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Presented at 2014 Russia Power, Moscow Choosing the Right Stator Bar for Your Next Rewind By Bill Moore, P.E., Dr. Viatcheslav Dombrovski, Dr. Aleksandr Khazanov National Electric Coil Abstract This paper will discuss key factors the generator owner should consider when planning their next generator stator rewind. Not all stator bars are the same, and different types of generators require different bar and coil designs. This paper will present a survey of the various generator types and associated bar and coil designs. Not only will differences in cooling technologies be highlighted, but different insulation systems and corona suppression arrangements will also be discussed. Various series connections and lead group transpositions will also be discussed. A discussion on end winding support systems and approaches will also be presented. Finally, key design features to incorporate higher output, lower losses and improved generator efficiency will be included. The paper will provide an excellent background on the stator winding design features owners should look for and evaluate as they plan a future generator rewind. Design Choices There are many type of bar/coil designs available, depending upon the cooling method (air, hydrogen, oil or water), rating (conventional or inner-cooled), and geometry to name a few design factors. Smaller size coils typically correlate with smaller rated output, but this also depends upon cooling technology. Water-cooled coils, due to the greater heat transfer possible using water cooled hollow conductors, tend to be significantly smaller in size compared to equivalent rated inner gas cooled coils. Many different coil types and configurations. 1 Presented at 2014 Russia Power, Moscow Multiturn versus Single Turn Bar Over the last forty years of generator design, it has been typical for multi-turn coils to be used in small, lower rated, steam turbine driven generators and also in hydrogenerators up to about 100 MVA in rated output. In larger steam turbine driven generators and hydrogenerators rated higher than 100 MVA, a single turn bar winding is more often used. Full Loop Multiturn Coil. Both single turn bars and multiturn coils are made up of copper strands with strand insulation and groundwall insulation. Coils have individual turns, often with dedicated turn insulation, while single turn bars don’t. Coils also have two legs or cell sections, making a complete loop, while bars are typically “half-coils.” Multiturn coils are most often utilized in hydrogenerators, with short core lengths and many core slots, while bars or half coils are most often used in larger turbo generators with long length cores and fewer core slots. The full loop multiturn coil becomes more economical to handle and wind when applied to hydrogenerators with many slots. Likewise on large turbogenerators, single turn bars or half coils are much easier to handle than a full loop coil would be. Single turn bars (half coils). 2 Presented at 2014 Russia Power, Moscow When rewinding, the option does exist to change a multiturn coil to a single turn bar. Some owners are choosing this option more frequently, since the turn insulation can be a weaker area in the coil design and winding failures are often due to a surge and failure of the turn insulation. The choice of a multiturn coil or single turn bar is often dictated by the owner, perhaps based on previous bad experience, such as an untimely failure. Although rewinds can include a new core with much better core steel material, an increase in flux density in the magnetic circuit, may also result in higher field current, heating and losses. Multiturn coil design provides more flexibility in accommodating these flux increases compared to designs with a single turn bar. This is shown by the following equation for the electromotive force, emf: e.m.f. = Uphase × a × m/(kwinding × t × N) Where: Uphase is phase voltage a is number of parallels m is number of phases kwinding is winding coefficient defined by winding pitch, shortening and slot skew t is number of turns N number of coils in the stator core Some negative aspects of the multiturn design include the risk of turn insulation failure, as well as “top strand heating.” Top strand heating results from eddy current losses that are greater in the top strands. For bars, this is not an issue due to the high radial thermal conductivity with the Roebel type transposition. The equivalent radial thermal conductivity coefficient (KB) for bars rad_eqv_bar can be characterized by the following equation: rad_eqv_bar=copper × n × hstrand / Ltransp 180° Where copper is copper thermal conductivity n is number of strands in the bar in radial direction hstrand is the copper strand height Ltransp 180° is the length of 180° transposition (from full bar height) at: Ltransp 180°=n × Ltransp_single_transp Ltransp_single_transp is the length of single transposition The equivalent radial thermal conductivity coefficient (KM)for multi-turn coils rad_eqv_MT can be characterized by thefollowing equation: rad_eqv_MT=strand_insul × (n-1) x hstrand_ins_bu / (n × (hstrand_ins_bu + hstrand) Where: strand_insul is insulation thermal conductivity n is number of strands in the bar in radial direction hstrand_ins_bu is the strand insulation build up hstrand is the copper strand height The ratio K at all conditions is the following: K= (copper/strand_insul) × (hstrand)2/(Ltransp_single_transp × hstrand_ins_bu) 3 Presented at 2014 Russia Power, Moscow To estimate the order of K consider that copper = 390W/(m×°K), strand_insul =0.2 W/(m×°K) and some typical dimensions such as , Ltransp_single_transp= 40mm, hstrand = 1.8mm, hstrand_ins_bu = 0.25mm. Than K=(390/0.2) × (1.8)2/(40 × 0.25) ≈ 630. Thus, we can say that bar heat transfer in the radial direction is more than 500 times better than a multiturn coil heat transfer in the radial direction. Therefore, the top strand heating is not an issue for bars. The situation of top strand heating could be aggravated in case of top strands allocation very close to the air gap when part of the main flux could reach the top strands. This phenomenon need to be taken in