Self Healing MV Capacitors Vs. All film Capacitors

This description focuses on single capacitors and reactive power compensation systems in the power range from 50 to approx. 6,000 kvar, because the greatest deficit in risk-awareness is present here. In practice, these PFC systems are often just «parked» somewhere since the dimensions and prices of such equipment are relatively small and they should be close to the load. Protection devices are then often neglected in comparison to larger systems, because the costs appear to be unreasonably high.

It is a fact that the protection systems necessary for the reliable operation of a small reactive power compensation system, e.g. 300 kvar, require the same protection relay and a similarly expensive current transformer as a 10 MVAR system. If the total power is divided into 3 or 6 units, even higher costs are incurred. Disparities of up to 80% for the protection component then occur, compared to 5% for larger systems.

Serious mistakes are often made especially in the reactive power compensation of small installations, which lead to equipment dam­age and environmental incompatibility. This unsatisfactory situation was the starting point for the development of a new concept that offers an acceptable relationship between protection costs and total costs, while reducing the ecological risk.

There is a newer technology of metallised polypropylene film(MKP) for medium voltage which is becoming very popular and is much suited for such application compared to All film technology. Before we discuss the limitations of all film technology a some advantages of the MKP technology just to keep you interested.

Operational stress of Allfilm medium voltage capacitors

Capacitors operate at full power immediately after every switching. No-­load or low-load periods do not exist. The design is made under economical constraints with high electrical field strengths up to 75 kV/mm and a finite service life, which can be dependent on many influencing factors, and is estimated from statistical data. There are many effects that cannot be detected during durability tests.

Summarizing, it can be said that modern power capacitors are very reliable and failure rates greater than 0.2% per year are very rare. However, it must be considered that much higher failure rates occur from early failures, manufacturing faults, dimensioning errors, incorrect appli­cation or overload.

The effects of such failures must be assessed carefully by means of a risk analysis that also includes the ecological risk, due to the high short-circuit power present in medium voltage installations.

Objective of capacitor protection techniques

The reduction of damage to the environment is the most important criterion for capacitors, while preventive protection against permanent damage is the prime concern with motors, transformers, inverters, lines, cables and similar components.

Breakdown Behavior of Allfilm medium voltage capacitors

Allfilm capacitors are constructed with layers of aluminum foil and polypropylene film. These foils are first winded together and then flattened to make packets. These packets are  connected in series and parallel connections inside a steel enclosure to make a capacitor. Finally, this whole assembly is immersed in synthetic mineral oil (e.g. Jarylec) to complete the construction. In some cases each packet has its own fuse which is meant to disconnect the packet in case of failure.

Breakdown of the dielectric is the prime cause of failure. Only this break­down and the resulting consequential effects are considered here.

Every breakdown of a single winding element in a capaci­tor with several internal serial winding circuits leads to a change of the internal voltage distribution, irrespective of whether this winding is fused individually or whether it is a fuseless design. This leads inevitably to higher voltage stress in the remaining winding elements. Accelerated ageing accompanies the increased voltage stress, which results in further winding breakdowns.

Considerable damage to the environment of the capacitor must be expected if the breakdown process is uncontrolled, i.e. if operation is continued until an over-current, earth fault or short-circuit trip responds.

This means that, when the maximum permitted energy input into the capacitor casing is exceeded (violation of the typical cur­rent-time destruction limit), it can, in the worst case, tear open, and the contents of the casing can be ejected. A considerable shock wave, with ignition of the oil spray and the solid flammable content, are conceivable further consequences. 

3-phase medium voltage capacitors

These capacitors are frequently built without internal fuses, due to their – usually - low power and three-phase design. After a winding breakdown, such a capacitor develops a group short-circuit.

Depending on the number n of internal serial circuits, the capacitance and voltage stress in the affected branch increases by the fac­tor n/n-1.

The current increases correspondingly. Thermally, this is barely noticeable due to the low capacitor losses. Further short-circuits can occur, especially if the fault remains unnoticed for a long period. 

When we have a failure situation, the short-circuited capacitor element and all paralleled elements are bridged out of operation. As a result, the effective kvar output of the capacitor increases. 

