performance parameters of the battery system in 436 may include operations 438 to 448 in Figure 4B.

[0059]

[0063] In 438, the method may include obtaining module-specific measurements of each performance parameter for each battery module of the battery system via a measurement circuit of the module interface device of that battery module. As previously stated, several examples of performance parameters that can be measured include the battery module's stored energy, energy storage capacity, voltage, current, and power. The module-specific measurements of each performance parameter obtained in 438 for each battery module may be stored as performance data in a storage machine accessible by the control system 120. This performance data is associated with the battery module identifier of that battery module and a timestamp representing the time the measurement was performed.

[0060]

[0064] In some examples, as part of obtaining module-specific measurements in 438, the method may include, in 440, instructing the switching circuits of the battery modules in the battery system to perform the measurement procedure for each module-specific measurement. In a first example, the switching circuit of the battery module being measured may be instructed to connect the battery module to a test load in the distribution network during the measurement, while other battery modules are disconnected from the distribution network by their corresponding switching circuits. In a second example, the switching circuit of the battery module being measured may be instructed to disconnect the battery module from the distribution network during the measurement, such as in a configuration in which the measurement circuit incorporates a test load.

[0061]

[0065] In 442, the method may include obtaining group-specific measurements of each performance parameter for each battery group. As previously mentioned, several examples of performance parameters that can be measured include the battery group's stored energy, energy storage capacity, voltage, current, and power. For each battery module, the group-specific measurements of each performance parameter obtained in 442 may be stored as performance data in a storage machine accessible by the control system 120, associated with the battery group identifier of that battery group.

[0062]

[0066] In some examples, as part of obtaining group-specific measurements in 442, the method may include, in 444, for each performance parameter, combining module-specific measurements of the performance parameter obtained in 438 for that battery module of the battery group, according to the configuration of the battery group identified in 418, to obtain a group-specific measurement of that performance parameter. For example, in a series configuration of two or more battery modules of a battery group, the voltage of the battery group is equal to the sum of the voltages of the individual battery modules. However, since combining battery modules of different voltages and / or capacities can cause problems in certain configurations or damage the battery system, the group-specific measurements obtained in 442 may be obtained based on module-specific measurements without actually connecting the battery modules of the battery group to the distribution network at the same time.

[0063]

[0067] In 446, the method may include obtaining system-wide measurements of each performance parameter for the battery system. As previously stated, several examples of performance parameters that can be measured include the battery system's stored energy, energy storage capacity, voltage, current, and power. For the battery system, the system-wide measurements of each performance parameter obtained in 446 may be stored as performance data in a storage machine accessible to the control system 120.

[0064]

[0068] In some examples, as part of obtaining a system-wide measurement in 446, the method may include, in 448, for each performance parameter, combining group-specific measurements of that performance parameter obtained in 442 for the battery group of the battery system, according to the configuration of the battery system, to obtain a system-wide measurement of that performance parameter. For example, in a series configuration of two or more battery groups of a battery group, the voltage of the battery system is equal to the sum of the voltages of the individual battery groups. However, since combining battery groups of different voltages and / or capacities can cause problems in certain configurations or damage the battery system, the system-wide measurement obtained in 446 may be obtained based on module-specific measurements and corresponding group-specific measurements without actually connecting the battery group to the distribution network at the same time.

[0065]

[0069] From operation 436 in Figure 4B, the process flow of method 400 may proceed to operation 456 in Figure 4C. Furthermore, from operation 436 in Figure 4B and operation 402 in Figure 4A, the process flow of method 400 may proceed to operation 450.

[0066]

[0070] In 450, the method may include identifying a change to the battery system. Several examples of a change to the battery system may include adding one or more battery modules to the battery system, replacing one or more battery modules in the battery system, removing one or more battery modules from the battery system, and / or reconfiguring one or more battery modules of the battery system for the distribution network. In some examples, a change to the battery system may be identified in 450 based on user input received from power system personnel via an operator interface. For example, the user input may indicate one or more battery modules and / or one or more battery groups that have been added to, removed from, replaced in, or reconfigured within the battery system.

[0067]

[0071] In 452, the method may include returning to operation 402 in Figure 4A to update the power system profile data in response to the identification of a change in the battery system in 450. By returning to operation 402 in Figure 4A, the power system profile data may be established for at least the change identified in operation 450, including performing some or all of operations 404 to 434.

[0068]

[0072] In 454, the method may include returning to operation 436 in Figure 4B to obtain updated measurements of one or more performance parameters of the battery system, depending on the changes to the battery system identified in 450. By returning to operation 436 in Figure 4B, measurements of performance parameters reflecting the changes to the battery system may be obtained, including performing some or all of operations 438 to 448.

[0069]

[0073] Referring back to Figure 4C, in 456, the method may include obtaining target values ​​for one or more performance parameters for the battery system. The target values ​​for the performance parameters may be system-wide with respect to the battery system, group-specific with respect to individual battery groups, and module-specific with respect to individual battery modules. As part of obtaining target values ​​in 456, the method may include operations 458 to 462.

[0070]

[0074] In 458, the method may include obtaining module-specific target values ​​for each performance parameter for each battery module. As previously stated, several examples of performance parameters include stored energy, energy storage capacity, voltage, current, and power. For example, module-specific target values ​​for a particular voltage (e.g., 4, 8, 12, 16, 28, 64 volts, etc.) may be obtained for some or all of the battery modules in a battery system. In some examples, the module-specific target values ​​for each performance parameter may be operator-defined target values ​​and may be obtained as user input received from personnel via the operator interface. The module-specific target values ​​for each performance parameter obtained for a battery module may be stored as data associated with the battery module identifier of that battery module.

