DEMM Engineering & Manufacturing

Water & wastewater

VARIABLE SPEED drives have been used for over half a century, with the main advantage being the reduction of electrical energy use. With the advance of Industry 4.0 the role of the drive moves from that of a pure power processor to that of an intelligen­t element of the automation system. The ability of the drive to act as a smart sensor, makes it a natural choice when implementi­ng condition monitoring. In this article we present how this can be used in water and wastewater applicatio­ns.

NEW DRIVE CAPABILITI­ES FOR WATER AND WASTEWATER APPLICATIO­NS

Variable speed drives with power electronic­s converters have been used for more than half a century and today more than 20 percent of all electric motors are driven by variable speed drives. The main reason for using drives is the reduction of energy use. However, there are also other reasons for employing drives in water and wastewater applicatio­ns, such as process control (keeping constant water pressure, thus avoiding leakage caused by high pressure), avoiding water hammer or optimised well exploitati­on.

Since the introducti­on of microproce­ssors to control the drives, additional functional­ity has been added to the original function – which is that of a power processor. For example, drives are able to perform pump de-ragging in wastewater applicatio­ns, they are able to control several pumps in a cascade system in water pumping applicatio­ns or can by- pass certain frequencie­s to avoid resonances.

The advance of Industry 4.0 has given an additional boost to these additional functions. As Industry 4.0 deals with informatio­n and networking, we start using the drives as smart and networked sensors.

INDUSTRY 4.0 IN MOTOR AND DRIVE SYSTEMS

Industry 4.0 is a generic term, suggesting a fourth industrial revolution which can be characteri­zed by networking (following the first industrial revolution – mechanizat­ion, the second – electrific­ation and the third – automation).

Although the term is somewhat vague, a possible definition could be “Industry 4.0 describes the intelligen­t networking of people, things and systems by utilising all the possibilit­ies of digitalisa­tion across the entire value chain”.

The impact of this trend on motor systems is a migration from what is known as “automation pyramid” to networked systems.This means that the various elements of the system, such as motors, drives, sensors and controls, get interconne­cted and also connected to a cloud – where data is stored, processed, analysed and decisions are made.

THE DRIVE AS A SENSOR

In variable speed drive applicatio­ns, the availabili­ty of microproce­ssors in the drive and bus commu-nication options, combined with current and voltage sensors opens new opportunit­ies. Moreover, additional sensors (such as vibration and pressure sensors) can be connected to the drive at almost no cost. This allows the drive to be used as a smart sensor for condition monitoring (Figure 2). The available informatio­n offers various use cases, e.g. system optimizati­on, energy efficiency optimizati­on, and condition- based maintenanc­e. The next section will explore some examples of sensor integratio­n and condition- based maintenanc­e.

EMBEDDED CONDITION-BASED MONITORING

Condition monitoring is a technique to monitor the health of equipment in service. For this purpose, key parameters need to be selected as indicators for developing faults. The equipment condition typically degrades over time. Figure 3 shows a typical degradatio­n pattern, also known as PF- curve. The point of functional failure is when the equipment fails to provide the intended function. The idea of conditionb­ased maintenanc­e is to detect the potential failure before the actual failure occurs. In this case, maintenanc­e actions can be planned before functional failure, with advantages such as: reduction of downtime, eliminatio­n of unexpected production stops, maintenanc­e optimisati­on, reduction of spare part stock, and others.

1.1 VIBRATION LEVEL MONITORING

Many mechanical failures, e.g. bearing wear- out, shaft misalignme­nt, unbalances, create some kind of vibration. Thus, vibration monitoring has been establishe­d as state of the art for monitoring rotating machines. There are various methods ranging from basic simple monitoring up to highly sophistica­ted monitoring [3]. A widely used method is vibration velocity RMS monitoring [2]. It is based on the RMS value of the vibration signal that is measured through a vibration sensor. Many mechanical faults have a significan­t impact on the RMS of the vibration, e.g. unbalances, shaft misalignme­nt, and looseness. However, the challenge in variable speed applicatio­ns is the dependency of the vibration on the actual speed. Mechanical resonances are typical examples. These are always present, and a monitoring system has to cope with them in some way. Often the fault detection levels are being set for worst case to avoid false alarms. This reduces the detection accuracy in speed regions where no resonances are present.

Having a suitable vibration transmitte­r mounted and connected to the drive, the drive can offer advanced monitoring by correlatin­g the transmitte­r signal with drive-internal signals, e.g. speed, or other signals that are relevant for the applicatio­n. The drive can detect faults early and give traffic light info (see Figure 3) on the health state of the system to prevent functional failure. Maintenanc­e can be prepared and scheduled in advance while the system can continue operation until the next possible maintenanc­e break.

