At the SPS fair in Nürnberg 2019, Danfoss gave a sneak peek its new active harmonic filter for high power quality applications. Sources say it is due to be launched in q1 of 2020. We look forward to check out its specifications. Danfoss was the first drives manufacturer to use active harmonic filters as a solution for their low harmonic drives, often applied when complying with for instance IEEE519. Last year Schneider followed up showing its Active Harmonic Filter in combination with multiple drives at SPS, see Active Harmonic Filters & Drives. The Danfoss filter AAF007 seems to be modular based on the picture presented.
Schneider dedicated 3 meters of exhibition space to its active harmonic filters at the SPS fair in Nuernberg this year. Great to see that the big boys are catching on. Schneider is no newcomer to the field though, rather one of the biggest suppliers of active filters world wide. This is the first year they show these products at the SPS. This year small filters down to 20 A is a new offering from Schneider in the PCSn series. We assume this will broaden the application scope significantly.
For more info check out the PCSn flyer Schneider_PCSn_998-20306747_GMA
Comsys has released a application note explaining the detailed advantages of using central filtering of many drives rather than installing separate low harmonic drives. A central active harmonic filter is often the cheapest and most efficient answer to maintain code compliance.
Read the report here: Global-vs-Local-Compensation_Application_Note
Active Harmonic Filters are becoming cheaper and very competitive compared to other active mitigation solutions such as Active Front End, which we explained here. In some applications that are not too dynamic, a passive harmonic filter makes perfect sense to reduce the investment. A combination of active and passive filters can be the best solution to reduce the investment cost while still being able to cope with dynamic loads. In such an application the passive harmonic filter focuses on the dominant harmonic component. This solution is currently used by for example the German auto industry in their production lines.
PQ Nosswitz, a German power quality solutions firm, devised a system to allow a flexible combination of active harmonic filters and passive harmonic filters to enable the most flexible and cost efficient solution for every project.
Power quality mitigation products are not only used to fulfil regulations such as IEEE-519 and G5/4. They have actual effects saving both power and increasing productivity. This presentation by ABB exemplifies some of their early case studies indicating savings of up to 10%. Note that these savings compare to having no harmonic mitigation.
The cases below clearly show the great business value of implementing a high power quality standard within your facility. The secondary effects of complying with IEEE 519 or similar standards enables the local grid to be dimensioned for less reactive power and harmonic current thus saving money through thinner cabling, smaller transformers etc. Power quality mitigation is not only a cost in the general investment calculation but a tool to save money.
Active Harmonic Filters are growing in popularity as a method to mitigate power quality issues. There are several factors to consider when specifying an active harmonic filter. Typical applications for active filters are compensation of variable frequency drives and data-centers to reduce the load on UPS systems or compensating the effects of renewable energy sources on the grid.
What is an Active Harmonic Filter and what is its Application.
The general definition to describe this application is an analog or digital device that measures the power quality on the grid side. It then injects current to compensate any unwanted deviations from the standard 50 or 60 Hz supply. Deviations can be mitigated in full or partially.
What Factors to Consider when Specifying an Active Harmonic Filter
Sensor or sensorless control
There are suppliers that provide sensorless control eliminating the need for current transformers. This solution reduce the installation cost. Sensorless is not used in all applications so make sure to check the application with the supplier. Sensorless control or voltage control as it is sometimes defined compensates the total THD. It is not possible to select a single source such as a single VFD. On the plus-side it is possible to protect a sensitive subgrid from a noisy primary grid.
Depending on design, the filter has higher or lower losses. Check the losses as this will reduce the Life Cycle Cost on your investment. Some active filters have up to 1%-point lower losses, which depending on your user profile, means a potential for considerable financial savings if calculated LCC over 5 years.
Harmonic Compensation Capacity
Harmonics are normally seen in the odd. Common capacity for active filters is 25th or 50th harmonic. Sometimes there is a claim of being able to mitigate the 51st harmonic, which has little value as harmonic order of 51 and above are normally not important.
Harmonics above the 50th are more difficult to measure as there are few PQ-meters that can handle such orders. There are however quite common sources such as Active Front End Drives that cause switching ripple above 3kHz, above the 60th harmonic (or above the 50th in 60 Hz systems).
There are a few Active Harmonic Filters capable of compensating such frequencies. Choose a filter according to the needs specified by your measurements.
A filter’s capacity to compensate a certain harmonic order is only part of the story. Another important factor is de-rating, discussed below.
Some power quality phenomena occur extremely fast requiring the mitigation to be even faster. If your process is affected by fast flicker or transients, take special care to evaluate the response capacity of the filter. Flicker is a specific phenomena that normally requires special software to compensate flicker in a controlled environment.
Interharmonics is commonly caused by syncronisation issues. If your installation includes such interharmonic sources, the type of active filter changes and the vendor has to be consulted. This is a common issue on some types of older wind turbines.
In Europe there are strict guidelines regarding EMC. If you want to be sure that the active filter does not interfere, the filter must be fitted with a properly tuned EMC-filter.
An Active Harmonic Filter’s rating is normally defined at nominal load, meaning at 50/60Hz. As the filter works further up the harmonics its capacity compared to nominal starts to de-rate. The de-rating curve is documented by all serious suppliers and should be available if you ask them.
A de-rating of 50%, at say the 13th harmonic, means that a 100A filter only has the capacity to compensate 50A at the 13th. Naturally if you have harmonics of higher order it becomes more important to check the de-rating.
