[0001] The present disclosure relates to a high-voltage device, particularly to a high-voltage
power device.
[0002] One object to be achieved is to provide a high-voltage device with improved properties,
e.g. a reduced noise radiation.
[0003] According to an embodiment, the high-voltage device comprises at least one winding
and at least one structure adjacent to the at least one winding. The structure comprises
a micro-architectured material.
[0004] During operation of a high-voltage device with a winding, considerable forces develop,
e.g. due to magnetostriction and core resonances. Also the winding experiences strong
radial and axial forces due to the high magnetic fields involved. This leads to noise
production. The present invention is, inter alia, based on the idea to use one or
more micro-architectured materials in a high-voltage device. Micro-architectured materials
are materials which can be tailored to desired properties, like the capability of
absorbing vibro-acoustic energy. Also the thermal and electric insulation properties
can be tailored. The usage of micro-architectured materials in high-voltage devices
provides many possibilities for improving the properties of the high-voltage device.
[0005] A high voltage device is a device in which, during operation, voltage difference
of more than 1000 V or more than 1500 V between electrical components of the device
appear. For example, during operation, electrical currents of more than 100 A or more
than 1000 A flow in the high-voltage device.
[0006] The high voltage device comprises one or more windings. All features disclosed herein
for one winding are also disclosed for the other winding(s). The winding may be wound
around a core of metal, e.g. steel. The high-voltage device may be transformer, particularly
a power transformer, or a reactor.
[0007] In case of two or more windings, the at least two windings may be galvanically insulated
from each other. The high-voltage device may comprise a primary winding, a secondary
winding and a tertiary winding. The at least two windings are, for example, wound
around a common core. The windings may be arranged adjacent to each other, i.e. wound
around parallel axes which are spaced from each other. Alternatively, the windings
may be wound concentrically around the same axis.
[0008] The structure which is adjacent to the at least one winding comprises or consists
of micro-architectured material. The structure may be arranged between two windings
or may be arranged inside of the at least one winding. The high-voltage device may
comprise two or more structures comprising a micro-architectured material adjacent
to the at least one winding. All features disclosed for one structure are also disclosed
for all other structures of the high-voltage device.
[0009] For example, the at least one structure may be electrically insulated from the at
least one winding. Particularly, the structure is spaced from the at least one winding.
[0010] Micro-architectured materials are also known as metamaterials or MAM. They are a
class of porous multiscale materials formed by the periodic or semi-periodic assembly
of one or more unit-cells or representative volume elements (RVE) in the design space.
The unit cell or RVE may have dimensions in the micrometer to millimeter range. Micro-architectured
materials can be designed isotropically or anisotropically. For example, micro-architectured
materials provide the possibility to tailor the Poisson's ratio and/or the Young's
modulus through the design of the micro-architectured material.
[0011] According to a further embodiment, the micro-architectured material is designed for
damping noise generated in the high-voltage device during operation. This can be achieved
by tailoring the Young's modulus and/or the Poisson's ratio of the micro-architectured
material. Particularly, the micro-architectured material may be designed to mitigate
the effect of radial and/or axial winding forces and/or may be fine-tuned for force
overtones and/or the eigenfrequencies of the high-voltage device.
[0012] According to a further embodiment, the micro-architectured material has a Young's
modulus between 3 MPa inclusive and 200 GPa inclusive. For example, in case of an
anisotropic Young's modulus, this Young's modulus is the average Young's modulus averaged
over all directions or is the minimum Young's modulus or the maximum Young's modulus.
[0013] According to a further embodiment, the micro-architectured material has a negative
Poisson's ratio or a Poisson's ratio of zero. These materials have unique properties
and functionalities that are interesting for a wide range of potential applications.
The micro-architectured material may have one single value of the Poisson's ratio
or it may vary depending on the direction of compression and or depending on the location
of the material in the structure. The micro-architectured material may be shape-shifting
or shape-morphing.
[0014] The hexagonal (with positive or negative angle) and chiral unit cells are some examples
of the unit cell geometries which can be used for the design of micro-architectured
materials with tunable material properties, like the Poisson's ratio. Thus, already
by the design of the unit cell's geometry, one can reach a broad range of elastic
properties or even extend this range through random integration of unit cells in the
design space of the lattice structures, which allows for targeting very specific combinations
of mechanical properties and/or advanced functionalities.