[0071]

[0075] In 460, the method may include obtaining group-specific target values ​​for each battery group, for each battery group. As previously mentioned, several examples of performance parameters include stored energy, energy storage capacity, voltage, current, and power. For example, group-specific target values ​​for a particular voltage (e.g., 44, 72, 1500 volts, etc.) may be obtained for some or all of the battery groups in a battery system. In some examples, the group-specific target values ​​for each performance parameter may be operator-defined target values ​​and may be obtained as user input received from personnel via the operator interface. The group-specific target values ​​for each performance parameter obtained for a battery group may be stored as data associated with the battery group identifier of that battery module.

[0072]

[0076] In 462, the method may include obtaining system-wide measurements of each performance parameter for the battery system. As previously mentioned, several examples of performance parameters include stored energy, energy storage capacity, voltage, current, and power. The system-wide target value for each performance parameter may correspond to a value suitable for a particular power source (e.g., 114 in Figure 1) and / or electrical load (e.g., 116 in Figure 1). As an example, a system-wide target value for voltage (e.g., 1500 volts) may be obtained. In some examples, the system-wide target value for each performance parameter may be an operator-defined target value and may be obtained as user input received from the operator via the operator interface. The system-wide target values ​​for each performance parameter obtained for a battery group may be stored as data associated with the battery group identifier of that battery module.

[0073]

[0077] In operation 464, the method may include identifying each battery module in the battery system as available or unavailable. As part of operation 464, the method may include, in operation 466, comparing the measured value of each performance parameter for the battery module to a module-specific target value for that performance parameter for the battery module. For example, a battery module that shows a measured value of a performance parameter that meets or is within the threshold range of the module-specific target value for that performance parameter may be identified as available. In this example, a battery module that does not show a measured value of a performance parameter that meets or is within the threshold range of the module-specific target value for that performance parameter may be identified as unavailable. It should be understood that the threshold ranges in the above examples may indicate whether the measured value is greater than or equal to a target value for a particular performance parameter (e.g., energy storage capacity, current, power). In operation 464, battery modules identified as available or unavailable may be stored in a data storage machine as data associated with the corresponding battery module identifier of those battery modules.

[0074]

[0078] In operation 468, the method may include identifying each battery group in the battery system as available or unavailable. As part of operation 468, the method may include, in operation 470, comparing a measured value of each performance parameter for the battery group with a group-specific target value for that performance parameter for the battery group. For example, a battery group that shows a measured value of a performance parameter that meets or is within the threshold range of the group-specific target value for that performance parameter may be identified as available. In this example, a battery group that does not show a measured value of a performance parameter that meets or is within the threshold range of the group-specific target value for that performance parameter may be identified as unavailable. It should be understood that the threshold ranges in the above examples may indicate whether the measured value is greater than or equal to a target value for a particular performance parameter (e.g., energy storage capacity, current, power). Battery groups identified as available or unavailable in operation 468 may be stored in a data storage machine as data associated with the corresponding group identifier of those battery groups.

[0075]

[0079] In 472, the method may include selecting a first subset of battery modules of a battery system connected to the distribution network of a power system. The first subset of battery modules selected in 472 may be stored in a data storage machine as data associated with the corresponding battery module identifiers of those battery modules. In some examples, the first subset of battery modules may be selected in 472 in response to user input received from power system personnel via an operator interface.

[0076]

[0080] Furthermore, as shown in 474, a first subset of battery modules selected in 472 may be based on target values ​​of performance parameters obtained in 456, including some or all of module-specific, group-specific, and system-wide target values. As shown in 476, a first subset of battery modules selected in 472 may be based on measured values ​​of performance parameters obtained in 436 of Figure 4B. For example, a first subset of battery modules may be selected based on module-specific measured values ​​of one or more performance parameters obtained for each battery module in at least a first subset of battery modules. In this example, battery modules may be selected to satisfy one or more module-specific target values, one or more group-specific target values, and / or one or more system-wide target values. As illustrated in 478, a first subset of battery modules selected in 472 may be selected based on the power system configuration specified in 404, including the battery group configuration specified for each battery group specified in 418.

[0077]

[0081] In some cases, a first subset of battery modules selected in 472 may be selected from battery modules identified as available in 464. For example, the first subset of battery modules selected in 472 may not include any battery modules identified as unavailable in 464. Alternatively, the first subset of battery modules selected in 472 may be selected from a group of batteries identified as available in 468. For example, the first subset of battery modules selected in 472 may not include any battery modules that form part of a group of batteries identified as unavailable in 468.

[0078]

[0082] As an exemplary example of operation 472, in which the power system includes a parallel configuration of a first series battery module and / or battery group and a second series battery module and / or battery group, the first subset of battery modules may be selected as follows: that is, the voltage of the first series configuration is equal to the voltage of the second series configuration, and furthermore, the battery system has a target system-wide capacity with respect to the total system current, power, and energy storage capacity. From operation 472 in Figure 4C, the process flow of method 400 may proceed to operation 480 in Figure 4D.

[0079]

[0083] Referring to Figure 4D, in operation 480, the method may include operating the power system to achieve target values ​​for one or more performance parameters. As part of operation 480, the method may include performing some or all of operations 482 to 488.

[0080]

[0084] In 482, the method may include, for each battery module in the first subset selected in 472, instructing the module interface device of that battery module to connect the battery module to the power distribution network via the switching circuit of the module interface device. For example, the power system manager 130 in Figure 1 may instruct a group manager (e.g., of group manager 132) operably coupled with the module interface device to instruct the module interface device to connect the battery modules of the battery system 110 to the power distribution network 123 via the switching circuit.

[0081]

[0085] In 484, the method may include, for each battery module in a second subset of battery modules of a battery system not included in a first subset, instructing the module interface device of that battery module to disconnect the battery module from the power distribution network via the switching circuit of the module interface device. For example, the power system manager 130 in Figure 1 may instruct a group manager (e.g., of group manager 132) operably coupled with the module interface device to instruct the module interface device to disconnect the battery modules of battery system 110 from the power distribution network 123 via the switching circuit.