account if top strand allocation is closer to the air gap than ½ of slot width. In that case top strand heating becomes even worse for multiturn coils. Comparison of Stator Bar (Left) and Multiturn Coil (Right) heating. GVPI versus BVPI versus Resin Rich/B-Stage The stator winding manufacturing insulation scheme, whether Global VPI, Bar VPI, or Resin Rich/B-Stage, often is based on the manufacturer’s facilities and experience. The basic differences are the following: GVPI – Global Vacuum Pressure Impregnation – the entire stator is vacuum pressure impregnated. The system, when done properly, is efficient, low cost and reliable. One drawback involves the repairability of the stator winding should a bottom coil fail. Although repairs are possible, rewind of a GVPI stator winding is very difficult – more difficult than a BVPI winding. BVPI – Bar Vacuum Pressure Impregnation (can be referred to as single coil VPI) – each individual bar or coil is vacuum pressure impregnated. The resin impregnated coil is then cured and the hard coil is installed in the stator core. With this process, epoxy resin is driven into the coil and tape. A vacuum is pulled first, then Nitrogen gas pressure is applied. This process can be more expensive 4 Presented at 2014 Russia Power, Moscow than the other two systems, since large Vacuum Pressure Chambers and large amounts of epoxy resin are necessary, and custom made steel dies are precisely machined for each finished size. When done well, the bar/coil is essentially void free with very low Power Factor readings. This system also has the advantage should an individual bar/coil fail, it can be removed and replaced without damaging the core or requiring an entire rewind. Individual water cooled stator bars in BVPI resin tank Resin Rich/B-Stage – This insulation system uses insulating tapes are already preloaded with epoxy resin. When applied and heated, resin flows and with pressure and temperature the insulation is cured. Well made bars/coils with this system utilize expensive autoclaves for applying the proper pressure for forming the coil to the desired shape. Often times, however, industrial shops manufacture coils of this system utilizing inexpensive equipment that result in poor quality bars and coils. Most owners and specifications allow both BVPI and Resin Rich/B-stage replacement windings, since if done properly by high quality high voltage coil manufacturers, performance is comparable. GVPI windings are common on new machines but rarely used on rewinds. Uprate It often is possible to uprate the generator to a higher MVA output and do it as part of a rewind/refurbishment project. Older generators often can be uprated the largest amounts, since their old insulation is less efficient, having lower dielectric strength compared to more recent advances in insulation technology. Stator bars/coils manufactured with shellac mica, asphalt, and even polyester, can be upgraded to more advanced epoxy mica glass materials. The newer insulation is stronger and can allow more copper to be placed into the slot. This decreases I2R loss, and combined with other design enhancements, can results in significant increases in MVA output on the order of 10 to 50% for some very old machines. Most owners state a specific VPM (Volts Per Mil) in the specification to keep the high voltage coil suppliers on a level playing field. A value of 2.65 kV/mm (65 5 Presented at 2014 Russia Power, Moscow VPM) is a common specification requirement that balances maximum performance with long term reliability. A higher value may appear attractive in the proposal evaluation since it will allow a higher MVA output, but long term reliability is jeopardized – premature failure of the bar/coil is more likely since the insulation is stressed more heavily. Transposition The right transposition is a critical choice in the preparation of a rewind, but most often this choice is made by the supplier rather than the owner. Bar/Coil transpositions are necessary to reduce and even eliminate circulating current losses in the coil. These losses are generated from the voltage potential between strands of different heights in the slot. For single turn bars, Roebel transpositions in the cell portion are most common, ranging from 360 to 540 degrees for most applications, although the author’s company has manufactured bar Roebel transpositions as high as 900 degrees. The transposition virtually eliminates circulating current losses in the coil by ensuring that each strand occupies the same height position, for the same distance, as every other strand. 360 degree Roebel bar transposition The Roebel transposition is very efficient in circulation current suppression as well as low manufacturing costs. While the 360 degree Roebel is most common, longer core lengths can accommodate a more efficient 540 degree Roebel. Higher degree Roebels as mentioned above, can be incorporated by adding transpositions in the end turns. Roebel transpositions in the cell are not new, but do represent a significant improvement over previous methods of transposition to reduce circulating current losses. These older methods included the lead group transposition and the strand by strand transposition. Both methods require more precision at site during the field winding process, and many older machines with these types of transpositions suffer from strand shorts. The author’s company, as part of a start rewind in Africa, converted the existing strand by strand transposition to a Roebel bar transposition, completed the on-site rewind in record time. A sister machine, rewound by the OEM, kept the strand by strand transposition. That 6 Presented at 2014 Russia Power, Moscow machine failed on startup due to strand shorts in the connections, and the author’s company was asked to step in and rewind that sister machine also at that point. Strand by strand transposition. In this design, the OEM did not convert the strand by strand transposition. It failed on startup. Conversion to Roebel bar transposition by author’s company allows solid clip connection. It started up successfully. Transpositions in multiturn coils are typically handled by a 180 degree twist in one of the turns. This twist inverts the conductor strands for the remaining path of the coil, so the same effect of circulating current reduction is accomplished. The placement of the twist is critical to effecting the loss reduction. This is a point the designer must take into account. 