This is now 181kvar. When an external star circuit is functioning with 3x 150kvar and one of the capacitors suddenly becomes 181kvar, this causes shifting of the star point and stresses in the circuit.

Consider an example with fuse-protected capacitors.

In this case, the effective kvar output comes down, but the voltage stress on the functioning packets, in this case, increases by more than 19%. This increased stress is disastrous for the capacitor.

Internal fuse Protected Capacitor

Internal series connections depend on the voltage on the elements and the capacitors, because a failure of one element causes overvoltage on the other healthy units. The failure of one element may result in voltage rise between 0.5 to 2.5% depending on the internal construction. For smaller voltages this may not be such a problem but for higher voltages eg 7.2kV these fuses are under additional stress and prone to rapid failure. Another problem is to have a fuse with the right breaking capacity at the high voltage and to have sufficient open distance once the fuse has operated.

When the element fails the fuse may result in arcs and formation of Gas in the enclosure which leads to contamination of the oil, however much of the manufacturers may claim. The fusing temperature is often between 700~1000°C, which is well above the flashpoint of the insulating oils (e.g. Jarylec has a flash point of 144°C). The important point here is that there are numerous such fuses inside the capacitor and therefore the chances of catastrophic failures are quite high.

Another important aspect is that a failure of one element may cause a loss of capacitance from 2 to 5% depending on the internal construction in a capacitor. This is one of the biggest advantages with MSD as we will see later in this note. MSD being based on self-healing technology has no loss of capacitance even after a short fault is cleared.

When there is short circuit between the terminals the discharge current of the capacitor is very high. Normally the manufacturers claim 200~300 times the rated current, but in certain case may go up to even 1000 times the rated current. The internal fuses are highly susceptible to failure during these times. When there is an internal fault (element breakdown) , due to the lower circuit impedance inside the capacitor, the discharge current from the elements connected directly in parallel to the damaged element, is even higher than a direct external discharge.

External Fuse Protected Capacitor

Internally protected capacitors can never be protected by an external fuse. Therefore, when one element fails, not only the energy of the parallel elements discharges through the fault but also of the other capacitor units in parallel. If the fuse does not break quickly, usually an explosion or severe mechanical damage will occur.

Because a fault in a group will only marginally increase the unit current, it is not easy to have a rapid operation of the external fuse at power frequency. For example, with one element being faulty may result in the current increase of only 30%. Therefore, some groups may see permanent overvoltage of 30% over some months, and eventually fail. Even during failure their currents are not high enough for a rapid breakdown. At this time there might be arcing in the capacitor and a strong possibility of rupturing or other sever mechanical damage and fire. 

Dielectric structures used in our MSD power capacitors are “self-healing”: In the event of a voltage breakdown the metal layers around the breakdown channel are evaporated by the temperature of the electric arc that forms between the electrodes. They are removed within a few microseconds and pushed apart by the pressure generated in the centre of the breakdown

spot. An insulation area is formed which is reliably resistive and voltage proof for all operating requirements of the capacitor.

 The capacitor remains fully functional during and after the breakdown. In the graphic above the black layers are the metal layers (shown exaggeratedly which is normally in 10s of Angstroms) and the blue is the Polypropylene between 4~8um. In the last sequence, it is shown how at the end of the self-healing process the insulation area is formed. Normally this insulated area is <2mm therefore there is negligible loss of capacitance.

Capacitance remains constant throughout the life of the capacitor.

For voltages within the permitted testing and operating limits the capacitors are overvoltage and short-circuit-proof.

They are also proof against external short circuits as far as the resulting surge discharges do not exceed the specified surge current limits.

Overpressure Protection

Another distinct advantage of self-healing capacitors is the implementation of Over Pressure Protection mechanism. The self-healing process generates gases inside the capacitor. In normal course because of the dry construction these gases stay embedded in the resin. However when the capacitor nears its end of life failure the number of self-healing breakdowns increases which causes the pressure to rise inside the capacitor. MSD capacitors are equipped with an over pressure switch which disrupts the control voltage of the contactor when there is a pressure rise and thereby safely disconnecting the capacitor. It is impossible to have such a safe system in Allfilm capacitors, which are prone to frequent ruptures and explosions.