[0082]

[0086] In several examples where the power system includes switchable group interfaces, such as the cathode-side group interface 150 and the anode-side group interface 152, the method may include instructing the group interfaces to connect or disconnect the battery groups to the distribution network. For example, in 486, the method may include instructing the cathode-side and anode-side group interfaces of each battery group, which includes a first subset of battery modules selected in 472, to connect the battery group to the distribution network. For example, a battery group group manager may be instructed by the power system manager to instruct the cathode-side and anode-side group interfaces to connect the battery group to the distribution network. In some examples, in 488, the method may include instructing the cathode-side and anode-side group interfaces of each battery group, which does not include a first subset of battery modules, to disconnect the battery group from the distribution network. However, in several other examples, operation 488 is not performed in the following cases: In other words, this is the case when a series configuration of battery groups does not depend on the cathode and anode group interfaces for connecting one or more battery modules to the power distribution network.

[0083]

[0087] From operation 480 in Figure 4D, the method may proceed to operation 450 in Figure 4B for monitoring changes to the battery system and / or operation 456 in Figure 4C for monitoring updates to target values ​​for one or more performance parameters.

[0084]

[0088] In some cases, the methods and operations described herein may be performed by a computing system of one or more computing devices. Such methods and operations may be implemented as computer application programs or services, as application programming interfaces (APIs), as libraries, and / or as other computer program products.

[0085]

[0089] Figure 5 is a schematic diagram showing further multiple embodiments of the control system 120 of Figure 1. In the example of Figure 5, the control system 120 includes a computing system 500 of one or more computing devices 502 capable of performing multiple methods and operations described herein, including the method 400 of Figures 4A to 4D. The computing system 500 is an example of a product 501.

[0086]

[0090] The computing system 500 includes a logic machine 510, a storage machine 512, and an input / output (I / O) subsystem 514. The computing system 500 is shown in a simplified form in Figure 5. The computing system 500 or its computing device 502 may take the form of one or more personal computers, server computers, network computing devices, mobile computing devices, and / or other computing devices, as several examples.

[0087]

[0091] The logic machine 510 includes one or more physical logic devices configured to execute instructions, such as instructions 516 stored in the storage machine 512. For example, the logic machine 510 may execute instructions 516, which are part of one or more applications, services, programs, routines, libraries, objects, components, data structures, or other logical configurations. Instructions 516 may be executed by the logic machine 510 to perform several methods and operations as described herein. These methods and operations may include performing one or more tasks, implementing data types, transforming the state of one or more components, achieving one or more technical effects, or otherwise reaching one or more desired results.

[0088]

[0092] The logic machine 510 may include one or more processors configured to execute software instructions. Furthermore, or alternatively, the logic machine 510 may include one or more hardware or firmware logic machines configured to execute hardware or firmware instructions. The processors of the logic machine 510 may be single-core or multi-core, and the instructions executed by the processors may be configured for sequential, parallel, and / or distributed processing. Individual components of the logic machine 510 may be distributed across two or more separate devices that may be located remotely and / or configured to perform collaborative processing. Multiple embodiments of the logic machine 510 may be executed by remotely accessible network computing devices that are virtualized and configured as a cloud computing configuration.

[0089]

[0093] The storage machine 512 includes one or more physical devices configured to hold instructions 516 and data 518 that can be executed by the logic machine 510 in order to perform some of the methods and operations described herein. When such methods and operations are performed, the storage machine 512 may be transformed, for example, to hold various data in the data 518.

[0090]

[0094] The storage machine 512 may include removable and / or built-in devices. The storage machine 512 may include, among other forms of storage, optical memory, semiconductor memory (e.g., RAM, EPROM, EEPROM, etc.), and / or magnetic memory (e.g., hard disk drives, floppy disks, tape drives, MRAM, etc.). The storage machine 512 may include volatile devices, non-volatile devices, dynamic devices, static devices, read / write devices, read-only devices, random access devices, sequential access devices, location addressable devices, file addressable devices, and / or content addressable devices.

[0091]

[0095] Multiple embodiments of the logic machine 510 and the storage machine 512 may be integrated into one or more hardware logic components. Such hardware logic components may include, for example, field-programmable gate arrays (FPGAs), programmatic and application-specific integrated circuits (PASICs / ASICs), programmatic and application-specific standard products (PSSPs / ASSPs), systems-on-a-chip (SOCs), and complex-programmable logic devices (CPLDs).

[0092]

[0096] Figure 5 provides a more detailed schematic representation of instruction 516, which includes an operator interface program 520, a system manager program 522, and a group manager program 524. The term “program” may be used to describe one aspect of a computing system 500 implemented to perform a particular function. Such a program may be instantiated by a logic machine 510 that executes instruction 516 held by a storage machine 512. Programs described herein may encompass individuals or groups of executable files, data files, libraries, drives, scripts, database records, etc. Multiple instances of programs described herein may be instantiated from the same portion of instruction 516. For example, multiple instances of the group manager program 524 may be instantiated for each group manager in Figure 1.

[0093]

[0097] When executed by the logic machine 510, the operator interface program 520 may provide an operator interface 526. The operator interface 526 allows an operator to control the power system 100 in Figure 1, including the battery system 110 and the battery management system 112. In some examples, the operator interface 526 may be presented to a client computing device 528 operably coupled to the computing system 500 via an I / O interface device 514. As an example, the operator interface 526 may include, or take the form of, a graphical user interface presented to the client device 528. In another example, the operator interface 526 may be presented via one or more input and / or output devices of the I / O interface device 514, as described herein. User input from a power system operator may be received via the operator interface 526 as previously described with reference to method 400 in Figures 4A to 4D.

[0094]

[0098] When executed by the logic machine 510, the system manager program 522 may provide the power system manager 130 shown in Figure 1. Therefore, it will be understood that the power system manager 130 may include multiple hardware configurations (e.g., the logic machine 510, the storage machine 512, and the I / O subsystem 514) of the computing system 500 running the system manager program 522. Furthermore, in some examples, the operator interface program 520 may form part of the system manager program 522.