De-rating is a matter of how robustly the filter is designed. Some suppliers offer zero de-rating up to the 7th before capacity starts to fall.
Physical Footprint – How Much Cabinet Space is Required?
Most active filter suppliers offer several alternatives regarding installation. Wall mount, Cabinet and IP00 modules to install in cabinets. Efficient use of cabinet space translates to lower system cost. Some filters have a modular design and can be enhanced with further capacity without adding to the footprint.
As mentioned, a modular design of your Active Harmonic Filter enables you to adapt the filter to potential changes in your future power compensation needs. The modular design means that you can easily add to the filter’s capacity within the existing cabinet, saving both cost and space.
Does the filter have built in commissioning software? Commissioning and service of Active Filters can be quite time consuming. Ask for a review of the support software included in the machine. Some suppliers have an extra charge for the necessary software. Minimum required functionality should be that the system performs a self-check of Voltage and CT phase order, CT polarity check, self-diagnosis, and self-calibration. Such features will quickly find installation errors before they can cause problems and will also shorten the needed commissioning time.
If the filter does not have this type of support software the commissioning becomes much more complex and might even require external support adding to the system cost.
There are different HMI setups. Some have a very simple front HMI while others include graphs showing the current and voltage waveforms and many further functions. A great added value is to have at least a web-based interface allowing in-depth monitoring and control functionality. Then no extra PQ-meter is necessary.
Smart Grid Functionality
Active filters have a built in rudimentary power and power quality meter to calculate the required compensation. Some filter manufacturers make use of this fact and enable the user to connect all filters on site and company wide through a web based architecture. An operator can then have an overview of the status of all connected cabinets and log them. This enables the possibility to log events that could or should have caused production disturbances, status monitoring of individual filters as well as remote control capability. Email and text alerts to dedicated service personnel from the filter reduce response time dramatically.
IP/NEMA Class and Water Cooling
Water-cooled Active Filters enable very good cooling of the IGBTs, the most critical component in the Active Filter. Water-cooling reduces overheating immensely, which increases availability in the same way as for Variable Frequency Drives. The power density of the installation is also improved.
Active Harmonic Filters are offered in a range of voltages. Most common ranges are 380–415V, up to 480 V. Higher voltages up to 600 and 690V are also available without step-up transformer, reducing foot print. Some suppliers have the capacity to supply MV ratings as well, normally using a step-up transformer. The active filter can then act as STATCOM.
In recent years several suppliers are offering battery connectivity to create a battery energy storage system for FCR and peak shaving. The active filters on-load capabilities are perfect for grid connectivity applications.
Sensorless Voltage Control
Recently a new type of sensorless solution make it much easier to install as no CTs are required which is standard for active harmonic filters. This method can not control specific frequencies but can be used to even mitigate noise from the grid.
Some filters offer resonance damping making them ideal in highly complex situations.
Using the active filter in shunt applications has a lot of energy saving potential compared to using serial filters – either passive or active front end.
Here are some examples and what they mean to you as user. When seen as a system, the active filter in shunt mode offers a total system loss that is lower than that of the passive filter.
Passive Harmonic Filters
A passive filter has between 0.6-1.5% losses
Assuming a 6-pulse drive has 2% losses, the total system loss is the sum of the losses
Pdrive*PFilter = 2% + (1.5 <-> 0.6)% => 3.5% to 2.6% total system loss.
NOTE! This does not include an eventual voltage drop through the passive filter and its effect on the motor’s losses.
Serial Active Filter – Front End
An active front end drive essentially has twice the loss of a standard drive as the power has to pass through two IGBTs.
Pafe = 2% + 2% + 1% for the LCL-filter = 5% losses. Total system losses observed in documentation are 4.7-5%.
Shunt Active Filter
Unlike the serial solutions the shunt active filter only has to be sized according to the harmonic currents to be filtered out. Under normal conditions this means that in a IEEE-519 or G5/4 application the filter has to be sized 15-30% of the 6-pulse load. This means the total system loss is also much lower even though the efficiency of the Active Filter is:
Pdrive + Padf = 0.02 + 0.02* (0,15 – 0,3) = 2.3 – 2.6 % in total system losses.
Summary from a System Owner’s View
Shunt Active Harmonic filters offer between 0 and 1.17% points lower power consumption compared to Passive Harmonic Filters. This does not include any effect from voltage drop through the serial passive filter.
Shunt Active Harmonic Filters offer between 2.7 – 2.4 % lower power consumption compared to Active Front End drives.
Power Losses are a Significant Part of Your Life Cycle Cost Calculation
Minimising losses over time, especially in industrial process loads with more than 8000 hours of yearly operation, 1%-point saving in power consumption translates into significant value.
(Pdrive + Pcooling) (kW)* Yearly operation hours(h)*Net Losses(%) = Total cost saving potential
Energy Cost Estimate
Electrical power prices differ but the relation between cooling and electricity is roughly equivalent to
Pcooling = 0.3 * Pdrive
In the case of the AFE there are cases where the entire harmonic mitigation solution has been paid off in 2.5 years simply by choosing shunt Active Harmonic Filters instead of Active Front End thanks to lower power losses.
The Active Harmonic Filter is very competitive compared to both Passive filters and Active Front End. As the capital expenditure is very similar, a lower power consumption make the AHF a very good overall choice.
Furthermore the availability offered by a shunt installation where the drive can continue to operate even though the mitigation has failed offer a great upside through higher availability of the process.