[0015] According to a further embodiment, the micro-architectured material is formed by
an additive manufacturing process, for example by 3D-printing. The skilled person
is able to detect whether a structure was formed by additive manufacturing. For example,
when using 3D printing, the micro-architectured material is formed in one piece or
integrally, i.e. without internal interfaces.
[0016] According to a further embodiment, the micro-architectured material has an anisotropic
structure. Particular, with respect to one of the windings, the micro-architectured
material may have a different structure in radial direction than in circumferential
and/or axial direction. Anisotropic structures can provide particular beneficial effects
in view of noise damping.
[0017] According to a further embodiment, the micro-architectured material has a porous
structure. For example, the porosity is between 10% and 90% inclusive. Thereby, "porosity"
is defined as the cavity volume (volume of the pores) over the total volume.
[0018] According to a further embodiment, the structure is at least partially arranged in
oil. Particularly, the micro-architectured material is arranged in the oil. The oil
is used for cooling and/or electrical insulation in the high-voltage device. For example,
the structure is embedded in the oil, i.e. is in contact with the oil.
[0019] According to a further embodiment, the pores of the micro-architectured material
are formed such that the micro-architectured material is permeable for the oil. For
example, the micro-architectured material is impregnated with the oil.
[0020] According to a further embodiment, the micro-architectured material is at least partially
formed of cellulose. Additionally or alternatively, the micro-architectured material
may be at least partially formed of polymer and/or metal.
[0021] According to a further embodiment, the structure is a barrier between two windings
of the high-voltage device. Additionally or alternatively, the structure is a barrier
between the at least one winding and a housing of the high-voltage device. The housing
of the high-voltage device surrounds the winding(s), for example. The housing may
be a tank or tank wall, respectively. Especially, the barrier may be formed as a plate
or as a cylinder shell.
[0022] According to a further embodiment, the structure is a spacer or a spacer-block for
one of the winding. Spacers are used to support and separate individual turns of a
winding from each other in axial direction and/or to support the turns in radial direction.
Spacer-blocks are in particular there to maintain certain distance between winding
ends and the core.
[0023] According to a further embodiment, the structure is an electrical insulation of a
winding. For example, the structure is a cover around the turns of a winding.
[0024] According to a further embodiment, the structure is spaced from the windings. Particularly,
the structure or at least the micro-architectured material thereof is not in contact
with any of the windings. The gap between the structure and the windings may at least
be partially filled with oil.
[0025] According to a further embodiment, the micro-architectured material has a TPMS structure.
"TPMS" stands for triply periodic minimal surfaces. This is a non-intersecting 3D
surface characterized by a zero value of mean curvature at each point.
[0026] According to a further embodiment, the micro-architectured material has an octet
structure. This means that a unit cell or the RVE of the micro-architectured material
has an octet structure. Alternatively, the micro-architectured material or the unit
cell / RVE has a tetrakaidekahedron or Gurtner-Durand structure or an irregular tetrahedron
structure or a cube structure or a diamond structure or a Kelvin structure or a rhombicuboctahedron
structure or a double-pyramid dodecahedron structure.
[0027] Hereinafter, the high-voltage device will be explained in more detail with reference
to the drawings on the basis of exemplary embodiments. The accompanying figures are
included to provide a further understanding. In the figures, elements of the same
structure and/or functionality may be referenced by the same reference signs. It is
to be understood that the embodiments shown in the figures are illustrative representations
and are not necessarily drawn to scale. In so far as elements or components correspond
to one another in terms of their function in different figures, the description thereof
is not repeated for each of the following figures. For the sake of clarity, elements
might not appear with corresponding reference symbols in all figures.
Figures 1, 3 and 4 show different exemplary embodiments of the high-voltage device,
Figure 2 shows an exemplary embodiment of the winding of a high-voltage device,
Figures 5 to 17 show different exemplary embodiments of the micro-architectured material,
Figure 18 shows a further exemplary embodiment of the high-voltage device.