[0095]

[0099] When executed by the logic machine 510, the group manager program 524 can provide each instance of the group manager 132 in Figure 1. Therefore, it will be understood that group managers 132-1.1 to 132-1.N, 132-2.1 to 132-2.N, 132-M.1 to 132-MN, etc., may include multiple hardware configurations of the computing system 500 running the group manager program 524 (e.g., logic machine 510, storage machine 512, I / O subsystem 514) to instantiate multiple instances of the group manager program. In some examples, each group manager of the battery management system 112 may be implemented as a separate computing device of the computing system 500 running each instance of the group manager program 524. In such examples, the power system manager 130 may be implemented as a separate computing device of the computing system 500 running the system manager program 522, rather than as a computing device running the group manager program 524. As another example, the program of instruction 516 may be executed by the same computing device or a set of two or more computing devices of computing system 500.

[0096]

[0100] Figure 5 provides a more detailed schematic representation of the data 518, including power system profile data 530, performance data 532, and performance parameters 534. While various examples of the data 518 are described herein, it will be understood that the data 518 may include further forms of data not shown in Figure 5.

[0097]

[0101] The power system profile data 530 is an example of power system profile data that may be established in operation 402 of Figure 4A. The power system profile data 530 may include a power system identifier 540 that identifies a power system 100 in an operating environment which may include multiple power systems. The power system profile data 530 may include power system configuration data 542 associated with the power system identifier 540. The power system configuration data 542 may include a power system configuration 544 and multiple battery group profile data sets 546 corresponding to multiple battery groups of a battery system.

[0098]

[0102] Power system configuration 544 is an example of a power system configuration identified in operation 404 of Figure 4A. Power system configuration 544 may include a data representation of the physical, electrical, and logical configuration of power system 100, including the position of each component of power system 100 relative to other components in a physical, electrical, and logical context. For example, power system map 554 may identify the position of each battery group in battery system 110, including the order of each battery group in series configuration 140-1, 140-2, 140-M, and parallel configuration 142.

[0099]

[0103] The battery group profile dataset 546 may include a set of battery group profile data 550 for each battery group in the battery system 110. The battery group profile data 550 is an example of battery group profile data that may be established in operation 416 of Figure 4A. The battery group profile data 550 may include a battery group identifier 552 that identifies a battery group within the battery system 110, which includes multiple battery groups. The battery group identifier 552 is an example of a battery group identifier that may be established in operation 408 of Figure 4A. The battery group profile data 550 may include a group manager identifier 554 that identifies the group manager associated with the battery group identified by the battery group identifier 552. The group manager identifier 554 is an example of a group manager identifier that may be established in operation 412 of Figure 4A. As previously described in operation 414 of Figure 4A, each group manager identifier may be associated with a corresponding battery group identifier. For example, in the example in Figure 1, in the power system 100, group manager 132-1.1 is associated with battery group 118-1.1, and group manager 132-1.N is associated with battery group 118-1.N. The associations established or recorded between each battery group and each group manager by the respective instances of battery group profile data 550 and identifiers 552 and 554 enable the control system 120 to identify a group manager that can operate to control the operation of a particular battery group.

[0100]

[0104] The battery group profile data 550 may include battery group configuration data 556 for the battery group identified by the battery group identifier 552. The battery group configuration data 556 may include a battery group configuration 558 and a set of multiple battery module profile datasets 560.

[0101]

[0105] The battery group configuration 558 may include a data representation of the physical, electrical, and logical configuration of the battery group identified by the battery group identifier 552, including the respective positions of each battery module in the battery group relative to other battery modules in the battery group within the physical, electrical, and logical contexts. For example, the battery group configuration 558 may identify the position of each battery module in the battery group identified by the battery group identifier 552, including the order of each battery module in the battery group. The battery group configuration 558 is an example of the battery group configuration identified in operation 418 of Figure 4A.

[0102]

[0106] The battery module profile dataset 560 may contain each instance of the battery module profile data 562 for each battery module in the battery group. The battery module profile dataset 562 may contain a battery module identifier 564 that identifies a battery module within the battery group identified by a battery group identifier 552 that includes multiple battery modules. The battery module identifier 564 is an example of a battery module identifier established in operation 422 of Figure 4A.

[0103]

[0107] The module profile data 562 includes a module interface device identifier 566 that identifies a module interface device operably coupled to the battery module identified by the battery module identifier 564. The battery interface device identifier 566 is an example of a module interface device identifier established in operation 428 of Figure 4A. The association of the module interface device identifier 566 with the battery module identifier 564 in the module profile data 562 enables the control system 120 to determine which module interface device controls the operation of each battery module of the battery system 110. As previously described in operation 430 of Figure 4A, each module interface device identifier may be associated with a corresponding battery module identifier.

[0104]

[0108] The module profile data 562 may include a battery module performance specification 568 that specifies the values ​​of one or more performance parameters 534 for the battery module identified by the battery module identifier 564. The battery module performance specification 568 is an example of a battery module performance specification obtained in operation 432 of Figure 4A. Multiple examples of performance parameters 534 may include stored energy 570, energy storage capacity 572, voltage 574, current 576, power 578, and other performance parameters 580 (e.g., years, charge cycles, discharge cycles, temperature, etc.). In the context of the battery module performance specification 568, the performance parameters 534 may represent the listed performance parameters of the battery module (e.g., the manufacturer's assessment of the battery module).

[0105]

[0109] In contrast to the battery module performance specifications 568 that may be provided for each battery module of the battery system 110, the control system 120 may measure the actual performance of the battery system 110, which may be stored in data 518 as performance data 532. Performance data 532 is an example of the measured values ​​of performance parameters obtained in operation 436 of Figure 4B. It will be understood that the actual performance of the battery system 110, as represented by the performance data 532, including the actual performance of various battery groups and battery modules of the battery system, may differ from the battery module performance specifications provided in 568. For example, factors such as age, charge cycles, discharge cycles, temperature, malfunctions, and damage may affect the actual performance of a battery module, thereby affecting the actual performance of the battery groups and the battery system 110.