Below is a comparison of the Electronicon MSD(TM) capacitors versus the ALL film capacitors.

For more information please visit Electronicon website for more information.

Proper Connection in PFC Capacitors

Most of the time the user of PFC capacitors is confused about how to terminate the capacitors. The capacitor manufacturers normally do have a well documented procedure on how to terminate the cables to the capacitors, but unfortunately this information does not reach the end user- when he needs them.

Below is a general procedure that would help users to have a better connection and faultless operation.

1. Ensure Proper Cable Sizes.

As you will see in the table below- the cables sizes are slightly different from those recommended by the Cable manufacturers. The reason is very simple, yet very easy to miss in the designing of the panels. We would like the cables to act like a heat sink and should be able to drive away the heat from the terminals. On the other hand having smaller cross-section would heat up the terminals and will result in heat damaging the sensitive film inside the capacitor. The terminals insulation may also be damaged and may result in short circuits or other failures.

For example for a 25kvar capacitor one should use 16mm2 instead of 10mm2.

2. Select Multi-strand cables. Finer the strands better the connection. Select and use a ferrule of the correct size. Do not use oversized ferrules as they result in poor connection.

3.  Use a proper tool recommended by the Ferrule supplier. Hydro-pneumatic tools are ideally suited for such application.

4. The form of the crimped cables should be rectangular allowing the terminals to get a proper grip on the cable and the cables are held tightly.

 5. Use the specified torque to tighten the screws of the termination. The example table shows the specifications of the Electronicon Power Factor Correction Capacitors.

6. More are more people are moving towards Torx screw for terminations now. The concept of using Torx Screws for capacitors was started by Electronicon Kondensatoren GmbH, Germany.

Advantages of the TORX screw:

• optimum control of torque transmission to the screw
•  no vertical pressure during fixation required; avoids damage to internal wiring of the capacitor
• unique and definite tool required, confusion impossible: enhances safety and transparency of your assembly process

TORX has become one of the world’s leading screw standards, and proper tools are available all over the world.

Base Film Sources - (BOPP- Biaxially Oriented PP)

You cannot get a good omelette with bad eggs, similarly,  it is not possible to get a good capacitor with bad base film ( BOPP). There has been a spurt of base film manufacturers across the globe. Many of them having modified the packaging grade machines for capacitor grade films. This is dangerous not only for the manufacturer but also for the end user. The manufacturer may want to reduce the cost and win a tender, but the majority of the difficulties would be face by the end user. The capacitor is expected to have a life of 8 to 10 years, however with such films it barely survives the warranty periods.

A few of the better known sources of capacitors grade film are given below-

• Treofan
• Bollore
• Kopa Films
• Tervakoski
• SYC

It would be worthwhile, and in his own interest, for the end user to make an agreement with the capacitor manufacturer to use any one of these above mentioned BOPP sources.

For more information on the process and the resin used for capacitor grade films, please check the link below.

Process-

http://ecadigitallibrary.com/pdf/CARTSEUROPE06/1_4%20Jacobs-Borealis_a.pdf

Datasheet-

http://www.borealisgroup.com/pdf/literature/borealis-borouge/sds/IN0002_GB_FF_2009_04_BB.pdf

10 Steps for Selecting The Right Film DC Link Capacitor

Ten Steps To Your Film DC Link Capacitor.

Step 1.  Specify your DC bus voltage

Step. 2 Determine the acceptable voltage ripple limit.

Normally the limits vary from 5-10%, however in some rectifier applications they could also be lower than 1% of the DC bus voltage. 

Step 3. Calculate the capacitance required to reach the Uripple level.

Step 4.Calculate the capacitance current

Step 5. Verifying Design Limits

Once the capacitor capacitance and capacitance currents have been identified, it is important to verify that the calculated capacitance is able to handle the calculated current. If not then increase the capacitance to match the current.

Step 6. Select the parts from the Databook.

Step 7. Thermal calculations

The thermal calculations and it's implication can be found in the PEC Application Notes and

Semikube Selection Guide from Semikron GmbH.

Step 8 Lifetime

The lifetime calculations and FIT rates would appear in later blogs however, the above mentioned links have sufficient information on this topic.

Step 9. Capacitance Characteristics

Do not forget to check the performance of the selected capacitor for your operating frequency.