7 Presented at 2014 Russia Power, Moscow Twist in Multiturn Coil Core and Number of Slots Unless the core is being replaced, and options are on the table to change the number of slots, all bar/coil rewind designs must work within the existing parameters of the stator core. That means that the core length, core diameter, number of slots and slot size remains fixed. The design of the coil in the slot can be changed to increase MVA output. This can be accomplished by increasing the copper content and changing the number and size of strands, primarily. Overall stator winding losses can also be affected by changing the “mean length turn.” If the core is replaced, which is common on older hydrogenerators, options to change the number of slots are possible. Changing the number of slots can improve output, efficiency, and even reliability of the refurbished machine. Corona Suppression System There are different styles of Corona Suppression Systems (CSS) in the industry today, varying only by the number of different high voltage bar/coil suppliers and materials available in the market. Primary choices include paint or tape systems in the bar/coil cell portion, and the same in the transition area moving into the end turns. A well tested system that is compatible with the existing groundwall insulation and slot packing system is essential. A common issue with many suppliers is in the transition area between the semi-conductive material in the cell and the gradient material in the cell bend just outside 8 Presented at 2014 Russia Power, Moscow the core. Corona burning causing degradation of the CSS can occur, requiring regular inspections and maintenance to maintain reliability. CSS that are paint based are typically less expensive and easy to repair but can be more easily scratched and damaged. CSS that are taped based are more expensive and more difficult to repair, but more resistant to scratching and damage. The author’s company has developed a CSS that includes both paints and tapes. The CSS has been VET (Voltage Endurance Tested), blackout and UV (Ultra Violet) camera tested, and proven to be compatible with our own insulation design. Slot packing An effective slot packing system must hold the bar/coil tight in the slot, free from excessive vibration and looseness that can lead to slot discharge and vibration sparking. Again, there are many options out there, but a tried and true system for many decades is the use of semi-conductive side ripple springs. This system, used by the author’s company for over 30 years, includes insulating springs that are compressed when the bar/coil is installed into the slot core. This pre-loads the spring, similar to a Belville washer. The pre-load will keep the bar/coil pressed tight against the core slot, even after many years of operation, when insulation and top fillers and wedges shrink and the bar/coil will have a tendency to become loose in the slot. Side ripple springs are semconductive with carbon black to promote grounding of the coil surface to the core. Other systems such as flat side and round packing promote tightness initially, but overtime become loose. GVPI winding will develop cracks in the resin between the coil and the core if not properly packed with shear stress relieving surfaces. Similarly, top ripple springs are commonly used to provide radial pressure on the bar/coil in the slot to keep it tight. These do not have to be semi-conductive since there is no radial path the core ground. Semi-conductive side ripple springs next to bars in slot. 9 Presented at 2014 Russia Power, Moscow End Winding Bracing Not to be forgotten is the importance of end winding bracing on the installed bars/coils. Severe damage to the stator winding can occur during transient faults, if the end winding is not braced and supported properly. Likewise, changes in temperature from cold, startup conditions to hot, full load conditions, create thermal stresses on the winding that must be managed. A bracing system that provides radial support of electromagnetic forces, but allows axial expansion from temperature changes is most effective. These types of systems are expensive and not always included in the original equipment due, primarily to cost cutting or lack of design knowledge. A rewind provides the opportunity to include this important system and this is a choice the owner should make to improve long term reliability. Bracing Upgrade on 7FH2 Rewind Conclusions It is important that owners know that they can have a lot of influence over the design and manufacture of new stator bars and coils, both for new units and rewinds. Choices dictated by the owner can affect quality, schedule, and long term reliability. Key decisions include whether to ask for bars or coils, BVPI or RR, transposition details, uprated MVA, CSS, and end turn bracing upgrades. Each of these decisions plays a crucial role in the final design, manufacture, installation, testing and final successful operation of the stator winding. References 1. Eddy Currents in Large Slot-Wound Conductors, A. B. Field. AIEE Transaction, volume 24, 1905, pages 659-86. 2. Transpositions in Turbogenerator Coil Sides Short Circuited at Each End, B.J. Bennington and W.C. Brenner, IEEE Transaction on Power Apparatus and Systems, Vol. 89, No. 8, 1970. 10 Presented at 2014 Russia Power, Moscow 3. Power Factor Tip-Up Reduction in High Voltage Coils, F.T. Emery, IEEE Symposium on Electrical Insulation, June, 1992. 4. Rewinding generators to uprate hydro plant, C. Gentilini, Water Power & Dam Construction, January 1977. 5. Semi-Conducting Corona Suppression System for High Voltage Windings, B. Nindra and A. Khazanov, IRMC, June 2002. 6. Insulation Degradation in Generator Stator Bars due to Spark Erosion and Partial Discharge Damage, W. Moore and A. Khazanov, IEEE, 2010. 7. Solving Stator End-Winding Dusting and Resonance Issues, B. Martin and B. Moore, 80th Doble Client Conference, April, 2013. 11