Optimization of the power transformer tank.
Parpala, Radu Constantin ; Stancu, Octavian ; Popescu, Diana 等
1. INTRODUCTION
Power transformers are designed and built according to high
engineering standards to provide many years of outstanding performance
and reliability (*** IEC, 2005). Electrical devices, insulation and
cooling systems are subjected to advanced technologies which require
safe and durable design solutions for the mechanical part, too.
Experience has shown that a key technical issues can be analyzed using
3D modeling and FEM analysis (Prevost & Woodcock, 2007), but few
references are found regarding the behavior of the transformer tank. The
vast majority of the installed power transformer tanks were not designed
using FEM.
The paper deals with optimization attempts and design improvements
of the tank for a 40 MVA power transformer. Starting from an initial
design an improved solution was calculated and validated. Reinforcements
were changed. The tank weight decreased and the total displacements on
the side walls were reduced. A new solution was found as the basis for
the new conceptual design of the tank. Remarks regarding
parameterization and optimization procedures were included.
2. MODEL PREPARATION
The transformer tank is a welded structure designed for strength,
durability, and compact form. It accommodates the core-and-coil assembly
and the oil filling, usually weighing several tones. This calls for a
statically secure and oil-leak-proof design, with an optimized weight.
[FIGURE 1 OMITTED]
Tank structures of power transformers are exposed to wide
variations in pressure during testing and subsequent start-up periods.
The design of the wall reinforcements is a tough job as it must take
into account the mounting elements, tune the static behavior with the
total weight and prevent magnetic flux leakage.
An initial design (T1) of a 40 MVA power transformer tank,
comprising vertical reinforcements and a horizontal band, was compared
with a modified variant (T2) with only vertical ribs. The CAD models of
the two tanks were built using CATIA V5, as shown in fig. 1. The
assemblies comprise 212 and 310 parts respectively.
When completing the CAD models clashes and clearances were solved.
New constraints were added to assure contact on surfaces, not on edges,
tiny features were eliminated and all the gaps were closed. Some parts
were rebuilt in order to assure a correct closure of the bottom part of
the assemblies. Other defeaturing options were activated when the CAD
models were imported to the solver. The volume of the two tanks was
8.027 [m.sup.3] for T1 and 7.922 for T2 corresponding to a total mass of
6302.5 kg and 6.218.7 respectively.
Model preparation for FEM analysis of large welded structures is
difficult to complete because the solver requires a clean geometry and
topology. Penetration and gap checks were performed with an accuracy of
[10.sup.-16] mm in the contact regions (ANSYS, 2007). Because solid
elements were used, the element size was chosen taking into account the
wall thickness and contact control options were activated. Figure 2
shows T2 meshed model, as well as details on side walls, while Table 1
contains mesh characteristics for both tanks. The wave front decreased
for the improved variant, which enabled shorter computing time. For each
structure two static FEM analyses were performed corresponding to the
required physical tests regarding power transformer tanks. The load
cases were: vacuum and 0.5 bar internal pressure. Although the load
cases presume a linear analysis, multiple contact regions due to the
bolted connections and welded parts influenced not only the mesh
strategy, but also the behaviour of the two tanks (Gomez, 2002).
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
[FIGURE 4 OMITTED]
3. FEM RESULTS
At the same load and close geometry characteristics, the maximum
values of the total displacements are relevant regarding the static
behaviour and tank stiffness (Heckman, 1998). Figures 3 and 4 show
isometric views of the two tanks and the displacement maps for the
second load case, which was 0.5 bar internal pressure. When processing
the results the scale factor was kept similar, in order to show the
improved behaviour of the new design. The total displacement decreased
with 50%, from 8.6229 mm (T1) to 4.4746 mm for the T2 variant. Stress
distribution was also improved because stress concentrators were
eliminated and safety factors were significantly increased.
The calculations were the basis for changing the tank
reinforcements for future projects. Optimization procedures, as well as
sensitivity analysis were performed on reduced models of the side walls.
The number of the vertical ribs, as well as the rib thickness and the
rib height are now obtained using multicriteria optimization procedures,
based on parameter definition using recent functionalities of the
solver. Many "what is scenarios" were completed.
4. EXPERIMENTS
Power transformer tanks are special cases of pressure vessels
design. Before assembling the core-and-coil and oil filling, the
required experiments are performed on the tank (Declercq, &
Lakhiani, 2006).
When analyzing the first design variant information from
experiments was already available. The average error of the calculated
displacements for the pressure test was less than 10%, which is pretty
good for a large and complex structure. The measurement devices for the
pressure test of the improved tank T2 were placed exactly in the areas
where local and global maximum were revealed by the FEM analysis.
For a better description of the tank behavior the measurement
points were increased to 10, and the devices were placed both on the
vertical ribs and on the walls. Figure 5 shows a comparison between FEM
results and measured displacements (MES).
All the tests, both vacuum and 0.5 bar pressure confirmed that the
design and the simulation were correct. The accuracy of the computed
displacement was improved as well, and there were measured points were
the error decreased under 0.5% (see points 7 and 9 Fig. 5). This proved
a better model preparation strategy.
[FIGURE 5 OMITTED]
5. CONCLUSION
Worldwide the actual fleet of power transformers is close to the
lifetime. New technologies are in progress requiring design improvements
for the mechanical part too. FEM simulation is a powerful tool for the
transformer design. It offers rapid verification procedures and points
out useful practical information obtained priory the final tests. A new
solution was found as the basis for the new conceptual design of the
tank.
Design optimization is an innovation tool, minimizing time and
costs and providing innovative design solutions. Parameterization of the
reinforcement elements allowed sensitivity analysis and shape
optimization procedures. New attempts are in progress for combining
topology and shape optimization procedures and to customize the CAD-FEM
environment.
Bringing simulation and analysis into design is the basis for a
reliable, cost-efficient and durable product. The paper demonstrates the
efficiency of a simulation driven design.
6. REFERENCES
ANSYS (2007). ANSYS Structural Analysis Guide, ANSYS INC., Huston
2007
Declercq, J. & Lakhiani, V.K. (2006). Building reliability into
design of transformers for reliability of electrical systems, Available
from: www.cigre.cl/sem_inter_cigre_nov_2005/
presentaciones/crompton.pdf, Accessed:2009-01-18
Gomez, E. (2002). Welded Joint Analysis for Pressure Vessels,
Available from: http://www.ansys.com/events/proceedings/
2002/PAPERS/98.pdf. Accessed: 2009-22-02
Heckman, D. (1998). Finite Element Analysis of Pressure Vessels,
MBARI
Prevost, T.A. & Woodcock, D.J. (2007). Transformer Fleet Health
and Risk Assessement. IEE PES Transformers Committee Tutorial. Available
from: http://www. transformerscommittee.org/meetings/f2004_LasVegas/Min
utes/F04-Main.pdf, Accessed: 2009-03-12
*** IEC 60076-7. (2005). Power transformers Part 7: Loading guide
for oil-immersed power transformers
PARPALA, R[adu] C[onstantin]; STANCU, O[ctavian]; POPESCU, D[iana]
& PUPAZA, C[ristina] *
* Supervisor, Mentor
Tab. 1. Mesh characteristics
Design variant T1 T2
Nodes 201346 414044
Equations 600525 1231551
Wave front 831 492