Step 10.Mounting

This is the final but one of the most important steps in the selection process. Do it carefully.

Advantage of Film DC Link over Electrolytic DC Links

Traditionally Electrolytic capacitors have been used most of the DC Link applications. The main reason has been the low cost per capacitance for these capacitors. However, they have a limitation on the maximum voltage applied (600Vdc) which necessitates series and parallel combination, high ESR and low life expectancy. Further, they are one of the components most prone to failure. The main failure mechanisms include the loss of electrolyte through out-gassing and chemical changes to the oxide layer. All the degradation mechanisms are aggravated by ripple current heating.

Over the years Electronicon Kondesatoren GmbH, has developed and proven Film Capacitors as a an alternative of choice for DC- Link applications. Electronicon capacitors with film metallisation as core capability and the use of Secumet^TM metallisation technology leaves the conventional metallisation and segmented film solutions far behind.

The film DC links are now available also for smaller systems of less than 5kw, in PCB mounted construction.

Following are the advantages as a designer that you get while moving from Electrolytic to Film DC links, besides the cost advantage.

What is in it for You?
1.     Extremely long life greater than 150000hrs - High reliability of your equipment
 
2.     Extremely low losses compared to electrolytic caps.- Lower running costs, savings for the end user
 
3.     Extremely low self inductance-  lower parasitic
 
4.     Accurate capacitance values- eliminating the need for sharing resistors- Savings due removal of additional item and operations
 
5.     No losses due to sharing resistors- lower cooling costs Lower Running costs
 
6.     Reduced capacitance need- due to 5 times more current handling than electrolytic capacitors.- reduced risk by lowered  energy density inside the equipment-
 
7.     Voltage rating upto 5000Vdc available in single container.- no more headaches of series and parallel connections
 
8.     No forming ( pre- loading) of capacitors required- as needed for electrolytic capacitors.- reduced risk of failure due to negligence at final customer, increases robustness of your product
 
9.     Unlimited shelf life- no risk of scrapping
 
10.  PCB mounted, Bolt fixing or Clamp fixing both are possible.- covers all your needs and applications
 
11.  Strong Connections for direct mounting on the busbars-  ease of use and longevity of connections
 
12.  Dry construction- No risk of spillage, no aggressive electrolytes, helps you comply with stringent environmental regulations
 
13.   UL Approved capacitors –safety guaranteed

Over pressure disconnection or Break Action Mechanism

Protection against Overload and Failure at the end of Service Life:

In the event of over-voltage or thermal overload or ageing at the end of the capacitor‘s useful service life, an increasing number of self-healing breakdowns may cause a rising pressure inside the capacitor, due to the gases released from the self-healings. To prevent it from bursting, the capacitor is fitted with an obligatory «break action mechanism» (BAM), also known as over-pressure disconnector. This safety mechanism is based on a weakened spot in one, two, or all of the connecting wires inside the capacitor. With rising pressure the case begins to expand, mainly by opening the folded crimp and pushing the lid upwards. As a result, the prepared connecting wires are separated at the weakened spot (at a predefined force), and the current path is interrupted irreversibly. It has to be noted that this safety system can act properly only within the permitted limits of loads and overloads. Also note that sufficient clearance must be kept above the capacitor to allow the capacitor to expand. The video below shows the operation of the Electronicon power factor correction capacitor. For more information visit Electronicon(India) web page.

BAM video Electronicon

Self Healing Technology

Self-Healing MKP capacitors:

All dielectric structures used in Metallised Polypropylene  power capacitors are “self-healing”: In the event of a voltage breakdown the metal layers around the breakdown channel are evaporated by the temperature of the electric arc that forms between the electrodes. They are removed within a few microseconds and pushed apart by the pressure generated in the centre of the breakdown spot. An insulation area is formed which is reliably resistive and voltage proof for all operating requirements of the capacitor. The capacitor remains fully functional during and after the breakdown. For voltages within the permitted testing and operating limits the capacitors are short-circuit- and overvoltage-proof. They are also proof against external short circuits as far as the resulting surge discharges do not exceed the specified surge current limits.

For more information please log on to www.electronicon-se.com or www.electronicon.com