[0106]

[0110] As previously described with reference to Method 400 in Figures 4A to 4D, the performance parameters 534 can be measured by the control system 120 at the individual battery module level, the individual battery group level, and the battery system level. Multiple examples of performance data 532 may include battery module-specific measurements 580 of the performance parameters 534 for each battery module of the battery system 110, battery group-specific measurements 582 of the performance parameters 534 for each battery group of the battery system 110, and system-wide measurements 584 of the performance parameters 534 for the battery system 110. The battery module-specific measurements 580 may include measurements of the stored energy 570, stored capacity 572, voltage 574, current 576, power 578, and other performance parameters 580 for each battery module of the battery system 110. The battery group-specific measurements 582 may include measurements of the stored energy 570, stored capacity 572, voltage 574, current 576, power 578, and other performance parameters 580 for each battery group of the battery system 110. The system-wide measurements 584 may include measurements of the stored energy 570, stored capacity 572, voltage 574, current 576, power 578, and other performance parameters 580 for the battery system 110.

[0107]

[0111] The performance data 532 may include battery module-specific target values ​​586 for the performance parameters 534 for each battery module of the battery system 110, battery group-specific target values ​​588 for the performance parameters 534 for each battery group of the battery system 110, and system-wide target values ​​590 for the performance parameters 534 for the battery system 110. For each battery module of the battery system 110, the battery module-specific target values ​​586 may include target values ​​for each performance parameter of performance parameter 534, including stored energy 570, stored capacity 572, voltage 574, current 576, power 578, and other performance parameters 580. For each battery group of the battery system 110, the battery group-specific target values ​​588 may include target values ​​for each performance parameter of performance parameter 534, including stored energy 570, stored capacity 572, voltage 574, current 576, power 578, and other performance parameters 580. For the battery system 110, the overall system target value 590 may include target values ​​for each of the performance parameters 534, including stored energy 570, storage capacity 572, voltage 574, current 576, power 578, and other performance parameters 580.

[0108]

[0112] For each battery module of the battery system 110, the control system 120 may compare the battery module-specific measurement value 580 of that battery module with the battery module-specific target value 586 of that battery module, using a performance parameter criterion from among the performance parameters 534, in order to determine whether the battery module-specific measurement value 580 for each performance parameter meets or falls within the threshold range of the battery module-specific target value 586 for each performance parameter. Based on this comparison, the control system 120 may determine whether each battery module is operating within an acceptable range. For example, based on whether each battery module is operating within an acceptable range, the control system 120 may determine whether to start or stop each battery module of the battery system 110.

[0109]

[0113] In some cases, a battery module-specific target value 586 may be initialized by the control system 120 based on a battery module performance specification 568 identified for that battery module. Alternatively, the battery module-specific target value 586 may be defined by the operator via user input received through the operator interface 526. Furthermore, in some cases, the battery module-specific target value 586 may be programmed by the control system 120 based on or in accordance with the fact that the battery module-specific measurement value 580 reflects the actual performance of each battery module in the battery system 110. It will be understood that the battery module-specific measurement value 580 and the battery module-specific target value 586 may differ between or among the battery modules in the battery system 110 due to differences between or among the battery modules.

[0110]

[0114] For each battery group of the battery system 110, the control system 120 may compare the battery group-specific measured value 582 for that battery group with the battery group-specific target value 588 for that battery group, using a performance parameter criterion from among the performance parameters 534, in order to determine whether the battery module-specific measured value 582 for each performance parameter satisfies or falls within the threshold range of the battery group-specific target value 588 for each performance parameter. Based on this comparison, the control system may determine whether each battery group is operating within an acceptable range.

[0111]

[0115] In some examples, a battery group-specific target value 588 may be initialized by the control system 120 based on a battery group performance specification 568 identified for that battery group. Alternatively, the battery group-specific target value 588 may be defined by the operator via user input received through the operator interface 526. Furthermore, in some examples, the battery group-specific target value 588 may be programmed by the control system 120 based on the fact that the battery group-specific measurement value 582 reflects the actual performance of each battery group in the battery system 110. It will be understood that the battery group-specific measurement value 582 and the battery group-specific target value 588 may differ between or within the battery groups of the battery system 110, for example, depending on the battery module configuration of each battery group.

[0112]

[0116] The control system 120 compares the system-wide measured values ​​584 of the battery system 110 with the system-wide target values ​​590 of the battery system, using a performance parameter criterion from among the performance parameters 534, in order to determine whether the system-wide measured values ​​584 for each performance parameter meet or are within the threshold range of the system-wide target values ​​590 for each performance parameter. Based on this comparison, the control system may determine whether the battery system 110 is operating within an acceptable range.

[0113]

[0117] In some examples, the overall system target value 590 may be initialized by the control system 120 based on the aggregation of battery group performance specifications 568 identified for each battery module of the battery system. Alternatively, the overall system target value 590 may be defined by the operator via user input received through the operator interface 526. As an example, the overall system target value 590 may be defined, at least in part, by the performance parameters or other characteristics of the power supply 114 and / or electrical load 116. Furthermore, in some examples, the overall system target value 590 may be programmed by the control system 120 based on the fact that the overall system measurement 584 reflects the actual performance of the battery system 110.

[0114]

[0118] Data 518 may include a registry 592 of available battery modules 594 (e.g., identified in operation 464 of Figure 4C) and unavailable battery modules 595 (e.g., identified in operation 464 of Figure 4C) from the entire set of all battery modules in the battery system 110. The registry 592 may further identify a first subset 596 of the battery modules of the battery system 110 selected in operation 472 of Figure 4C, and a second subset 597 of battery modules not included in the first subset 596. In this example, the first subset 596 includes battery module identifiers connected to the power distribution network of the power system, and the second subset 597 includes battery module identifiers not connected to the power distribution network of the power system.