[0028] Figure 1 shows a first exemplary embodiment of a high-voltage device 100, namely
a power transformer 100. The high-voltage device 100 comprises a housing 6 or tank
6, respectively, in which three windings 1, 2, 3 are arranged. The windings 1, 2,
3 are wound around a common core 5.
[0029] For electrical insulation and cooling purposes, the tank 6 is filled with oil. A
barrier 40 of a micro-architectured material 4 is arranged between the tank 6, i.e.
the tank wall, and the windings 1, 2, 3. The barrier 40 of the micro-architectured
material 4 is arranged in the oil and impregnated with the oil. Particularly, the
micro-architectured material 4 comprises pores to enable oil to penetrate the micro-architectured
material 4. By way of example, the micro-architectured material is produced by an
additive manufacturing process, like 3D-printing. It may comprise or consist of polymer
and/or cellulose and/or metal. The micro-architectured material 4 is designed such
that the barrier 40 damps the noise generated in the high-voltage device 100 during
operation, i.e. absorbs vibrations.
[0030] As can be seen in figure 1, the barrier 40 forms a housing surrounding the windings
1, 2, 3. The barrier 40 is spaced from each of the windings 1, 2, 3 such that it does
not adjoin any of the metallic parts of the windings 1, 2, 3. In other words, the
barrier 40 is galvanically isolated from the windings 1, 2, 3. This allows to form
the micro-architectured material at least partially from metal.
[0031] Figure 2 shows a detailed view of a winding 1, 2, 3 as used, for example, in the
transformer 100 of figure 1. The winding 1, 2, 3 comprises a plurality of turns 10
wound around the core and radially spaced from the core by spacer-blocks 11, 41. Some
spacer-blocks 41 are formed of the micro-architectured material 4. Also here, the
micro-architectured material 4 may be impregnated with the oil of the high-voltage
device and/or may serve as a noise damping element of the high-voltage device 100.
[0032] Figure 3 shows a further exemplary embodiment of a high-voltage device 100 with all
the windings 1, 2 arranged concentrically. Cylindrically shaped barriers 40 of the
micro-architectured material 4 are arranged in radial direction between the two windings
1, 2 and between the inner winding 1 and the core 5. Another cylindrically shaped
barrier 40 is formed around the outer winding 2.
[0033] Also in case of figure 3, the barriers 40 may be arranged in the oil and are spaced
from the windings 1, 2. The micro-architectured material 4 of the barriers 40 may
be designed for damping noise generated in the high-voltage device 100.
[0034] The exemplary embodiment of a high-voltage device of figure 4 is based on the one
of figure 1. Additionally, plate-shaped barriers 40 of micro-architectured material
4 are arranged between each two adjacent windings 1, 2, 3. These plate-shape barriers
40 are again arranged in the oil of the high-voltage device 100 and are designed for
noise damping.
[0035] Figure 5 shows a first exemplary embodiment of a micro-architectured material 4 with
a macroscopic piece of the micro-architectured material on the left side and a detailed
view of a lattice representative volume element (RVE) or unit cell of the micro-architectured
material on the right side. Here, the RVE has a cubic octet structure. The individual
struts of the shown RVE may be cylindrical with radius and length between 10 um and
1000 µm, for example.
[0036] In the exemplary embodiment of figure 6, the RVE has a tetrakaidekahedron or Gurtner-Durand
(isotropic) structure.
[0037] In the exemplary embodiment of figure 7, the RVE has an irregular tetrahedron (trigonal
symmetry) structure.
[0038] In the exemplary embodiment of figure 8, the RVE has a cube (cubic symmetry) structure.
[0039] In the exemplary embodiment of figure 9, the RVE has a diamond (cubic symmetry) structure.
[0040] In the exemplary embodiment of figure 10, the RVE has a Kelvin (cubic symmetry) structure.
[0041] In the exemplary embodiment of figure 11, the RVE has a rhombicuboctahedron (tetragonal
symmetry) structure.
[0042] In the exemplary embodiment of figure 12, the RVE has a double-pyramid dodecahedron
(transverse isotropy) structure.
[0043] In the exemplary embodiment of figure 13, the micro-architectured material has a
negative Poisson's ratio.
