Siemens SIMATIC PCS 7 Increase in productivity through intelligent maintenance, Introduction

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© Siemens AG 2011

Introduction

Increase in productivity through intelligent maintenance

How can the productivity of a plant with a high level of au- tomation be increased even further?

Plant operators in all sectors consider increased availabili- ty and shorter downtimes to be the most effective lever to- ward increasing productivity. Investigations have shown that downtimes are frequently the result of insufficient maintenance – despite the fact that maintenance is alrea- dy a significant portion of the lifecycle costs.

Intelligent maintenance strategies can make a significant con- tribution toward increasing productivity:

Failures can be prevented by monitoring the current plant condition.

Maintenance can then be planned. It does not wait until a fault has occurred, but implements appropriate measures in advance for avoiding faults. The timing of maintenance can be planned such that the existing resources can be used optimally.

Innovative maintenance strategies pay for themselves twice: planning security and the specific application of me- thods reduces the direct maintenance costs.

Plant availability is increased at the same time. This means that consequential costs resulting from failures, such as quality deficiencies or loss of image, are reduced.

Totally Integrated Automation supports intelligent mainte- nance strategies. The SIMATIC Maintenance Station is of signi- ficant importance, and presents the information relevant to maintenance from all automation components in a uniform and clear manner, thus providing the maintenance engineer with valuable support for making decisions.

Maintenance strategies

There are two maintenance strategies: response to failures or taking preventive measures. In the case of failure-oriented corrective maintenance, measures are only initiated when a fault has occurred, i.e. failures are acceptable in this case and may be minimized by a redundant plant design.

The objective of preventive strategies is to carry out mainte- nance measures before faults even occur, in order to avoid possible downtimes. This strategy can be satisfied using time-dependent and load-dependent measures. Regular maintenance work is an example of time-dependent measu- res. The load state is determined from the number of swit- ching operations, operating hours or load peaks.

Benefits of intelligent maintenance

Continuous plant monitoring

Reduces the risk of failures, and increases the availability

Enables maintenance to be planned

Optimized use of maintenance resources

Increases maintenance quality

Achieves cost savings

The potential for savings arises

During maintenance itself and

by avoiding consequential costs

Condition Monitoring, that is to say status monitoring, aims to detect imminent faults at an early stage. It provides infor- mation on the remaining duration of use. In the case of con- dition-based maintenance, the maintenance measures are only initiated when the period of use has expired.

It has been shown in practice that optimum results can be achieved through intelligent combination of the different stra- tegies.

Maintenance

Corrective

Preventive

Time-dependent

Condition-based

XXST8000410

Load-dependent

 

 

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Maintenance strategies

2Introduction

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Contents Maintenance System Benefits of intelligent maintenance Increase in productivity through intelligent maintenanceMaintenance strategies IntroductionContents General information Plant Asset Management as a maintenance taskMaintenance personnel Different demand for information at the plantAsset management in production Benefits of Plant Asset ManagementIntelligent maintenance in process engineering Plant Asset Management with Simatic PCSSimatic PCS 7 Maintenance Station Integrated plant and cross-system maintenanceOptimizing instead of repairing More productivity with Totally Integrated AutomationVisualization of information for maintenance Pump monitoring with the block PumpMon Maintenance Station User interface for maintenanceMonitoring and diagnostics of mechanical components Valve monitoring with the block ValveMonConfiguring a Maintenance Station Standard diagnostics functionsDesign of a Maintenance Station Visualization in the Maintenance StationIdentification Symbol displays and component faceplatesMaintenance MessagesMaintenance planning Alarm Control Center alarm management systemPM-MAINT intelligent maintenance management Archiving of maintenance dataFor industrial PCs Monitoring Signaling Alerting Visaulization OperatingMonitoring and diagnostics Prevention of potential failuresNetwork components Monitoring and diagnostics of networksMonitoring of PROFINET/Industrial Ethernet Network managementDiagnosis of optical Profibus links with OLM Benefits of network monitoring and diagnosticsMonitoring of Profibus Sitrans TH400 for Profibus PA Temperature measurementSitrans TH300 the Hart device Sitrans TW for rail mountingΜS/cm guaranteed Flow measurementLevel measurement Sitrans Probe LR, pulse radarGas analyzers Calomat 6/62Maxum edition Remote serviceProcess gas chromatography MicroSAMMonitoring and diagnostics for positioners and valves Sitrans VP300Monitoring and diagnostics of 24 V load feeders Contact erosion TemperatureGround fault or insulation detection Number of starts, breaking currentMonitoring and diagnostics Status assessment of high-voltage machines Monitoring and diagnostics of drive componentsDiagnostics of drives Schematic flow of information using example of a mixer drive Benefits Get more information
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