![]() ![]() ![]() Write-host "Runbook Instance URI " $RunbookInstanceURL #The Instance can be used to retrieve the Parameters for the particular job $ResponseObject = invoke -webrequest -Uri "$($RunbookInstanceURL)/Parameters" -method Get -Credential $mycreds $xml = $ResponseObject. While ( $DoExit -ne "Yes" ) # As the runbook is no longer active, query the Instance of the submitted job $ResponseObject = invoke -webrequest -Uri "$($RunbookJobURL)/Instances" -method Get -Credential $mycreds #Retrieve the Instance ID $XML = $ResponseObject $RunbookInstanceURL = $ The request is made as part of a standard XML template that includes the runbook GUID and GUIDs for any additional input parameters that the runbook requires. The body of the request being posted to the Orchestrator server. The PowerShell script will need to retrieve these identifiers to be able to submit a request to the Orchestrator Service Before filter placement, a radiograph of the IVC was obtained that showed a. ![]() The XML returned will contain the GUIDs (Id’s) used by Orchestrator for assigning data to input parameters of the runbook being called. Only filters with an unprotected primary strut design have been associated. iFilters intuitive user interface will quickly have you designing filters, connecting them. After retrieving the Runbook GUID, a query can then be made on the parameters of that runbook. Within the feed is the GUID assigned to the particular runbook. To initiate the runbook and then retrieve the output, a series of calls need to be made to the web service to identify the GUIDs.Įxecuting a runbook and retrieving the results can be thought of as 5 separate exchanges.Ī simple web request with filter for the name of a runbook returns an XML feed. This is primarily because all items in a runbook are objects that are called by object GUIDs, not friendly names. To action a runbook with PowerShell a series of exchanges need to occur between the script and Orchestrator Web Service. That variable will be then returned by a completed runbook. The workflow will take the input variable… add some text to it… and store it as a variable. To demonstrate the scripting, I have created a simple runbook that will accept a string input. With this simulation software, Röchling supports designers in the development of filter elements for use all over the globe.This example uses PowerShell to call an Orchestrator runbook and display the results. The high congruence between the results calculated virtually and the real-life testing methods confirms the precision of the program. In addition, the software user can define the principal field of application of the filter, which also affects the characteristics of the filter as a result of differing application conditions. To achieve precise results with regard to the potential mileage and service life of the filter element, the software takes parameters such as filter medium and geometry, dust class and quantity, density, nominal air flow and environmental influences into account. The program realizes the required filter characteristics reliably by accessing manufacturer information such as vehicle data, targets with regard to service life or dust capacity of the filter, information on the medium and specific packaging data such as pleat height and distance between pleats. Röchling’s simulation software takes these factors into account, thus allowing cross-market product development. Also, these tests do not reflect everyday conditions or regional differences such as local dust levels. In contrast to the usual tests performed according to ISO standard 5011 up to now, the application makes complicated test setups unnecessary. ![]() The program simplifies the complex and time-consuming predevelopment process. Available at no cost, the FilterLab active filter software design tool provides. Röchling Automotive has developed a software allowing the optimum filter design, service life and performance to be determined. FilterLab is an innovative software tool that simplifies active filter design. The performance of the filter is the result of a trade-off between pressure loss, dust capacity and efficiency. Aspects such as emissions directives and application-specific requirements play a crucial role in the complex process. When the filter is placed in your IVC, the blood flows past the. The heart then pumps the blood to the lungs to pick up oxygen. Your inferior vena cava (IVC) is the major vein that brings oxygen-poor blood from the lower body back to the heart. Round, angular, flat or high: there are lots of variables in filter design. An IVC filter is one method to help prevent pulmonary embolism. ![]()
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