Within the type test, pressure sensors are qualified on an impulse pressure hydraulic test bench by means of an "accelerated life" test.
The high-pressure filter of the impulse pressure test system is an essential component for fault-free operation. If there is increased abrasion due to damage to individual components within the hydraulic system, the filter will be clogged before the planned maintenance work to replace the filter occurs.
Real-time process monitoring of hydraulic high-pressure filters above 400 bar is not the norm. The pressure filter change was carried out at a set interval. In this case, a premature failure of a hydraulic piston pump allowed chips to enter the hydraulic system. These settled in the pressure filter but subsequently led to cracks in the filter element.
By means of the cyclic filter monitoring, this unforeseen event could not be noticed in time, which resulted in the complete failure of the impulse pressure test bench and high repair costs.
Condition monitoring of the high-pressure filter or the filter element. This is an essential factor for the service life, runtime and safety of the system.
The aim is to change the maintenance strategy from cyclical replacement to condition-based replacement of the pressure filter element.
Monitoring and visualisation incl. threshold monitoring of the pressure difference in front of and behind the oil filter provides early information on necessary filter changes.
Two high pressure sensors, which were not in use until the project was carried out, are installed in front of and behind the pressure filter. The analogue signals of these two sensors are converted with the help of an IO-Link converter (DP1222) and passed on to an IO-Link master which passes the sensor values on to moneo.
Threshold management and data monitoring is carried out with moneo RTM.
During set-up of the use case, a technical fault was discovered in the system due to an initially much too high differential pressure. This was subsequently rectified by the manufacturer.
Without the connection to moneo, this problem would probably not have been detected and would have led to a reduced service life of the high-pressure piston pump in the future.
Condition monitoring with moneo RTM ensures the process capability of the high-pressure filter system and thus the production process. Additional costs due to undetected damage are avoided.
The data acquisition on the oil filter (in front of and behind the filter), its visualisation and threshold monitoring enable condition-based maintenance of the oil filter. Soiling is detected promptly and thus expensive consequential costs for process and machine are prevented.
Get the big picture on the moneo dashboard.
In the dashboard, the user gets an overview of the pressure in front of the filter, behind the filter and the resulting differential pressure. In order to quickly identify the condition of the filter, it can be visualised via the traffic light indicator. The pre-set thresholds for the differential pressure are thus indicated in the colours red, yellow and green.
The analysis can be used to view further details. The screenshot shows the pressure and voltage values collected during 3 months. As we can see, the pressure difference increases over time. Since the filter clogs up over time, this is to be expected.
This function in moneo RTM allows users to define an individual threshold for each process value. In this application, thresholds are set such that maintenance personnel will be notified in good time when a filter change is necessary.
Especially during machine start-up, higher pressure fluctuations can briefly occur; these can simply be blanked out via delay times. This means that thresholds which are briefly exceeded will be suppressed and the system will only react if the pressure difference is exceeded for a time X.
The ticket processing rules wizard makes it easy to define actions to be executed when warnings and alarms occur.
In the following case, the ticket is processed via the SFI interface to SAP (PM system).
In the event of a threshold violation of the differential pressure, a maintenance order is generated in the SAP system via the SFI interface in parallel to the message in moneo. The person responsible for the system can change the corresponding filter and then report the filter change in the SAP system. This also automatically closes the threshold violation message in moneo.
Pressure in front of the filter in bar = analogue voltage signal * 100
Pressure behind the filter in bar = analogue voltage signal * 100
Pressure difference [∆P] = pressure in front of the filter - pressure behind the filter
In addition to the process values of the sensors, moneo also detects the operating hours of the high-pressure filter. This function can be implemented quickly and easily using the “Operating hours counter” template.
For this, the data source ② describing the operating status is required. In the following example, the output voltage of the pressure sensor in front of the filter and the following threshold ③ is used: