Abstract: Systems and methods are disclosed for enterprise work sharing between source and processing locations. For example, an enterprise work share engine assigns shared work requests to a processing pharmacy for prescription verification tasks that are prerequisites for prescription fulfillment at a source pharmacy. The assigned prescription verification task is completed by a pharmacy resource at the processing pharmacy and the disposition is sent to the source pharmacy. The prescription fulfillment task is completed by a pharmacy resource at the source pharmacy in response to receiving the disposition of the prescription verification task.

Abstract: Systems and methods are disclosed for enterprise work sharing between source and processing locations. For example, an enterprise work share engine assigns shared work requests to a processing pharmacy for prescription verification tasks that are prerequisites for prescription fulfillment at a source pharmacy. The assigned prescription verification task is completed by a pharmacy resource at the processing pharmacy and the disposition is sent to the source pharmacy. The prescription fulfillment task is completed by a pharmacy resource at the source pharmacy in response to receiving the disposition of the prescription verification task.

Abstract: A system and method for determining a rate of flow of an output from a vessel. The system includes a vessel having an inlet for receiving an output produced by an output generation device, and a measuring device for measuring a first pressure, a first temperature and a second pressure and a second temperature in the vessel. The first pressure and first temperature are measured when the output generation device is in a standby mode and the second pressure and second temperature are measured when the output generation device is in an operational mode. The system includes a programmable logic controller configured to calculate a rate of flow of the output utilizing the first pressure, the first temperature, the second pressure and the second temperature.

Abstract: A system and method for determining a rate of flow of an output from a vessel. The system includes a vessel having an inlet for receiving an output produced by an output generation device, and a measuring device for measuring a first pressure and a second pressure in the vessel. The first pressure is measured when the output generation device is in a standby mode and the second pressure is measured when the output generation device is in an operational mode. The system includes a programmable logic controller configured to calculate a rate of flow of the output utilizing the first pressure and the second pressure.

Abstract: A system and method is presented for reducing a concentration of ambient air used in a feed stream to form an inerting gas in a pressure swing adsorption system. The method includes introducing ambient air into a pressure swing adsorption system to form an inerting gas, introducing the inerting gas to a large volume of atmosphere, thereby inerting at least a portion of the large volume of atmosphere to form an inerted atmosphere, and removing a portion of the inerted atmosphere and introducing the portion of inerted atmosphere to the pressure swing adsorption system to form the inerting gas, thereby reducing an amount of ambient air utilized to form the inerting gas in the pressure swing adsorption system.

Abstract: A gas separation vessel has a vessel shell and a partition therein. A first bed support is mounted between the partition and the shell, and a second bed support is mounted within the partition to define a second bed space. First and second ports on the vessel shell beneath the bed supports permit gas flow between the bed spaces and the exterior of the vessel shell. A separation medium is placed in the bed spaces. A feed gas is introduced into the vessel to flow through the first bed and then through the second bed to separate at least one component of the feed gas from the other intermixed gases. Output gas is then collected from the vessel. The vessel may have a L:D ratio of not more than 4:1.

Abstract: A method of autonomously sharing a load between at least two output generation devices, the method including: providing at least two output generation devices, wherein the at least two output generation devices operate autonomously with respect to one another and the at least two output generation devices are in fluid communication with output receiving means adapted to receive output generated by the at least two output generation devices; monitoring output generated by the output generation devices; and cycling each of the at least two devices through an activated mode and a standby mode independently of one another in an automated manner to meet an output demand thereby sharing a load demand between the at least two output generation devices.

Abstract: A system and method for determining a rate of flow of an output from a vessel. The system includes a vessel having an inlet for receiving an output produced by an output generation device, and a measuring device for measuring a first pressure and a second pressure in the vessel. The first pressure is measured when the output generation device is in a standby mode and the second pressure is measured when the output generation device is in an operational mode. The system includes a programmable logic controller configured to calculate a rate of flow of the output utilizing the first pressure and the second pressure.

Abstract: A method of autonomously sharing a load between at least two output generation devices, the method including: providing at least two output generation devices, wherein the at least two output generation devices operate autonomously with respect to one another and the at least two output generation devices are in fluid communication with output receiving means adapted to receive output generated by the at least two output generation devices; monitoring output generated by the output generation devices; and cycling each of the at least two devices through an activated mode and a standby mode independently of one another in an automated manner to meet an output demand thereby sharing a load demand between the at least two output generation devices.

Abstract: A system and method is presented for reducing a concentration of ambient air used in a feed stream to form an inerting gas in a pressure swing adsorption system. The method includes introducing ambient air into a pressure swing adsorption system to form an inerting gas, introducing the inerting gas to a large volume of atmosphere, thereby inerting at least a portion of the large volume of atmosphere to form an inerted atmosphere, and removing a portion of the inerted atmosphere and introducing the portion of inerted atmosphere to the pressure swing adsorption system to form the inerting gas, thereby reducing an amount of ambient air utilized to form the inerting gas in the pressure swing adsorption system.

Abstract: A gas separation vessel has a vessel shell and a partition therein. A first bed support is mounted between the partition and the shell, and a second bed support is mounted within the partition to define a second bed space. First and second ports on the vessel shell beneath the bed supports permit gas flow between the bed spaces and the exterior of the vessel shell. A separation medium is placed in the bed spaces. A feed gas is introduced into the vessel to flow through the first bed and then through the second bed to separate at least one component of the feed gas from the other intermixed gases. Output gas is then collected from the vessel. The vessel may have a L:D ratio of not more than 4:1.

Abstract: A method for operating a fuel cell power plant to supply power to an internal load and an external load, includes the steps of evaluating power needs of the internal and external loads to determine a fixed IDC value sufficient to supply the needs; providing auxiliary power to the internal load and output power to the external load so as to maintain operation of the fuel cell power plant at the fixed IDC value; and adjusting at least one of the auxiliary power to the internal load and output power to the external load so as to maintain operation of the fuel cell power plant at the fixed IDC value. Operation within a preselected voltage range is also provided.

Abstract: A method for operating a fuel cell power plant to supply power to an internal load and an external load, includes the steps of evaluating power needs of the internal and external loads to determine a fixed IDC value sufficient to supply the needs; providing auxiliary power to the internal load and output power to the external load so as to maintain operation of the fuel cell power plant at the fixed IDC value; and adjusting at least one of the auxiliary power to the internal load and output power to the external load so as to maintain operation of the fuel cell power plant at the fixed IDC value.

Abstract: A member that is driven by a hydraulic actuator tends oscillate when fluid flow to the hydraulic actuator is terminated. A pressure relief device reduces that oscillation by connecting first and second first relief valves to the hydraulic actuator. The first relief valve provides a relatively large first relief passage as long as pressure in the hydraulic actuator remains above a threshold. A second relief valve opens a second relief passage at substantially the same threshold pressure and thereafter remains open as long as the pressure remains above another lower threshold. A timer causes the second relief valve to close a given interval of time, if the pressure does not drop below the other lower threshold.

Abstract: A method for operating a fuel cell power plant to supply power to an internal load and an external load, includes the steps of evaluating power needs of the internal and external loads to determine a fixed IDC value sufficient to supply the needs; providing auxiliary power to the internal load and output power to the external load so as to maintain operation of the fuel cell power plant at the fixed IDC value; and adjusting at least one of the auxiliary power to the internal load and output power to the external load so as to maintain operation of the fuel cell power plant at the fixed IDC value.