Abstract: The present disclosure discloses system and method for facilitating avoiding of human errors in human error detection environment. At first, a plurality of configurations corresponding to a plurality of machines may be received. Further, a plurality of scripts may be configured corresponding to the plurality of machines based on the plurality of configurations. Further, a script, of the plurality of scripts, may be executed on a machine, of the plurality of machines. Based on the executing of the script, a message and a graphical user interface (GUI) may be displayed on the machines. Further, the message and the GUI may be customized based on the configuration of the machine. Further, the customized message and the GUI guide the user interacting with the machine to avoid the human errors.

Abstract: Disclosed is a system for indicating an operational risk profile of an organization. A data receiving module 212 receives an input data corresponding to a set of parameters associated with an operational risk profile of an organization. A data computation module 214 computes a risk profile value corresponding to each parameter. An assignment module 216 assigns a risk profiling score to the parameter based on comparison of a predefined baseline target value and the risk profile value. Further, the data computation module 214 aggregates the risk profiling score assigned to each parameter in order to derive an aggregated risk profiling score for a predefined time interval. An identification module 216 identifies a category, amongst a plurality of predefined categories, based on the aggregated risk profiling score and a predefined range associated with each category indicating a distinct operational risk profile of the organization.

Abstract: The present disclosure discloses system and method for facilitating avoiding of human errors in human error detection environment. At first, a plurality of configurations corresponding to a plurality of machines may be received. Further, a plurality of scripts may be configured corresponding to the plurality of machines based on the plurality of configurations. Further, a script, of the plurality of scripts, may be executed on a machine, of the plurality of machines. Based on the executing of the script, a message and a graphical user interface (GUI) may be displayed on the machines. Further, the message and the GUI may be customized based on the configuration of the machine. Further, the customized message and the GUI guide the user interacting with the machine to avoid the human errors.

Abstract: A reduction/oxidation (“redox”) flow battery system includes a series of electrochemical cells arranged in a cascade, whereby liquid electrolyte reacts in a first electrochemical cell (or group of cells) before being directed into a second cell (or group of cells) where it reacts before being directed to subsequent cells. The cascade includes 2 to n stages, each stage having one or more electrochemical cells. During a charge reaction, electrolyte entering a first stage will have a lower state-of-charge than electrolyte entering the nth stage. In some embodiments, cell components and/or characteristics may be configured based on a state-of-charge of electrolytes expected at each cascade stage. Such engineered cascades provide redox flow battery systems with higher energy efficiency over a broader range of current density than prior art arrangements.

Abstract: Various embodiments include a fuel cell stack including a plurality of fuel cells including a cell anode electrode, a cell electrolyte, and a cell cathode electrode and separated by a plurality of conductive interconnects and at least one material located in a cell anode electrode of the plurality of fuel cells which provides a conductive path between adjacent interconnects when the cell anode electrode between the adjacent interconnects fails.

Abstract: An interconnect for a fuel cell stack includes a first set of gas flow channels in a first portion of the interconnect, and a second set of gas flow channels in second portion of the interconnect. The channels of the first set have a larger cross sectional area than the channels of the second set.

Abstract: A redox flow battery system is provided with independent stack assemblies dedicated for charging and discharging functions. In such a system, characteristics of the charging stack assembly may be configured to provide a high efficiency during a charging reaction, and the discharging stack may be configured to provide a high efficiency during a discharging reaction. In addition to decoupling charging and discharging reactions, redox flow battery stack assemblies are also configured for other variables, such as the degree of power variability of a source or a load. Using a modular approach to building a flow battery system by separating charging functions from discharging functions, and configuring stack assemblies for other variables, provides large-scale energy storage systems with great flexibility for a wide range of applications.

Abstract: An interconnect for a fuel cell stack includes a first set of gas flow channels in a first portion of the interconnect, and a second set of gas flow channels in second portion of the interconnect.

Abstract: An interconnect for a fuel cell stack includes a first set of gas flow channels in a first portion of the interconnect, and a second set of gas flow channels in second portion of the interconnect. The channels of the first set have a larger cross sectional area than the channels of the second set.

Abstract: An interconnect for a fuel cell stack includes a first set of gas flow channels in a first portion of the interconnect, and a second set of gas flow channels in second portion of the interconnect.

Abstract: An interconnect for a fuel cell stack includes a first set of gas flow channels in a first portion of the interconnect, and a second set of gas flow channels in second portion of the interconnect. The channels of the first set have a larger cross sectional area than the channels of the second set.

Abstract: A reduction/oxidation (“redox”) flow battery system includes a series of electrochemical cells arranged in a cascade, whereby liquid electrolyte reacts in a first electrochemical cell (or group of cells) before being directed into a second cell (or group of cells) where it reacts before being directed to subsequent cells. The cascade includes 2 to n stages, each stage having one or more electrochemical cells. During a charge reaction, electrolyte entering a first stage will have a lower state-of-charge than electrolyte entering the nth stage. In some embodiments, cell components and/or characteristics may be configured based on a state-of-charge of electrolytes expected at each cascade stage. Such engineered cascades provide redox flow battery systems with higher energy efficiency over a broader range of current density than prior art arrangements.

Abstract: A plurality of fuel cell stack components, such as interconnects, seals and bypass conductors are provided. The components may be used in solid oxide fuel cell stacks or other types of fuel cell stacks.

Abstract: An interconnect for a fuel cell stack includes a first set of gas flow channels in a first portion of the interconnect, and a second set of gas flow channels in second portion of the interconnect.

Abstract: Methods and compositions for treating myocardial dysfunction or inflammation are described. The methods of the invention involve administering an agent that can inhibit lysozyme to an animal in need thereof. Preferred lysozyme inhibitors include TAC and chitobiose.

Abstract: Methods and compositions for treating myocardial dysfunction or inflammation are described. The methods of the invention involve administering an agent that can inhibit lysozyme to an animal in need thereof. Preferred lysozyme inhibitors include TAC and chitobiose.