[0044] In the exemplary embodiment of figure 14, the micro-architectured material has a
Poisson's ratio of zero.
[0045] In the exemplary embodiment of figure 15, the micro-architectured material has a
positive Poisson's ratio.
[0047] Each of the materials of figures 5 to 17 can be used as a micro-architectured material
for the high-voltage devices of figures 1 to 4.
[0048] Figure 18 shows a further exemplary embodiment of the high-voltage device 100. In
this case, the high voltage device could be a power transformer or a power reactor.
The turns 10 of the winding 1 are axially spaced from each other with the help of
spacers 42. The spacers 42 are formed of a micro-architectured material 4, e.g. of
one according to figures 5 to 17.
[0049] The embodiments shown in the Figures 1 to 18 as stated represent exemplary embodiments
of the high-voltage device and the micro-architectured material. They do not constitute
a complete list of all embodiments according to the high-voltage device and the micro-architectured
material. Actual high-voltage devices and micro-architectured materials may vary from
the embodiments shown in terms of arrangements and sizes, for example.
Reference Signs:
[0050]
- 1
- winding
- 2
- winding
- 3
- winding
- 4
- micro-architectured material
- 5
- core
- 6
- housing / tank
- 10
- turns
- 11
- spacer block
- 40
- structure / barrier
- 41
- structure / spacer-block
- 42
- structure / spacer
- 100
- high-voltage device
1. High-voltage device (100) comprising
- at least one winding (1, 2, 3),
- at least one structure (40, 41, 42) adjacent to the at least one winding (1, 2,
3), wherein
- the structure (40, 41, 42) comprises a micro-architectured material (4).
2. High-voltage device (100) according to claim 1, wherein
- the micro-architectured material (4) is designed for damping noise generated in
the high-voltage device (100) during operation.
3. High-voltage device (100) according to claim 1 or 2, wherein
- the micro-architectured material (4) has a Young's modulus between 3 MPa and 200
GPa.
4. High-voltage device (100) according to any one of the preceding claims, wherein
- the micro-architectured material (4) has a negative Poisson's ratio or a Poisson's
ratio of zero.
5. High-voltage device (100) according to any one of the preceding claims, wherein
- the high voltage device (100) is a transformer or a reactor.
6. High-voltage device (100) according to any one of the preceding claims, wherein
- the micro-architectured material (4) is formed by an additive manufacturing process.
7. High-voltage device (100) according to any one of the preceding claims, wherein
- the micro-architectured material (4) has a porous structure.
8. High-voltage device (100) according to claim 7, wherein
- the structure (40, 41, 42) is at least partially arranged in oil,
- the pores of the micro-architectured material (4) are formed such that the micro-architectured
material (4) is permeable for the oil.
9. High-voltage device (100) according to any one of the preceding claims, wherein
- the micro-architectured material (4) is at least partially formed of a polymer.
10. High-voltage device (100) according to any one of the preceding claims, wherein
- the micro-architectured material (4) is at least partially formed of cellulose.
11. High-voltage device (100) according to any of the preceding claims, wherein
- the structure (40, 41, 42) is a barrier (40) between two windings (1, 2, 3) and/or
a barrier (40) between the at least one winding (1, 2, 3) and a housing (6) of the
high-voltage device (100).
12. High-voltage device (100) according to any of the preceding claims, wherein
- the structure (40, 41, 42) is a spacer (42) or a spacer-block (41) for one of the
windings (1, 2, 3).
13. High-voltage device (100) according to any one of the preceding claims, wherein
- the micro-architectured material (4) has a TPMS structure.
14. High-voltage device (100) according to any one of the preceding claims, wherein
- the micro-architectured material (4) has an octet structure or a tetrakaidekahedron
structure or an tetrahedron structure or a cube structure or a diamond structure or
a Kelvin structure or a rhombicuboctahedron structure or a double-pyramid dodecahedron
structure.
15. High-voltage device (100) according to any one of the preceding claims, wherein
- the micro-architectured material (4) is at least partially formed of metal,
- the structure (40, 41, 42) is spaced from the at least one winding (1, 2, 3).