[0115]

[0119] Data 518 may be output by the operator program 520 for presentation via the operator interface 526. For example, the input / output interface device 514 and / or client device 528 may include one or more output devices, such as a graphical display, an audio speaker, or an indicator valve. Data 518 may be presented by one or more output devices. The input / output interface device 514 and / or client device 528 may include one or more input devices. User input may be provided to the computing system 500 by an operator through one or more input devices. Several examples of input devices include a keyboard, a computer mouse, a touch display, a microphone, a controller device, and an instrument panel. Furthermore, the input / output interface device 514 may include one or more communication interface devices that enable the computing system 500 or the computing device 502 of the computing system to communicate with and / or exchange electrical energy with other devices, including the client device 528, the module interface device, the group manager 132, the power manager 130, the power system interface 122, the cathode-side interface 150, and the anode-side interface 152. Such communication may be transmitted via wired and / or wireless links of one or more communication networks. Communication networks may include personal area networks, local area networks, and wide area networks (e.g., the Internet).

[0116]

[0120] Furthermore, this disclosure includes multiple configurations, which are based on the following multiple embodiments.

[0117]

[0121] Example 1. A power system comprising: a battery system including a plurality of battery modules; a power distribution network for the battery system including a cathode interface and an anode interface; each module interface device including a measurement circuit operable to measure one or more performance parameters of each battery module of the battery system, and a switching circuit operable to connect and disconnect the battery module to the power distribution network independently of other battery modules of the battery system; and a control system operablely coupled to each module interface device, wherein the control system acquires target values ​​of the performance parameters for the battery system, acquires module-specific measurements of the performance parameters for each battery module of the battery system via the measurement circuit of the module interface device of the battery module, and the performance parameters A power system configured to select a first subset of the battery modules of the battery system connected to the power distribution network based on a target value and module-specific measurements of the performance parameters obtained for each battery module of at least a first subset of the battery modules; for each battery module in the first subset, to instruct the module interface device of that battery module to connect that battery module to the power distribution network via the switching circuit of the module interface device; and for each battery module in a second subset of the battery modules of the battery system not included in the first subset, to instruct the module interface device of that battery module to disconnect that battery module from the power distribution network via the switching circuit of the module interface device.

[0118]

[0122] Example 2. The power system according to Embodiment 1, wherein the plurality of battery modules of the battery system are organized into two or more battery groups, each of which a battery group comprises two or more battery modules from the plurality of battery modules, and the control system further includes a group manager that can operate to instruct each module interface device, which is electrically coupled to the battery modules of the battery group, to connect and disconnect the battery modules to and from the power distribution network via the switching circuit of the module interface device, for each battery group of the battery system.

[0119]

[0123] Example 3. The power system according to Embodiment 2, wherein the target value of the performance parameter for the battery system is a battery-group-specific target value of the performance parameter for each battery group of the battery system.

[0120]

[0124] Example 4. The power system according to Embodiment 2, wherein the first battery group of the two or more battery groups is arranged in parallel with the second battery group of the two or more battery groups by the power distribution network, and each battery module of each of the two or more battery groups is arranged in series with the other battery modules of that battery group by the power distribution network.

[0121]

[0125] Example 5. The power system according to Embodiment 2, wherein the first battery group of the two or more battery groups is arranged in series with the second battery group of the two or more battery groups by the power distribution network.

[0122]

[0126] Example 6. The power system according to Embodiment 1 or 2, wherein the target value of the performance parameter for the battery system is the system-wide target value of the performance parameter for the battery system.

[0123]

[0127] Example 7. The power system according to Embodiment 1 or 2, wherein the target value of the performance parameter for the battery system is a module-specific target value of the performance parameter for each battery module of the battery system.

[0124]

[0128] Example 8. The power system according to any one of Examples 1 to 7, wherein the performance parameters include one or more of stored energy, energy storage capacity, voltage, current, and power.

[0125]

[0129] Example 9. The power system according to any one of Examples 1 to 8, wherein the plurality of batteries in the battery system have two or more different performance specifications among the plurality of batteries that differ with respect to the battery chemical category and / or the performance parameters.

[0126]

[0130] Example 10. The power system according to any one of Examples 1 to 9, wherein the target value of the performance parameter is a target value specified by the operator.

[0127]

[0131] Example 11. A method for managing the operation of a power system performed by a computing system of one or more computing devices, comprising: obtaining a target value for a performance parameter for a battery system of the power system, the battery system comprising a plurality of battery modules; obtaining a module-specific measurement of the performance parameter for each battery module of the battery system via a measurement circuit of a module interface device operably coupled to the battery module; selecting a first subset of the battery modules of the battery system to be connected to a power distribution network of the battery system based on the target value of the performance parameter and the module-specific measurement of the performance parameter obtained for each battery module of at least a first subset of the battery modules; for each battery module of the first subset, instructing the module interface device of that battery module to connect the battery module to the power distribution network via a switching circuit of the module interface device; and for each battery module of a second subset of the battery modules of the battery system not included in the first subset, instructing the module interface device of that battery module to disconnect the battery module from the power distribution network via the switching circuit of the module interface device.

[0128]

[0132] Example 12. The method according to Embodiment 11, wherein the plurality of battery modules in the battery system are organized into two or more battery groups, each of which includes two or more battery modules from the plurality of battery modules, and the target value of the performance parameter for the battery system is a group-specific target value of the performance parameter for each battery group of the battery system.

[0129]

[0133] Example 13. The method according to Embodiment 12, wherein the first battery group of the two or more battery groups is arranged in parallel with the second battery group of the two or more battery groups by the power distribution network, and each battery module of each of the two or more battery groups is arranged in series with the other battery modules of that battery group by the power distribution network.

[0130]

[0134] Example 14. The method according to Embodiment 12, wherein the first battery group of the two or more battery groups is arranged in series with the second battery group of the two or more battery groups by the power distribution network.

[0131]

[0135] Example 15. The method according to any one of Examples 11 to 14, wherein the target value of the performance parameter for the battery system is a battery-group-specific target value of the performance parameter for each battery group of the battery system.