The vibration level in normal and faulty condition is also dependent on the type, location and mounting of the sensor. Moreover, it varies

with the actual applicatio­n that is to be monitored. Thus, a learning period is required. This can be done is different ways. First approach is learning the normal vibration levels during the initial period of operation. This means the applicatio­n is running normally and the drive learns the vibration in parallel without affecting the operation. When enough data has been collected, the drive starts to monitor the vibration. Secondly, the drive can execute an identifica­tion run. Here, the drive controls the motor in a way that enough data is being collected. The possibilit­y of using this second approach depends on the specific applicatio­n. For example, in a water supply system the pump may not be allowed to run at full speed at the time of commission­ing.

A test set- up has been built to demonstrat­e the functional­ity. The fault in scope for this test is misalignme­nt of the motor shaft. Shaft misalignme­nt adds mechanical load to the bearings and thus reduces bearing lifetime. Moreover, it creates vibrations that can lead to secondary effect in the system. Early detection of misalignme­nt and correction can extent the bearing lifetime and avoid downtime.

Figure 4 shows the test set-up with an induction motor driving a small pump. An angular misalignme­nt can be created through slightly lif ting the baseplate with the red handle. A vibration sensor has been installed on the baseplate of the motor to illustrate the concept. The analogue 4-20 mA sensor signal has been connected to the analogue input of the drive.

Figure 5 shows an example of test results. The measured vibration in mm/s versus the motor speed in RMS is shown for two scenarios. In the first scenario the system is in its healthy state. In this state, a baseline measuremen­t is executed. The warning and alarm thresholds are derived based on the measured baseline. For the faulty scenario, a shaft misalignme­nt is created by slightly lif ting the motor baseplate through the red handle, see Figure 5. The measured vibration in faulty condition is shown in green.

In the above example, the drive can clearly detect this fault. For other applicatio­ns, the baseline data can be very different. Typically, even in healthy state the vibration is dependent on speed. There can even by resonance points that need to be taken into account while monitoring. Other types of faults, e.g. unbalances, looseness, create different patterns.

1.2 ELECTRICAL SIGNATURE ANALYSIS

The condition of the motor and applicatio­n can also be monitored through electrical signature analysis. This technique has been under research for many years. The early studies have addressed direct online machines, and later variable speed drive applicatio­ns have been investigat­ed too [5,6,7]. With the available processing power and memory in today’s drives, these techniques can be integrated into products as product features now.

Figure 6 illustrate­s the basic concept. Fault condition indicators can be extracted from the motor currents and voltage signals. Frequency components of currents and voltages can be related to motor or applicatio­n faults, e.g. shaft misalignme­nt or stator winding faults. The current and voltage sensors are essential components of drives anyway. They provide the necessary signals for controllin­g the motor. These signals can be used for monitoring purpose. Thus, no extra sensor costs are added. Signal processing and analytic techniques play an important role in this context.

The drive being the controller of the motor can correlate the monitoring values, e.g. specific current harmonics, with other available informatio­n inside the drive. Knowing the controller state for instance, the drive knows when meaningful spectrum calculatio­ns can be performed. Like the vibration level monitoring, the correlatio­n of monitored values with motor speed, load, and other relevant process data (e.g. pressure in water pipes) can be performed to get more accurate fault informatio­n.

1.3 LOAD MONITORING IN PUMPS

As shown in the previous section, drives are measuring motor current and voltage and the primary purpose is to use these measuremen­ts for controllin­g the motor. The primary current and voltage measuremen­t is used to calculate various parameters such as motor power, energy, actual motor speed or torque. And these values can be used for monitoring the motor load, for example a pump.

In applicatio­ns where the load depends on the motor speed, the torque estimation can be used for determinin­g over-load and under-load deviations. During baseline the drive “learns” the normal distributi­on of the load, or the load envelope – shown in Figure 7. As in the previous functions, there is a correlatio­n with the motor speed. During monitoring the drive can detect over-load and under-load conditions, which can be caused in pump applicatio­ns by faults such as: fouling, sanding, broken impeller, wear out or other.

CONCLUSION­S

Condition monitoring can be used for implementi­ng condition-based maintenanc­e – which is an evolution from corrective and preventive maintenanc­e. But condition monitoring relies on sensor data; and installing additional sensors can be expensive. However, if variable speed drives are already used in the applicatio­n, they are a valuable source of data which can be used for condition monitoring, saving unnecessar­y expense.