[0132]

[0136] Example 16. The method according to any one of Examples 11 to 14, wherein the performance parameter for the battery system is a module-specific target value of the performance parameter for each battery module of the battery system.

[0133]

[0137] Example 17. The method according to any one of Examples 11 to 16, wherein the performance parameters include one or more of stored energy, energy storage capacity, voltage, current, and power.

[0134]

[0138] Example 18. The method according to any one of Examples 11 to 17, wherein the plurality of batteries in the battery system have two or more different performance specifications among the plurality of batteries that differ with respect to the battery chemical category and / or the performance parameters.

[0135]

[0139] Example 19. A manufactured product for managing the operation of a power system, comprising a data storage machine of the computing system storing instructions executable by the logic machine of the computing system, wherein the instructions are to obtain a target value for a performance parameter for a battery system of the power system, the battery system comprising a plurality of battery modules, to obtain a module-specific measurement of the performance parameter for each battery module of the battery system via a measurement circuit of a module interface device operably coupled with the battery module, and based on the target value of the performance parameter and the module-specific measurement of the performance parameter obtained for each battery module of at least a first subset of the battery modules, the battery A manufactured product capable of performing the following actions: selecting a first subset of the battery modules of the battery system connected to the power distribution network of the battery system; for each battery module in the first subset, instructing the module interface device of that battery module to connect the battery module to the power distribution network via the switching circuit of the module interface device; and for each battery module in a second subset of the battery modules of the battery system not included in the first subset, instructing the module interface device of that battery module to disconnect the battery module from the power distribution network via the switching circuit of the module interface device.

[0136]

[0140] Example 20. The product according to Example 19, wherein the plurality of batteries in the battery system have two or more different performance specifications among the plurality of batteries that differ with respect to the battery chemical category and / or the performance parameters, the performance parameters including one or more of the following: stored energy, energy storage capacity, voltage, current, and power.

[0137]

[0141] The configurations and / or approaches described herein are substantially illustrative, and it should be understood that these particular embodiments or examples should not be considered restrictive, as numerous variations are possible. A particular routine or method described herein may represent one or more of any number of processing strategies. Thus, the various actions illustrated and / or described may be performed in the illustrated and / or described order, or in a different order, or simultaneously, or omitted. Similarly, the order of the processes described above may be changed.

[0138]

[0142] The subject matter of this disclosure includes all novel and non-obvious combinations and subcombinations of the various processes, systems, and configurations disclosed herein, as well as other features, functions, operations, and / or characteristics, and any and all equivalents thereof.

Claims

1. A power system (100), Battery system (110) including multiple battery modules (210-1.1, 210-1.N), A power distribution network (123) for the battery system (110), including a cathode interface (125) and an anode interface (127), Each battery module (210) of the battery system (110) includes a module interface device (212) that includes a measurement circuit (340) capable of measuring one or more performance parameters (534) of the battery module (210), and a switching circuit (350) capable of connecting and disconnecting the battery module (210) to the power distribution network (123) independently of the other battery modules of the battery system (110), and Each module interface device (212) is operably coupled to a control system (120), and the control system (120) is To obtain target values ​​(586, 588, 590) for the performance parameters (534) for the battery system (110), For each battery module (210) of the battery system (110), module-specific measured values ​​(580) of the performance parameters (534) are obtained via the measurement circuit (340) of the module interface device (212) of the battery module (210). Based on the target values ​​(586, 588, 590) of the performance parameter (534) and the module-specific measured values ​​(580) of the performance parameter (534) obtained for each battery module (210) of the first subset (472) of the battery modules, the first subset (472) of the battery modules of the battery system (110) connected to the power distribution network (123) is selected. For each battery module (210) of the first subset (472), the module interface device (212) of that battery module (210) is instructed to connect that battery module (210) to the power distribution network (123) via the switching circuit (350) of the module interface device (212), and A power system (100) is configured to instruct the module interface device (212) of each battery module (210) of a second subset (484) of the battery modules of the battery system (110) that are not included in the first subset (472) to disconnect the battery module (210) from the power distribution network (123) via the switching circuit (350) of the module interface device (212).

2. The plurality of battery modules (210-1.1, 210-1.N) of the battery system (110) are organized into two or more battery groups (118-1.1, 118-1.2, 118-2.1) each of which a battery group (118) includes two or more battery modules (210-1.1, 210-1.2) of the plurality of battery modules (210). The control system (120) is The power system (100) according to claim 1, further comprising, for each battery group (118) of the battery system (110), a group manager (132) that can operate to command each module interface device (212), which is electrically coupled to the battery module (210) of the battery group (118), to connect and disconnect the battery module (210) to and from the power distribution network (123) via the switching circuit (350) of the module interface device (212).

3. The power system (100) according to claim 2, wherein the target values ​​(586, 588, 590) of the performance parameters (534) for the battery system (110) are the battery group-specific target values ​​(588) of the performance parameters (534) for each battery group (118) of the battery system (110).

4. The first battery group (118-1.1) of the two or more battery groups (118-1.1, 118-1.2, 118-2.1) is arranged in parallel (142) with the second battery group (118-1.2) of the two or more battery groups (118-1.1, 118-1.2, 118-2.1) by the power distribution network (123), The power system (100) according to claim 2, wherein each battery module (210) of each battery group (118) of the two or more battery groups (118-1.1, 118-1.2, 118-2.1) is arranged in series (140) with other battery modules of the battery group (118) by the power distribution network (123).

5. The power system (100) according to claim 2, wherein the first battery group (118-1.1) of the two or more battery groups (118-1.1, 118-1.2, 118-2.1) is arranged in series (140) with the second battery group (118-1.2) of the two or more battery groups (118-1.1, 118-1.2, 118-2.1) by the power distribution network (123).

6. The power system (100) according to claim 1, wherein the target values ​​(586, 588, 590) of the performance parameters (534) for the battery system (110) are the system-wide target value (590) of the performance parameters (534) for the battery system (110).

7. The power system (100) according to claim 1, wherein the target values ​​(586, 588, 590) of the performance parameter (534) for the battery system (110) are module-specific target values ​​(586) of the performance parameter (534) for each battery module (210) of the battery system (110).

8. The power system (100) according to claim 1, wherein the performance parameter (534) includes one or more of the following: stored energy (570), energy storage capacity (572), voltage (574), current (576), and power (578).

9. The power system (100) according to claim 1, wherein the plurality of batteries (210) of the battery system (110) have two or more different performance specifications (568) among the plurality of batteries (210) that are different with respect to the battery chemical category (568) and / or the performance parameter (534).

10. The power system (100) according to claim 1, wherein the target values ​​(586, 588, 590) of the performance parameter (534) are target values ​​defined by the operator.

11. A method for managing the operation of a power system (100) performed by a computing system of one or more computing devices, The objective is to obtain target values ​​(586, 588, 590) for performance parameters (534) for the battery system (110) of the power system (100), wherein the battery system (110) includes a plurality of battery modules (210-1.1, 210-1.N), and to obtain the target values. For each battery module (210) of the battery system (110), module-specific measurement values ​​(580) of the performance parameters (534) are obtained via a measurement circuit (340) of a module interface device (212) operably coupled to the battery module (210). Based on the target values ​​(586, 588, 590) of the performance parameter (534) and the module-specific measured values ​​(580) of the performance parameter (534) obtained for each battery module (210) of the first subset (472) of the battery modules, select the first subset (472) of the battery modules of the battery system (110) that is connected to the power distribution network (123) of the battery system (110). For each battery module (210) of the first subset (472), the module interface device (212) of that battery module (210) is instructed to connect that battery module (210) to the power distribution network (123) via the switching circuit (350) of the module interface device (212), and A method comprising, for each battery module (210) of a second subset (484) of battery modules of the battery system (110) that is not included in the first subset (472), instructing the module interface device (212) of the battery module (210) to disconnect the battery module (210) from the power distribution network (123) via the switching circuit (350) of the module interface device (212).

12. The plurality of battery modules (210-1.1, 210-1.N) of the battery system (110) are organized into two or more battery groups (118-1.1, 118-1.2, 118-2.1) each containing two or more battery modules (118-1.1, 118-1.2) of the plurality of battery modules (210-1.1, 210-1.N), The method according to claim 11, wherein the target values ​​(586, 588, 590) of the performance parameters (534) for the battery system (110) are group-specific target values ​​(588) of the performance parameters (534) for each battery group (118) of the battery system (110).

13. The first battery group (118-1.1) of the two or more battery groups (118-1.1, 118-1.2, 118-2.1) is arranged in parallel (142) with the second battery group (118-1.2) of the two or more battery groups (118-1.1, 118-1.2, 118-2.1) by the power distribution network (123), The method according to claim 12, wherein each battery module (210) of each battery group (118) of the two or more battery groups (118-1.1, 118-1.2, 118-2.1) is arranged in series (140) with other battery modules of the battery group (118) by the power distribution network (123).

14. The method according to claim 12, wherein the first battery group (118-1.1) of the two or more battery groups (118-1.1, 118-1.2, 118-2.1) is arranged in series (140) with the second battery group (118-1.2) of the two or more battery groups (118-1.1, 118-1.2, 118-2.1) by the power distribution network (123).

15. The method according to claim 11, wherein the target values ​​(586, 588, 590) of the performance parameters (534) for the battery system (110) are the battery group-specific target values ​​(588) of the performance parameters (534) for each battery group (118) of the battery system (110).

16. The method according to claim 11, wherein the target values ​​(586, 588, 590) of the performance parameter (534) for the battery system (110) are module-specific target values ​​(586) of the performance parameter (534) for each battery module (210) of the battery system (110).

17. The method according to claim 11, wherein the performance parameter (534) includes one or more of the following: stored energy (570), energy storage capacity (572), voltage (574), current (576), and power (578).

18. The method according to claim 11, wherein the plurality of batteries (210) of the battery system (110) have two or more different performance specifications (568) among the plurality of batteries (210) that are different with respect to the battery chemical category (568) and / or the performance parameter (534).

19. A manufactured product for managing the operation of a power system (100), The computing system comprises a data storage machine that stores instructions executable by the logic machine of the computing system, and the instructions are: The objective is to obtain target values ​​(586, 588, 590) for performance parameters (534) for the battery system (110) of the power system (100), wherein the battery system (110) includes a plurality of battery modules (210-1.1, 210-1.N), and to obtain the target values. For each battery module (210) of the battery system (110), module-specific measurement values ​​(580) of the performance parameters (534) are obtained via a measurement circuit of a module interface device (212) operably coupled to the battery module (210). Based on the target values ​​(586, 588, 590) of the performance parameter (534) and the module-specific measured values ​​(580) of the performance parameter (534) obtained for each battery module (210) of the first subset (472) of the battery modules, select the first subset (472) of the battery modules of the battery system (110) that is connected to the power distribution network (123) of the battery system (110). For each battery module (210) of the first subset (472), the module interface device (212) of that battery module (210) is instructed to connect that battery module (210) to the power distribution network (123) via the switching circuit (350) of the module interface device (212), and A manufactured product capable of performing the following actions: for each battery module (210) of a second subset (484) of the battery modules of the battery system (110) that is not included in the first subset (472), command the module interface device (212) of that battery module (210) to disconnect the battery module (210) from the power distribution network (123) via the switching circuit (350) of the module interface device (212).

20. The plurality of batteries (210) of the battery system (110) have two or more different performance specifications (568) among the plurality of batteries (210) that are different with respect to the battery chemical category (568) and / or the performance parameter (534), The manufactured product according to claim 19, wherein the performance parameter (534) includes one or more of the following: stored energy (570), energy storage capacity (572), voltage (574), current (576), and power (578).