Patent Grant
10978225
The subject matter of this patent document relates generally to insulators, and in particular to insulators suitable for use in high-voltage or plasma-facing environments.
High-voltage insulators are used in a variety of applications such as accelerators, plasma guns, Z-pinches, dense plasma focuses (DPFs), and others. They often have stringent requirements such as the ability to standoff high voltages, withstand the mechanical stresses associated with assembly and high current discharges causing material flexing, be easily machinable, handle high intermittent heat loads and temperature cycling, and maintain vacuum compatibility. These requirements are often conflicting leading to tradeoffs with material selection. Therefore, there is a need for designing and producing improved high-voltage insulators that can satisfy different, and seemingly contradictory, requirements.
The disclosed embodiments relate to high-voltage insulators and methods for assembling the same. The high-voltage insulators disclosed are capable handling contradictory and stringent requirements including providing high standoff voltages, the ability to withstand flexural forces and high temperature cycling. These and other features and benefits are provided by constructing the high-voltage insulators that include multiple sections of different material that are threaded to engage with one another without a need for epoxy or brazing.
In one example embodiment, a high-voltage insulator includes a first axially symmetric piece formed from a first material, a second axially symmetric piece formed from a second material, and an interface section where the first piece contacts with and forms a seal with the second piece. The interface section includes a first groove located on the first piece to accommodate a first gasket, a threaded section that includes two sets of matching threads, wherein a first set of the matching threads is formed on the first piece and a second set of the matching threads is formed on the second piece, and wherein a bottom section of the threaded section is proximate to the first groove. The interface section further includes a second groove located on the first piece and offset from the first groove in both a transverse direction and a longitudinal direction to accommodate a second gasket. In the above high-voltage insulator, the first material has a higher flexural strength than the second material, and the second material has a higher electric field standoff than the first material.
As noted earlier, high-voltage insulators must often withstand stringent and varied requirements that include the abilities to standoff high-voltages, withstand the mechanical stresses and flexural forces, accommodate high temperature fluctuations, and be machinable. For example, an insulating material such as poly-ether-ether-ketone (PEEK) is able to deform elastically under mechanical loads, has voltage standoff in excess of 480 V/mil (depending on manufacturer), and is fairly easy to machine. PEEK, however, is not able to withstand temperatures in excess of 480 degrees F. and suffers from higher water absorption than ceramic materials. Machinable Ceramics (such as MACOR, which is a machinable glass ceramic), on the other hand, are plasma-facing compatible, have superb electric standoff, and are able to withstand high heat loads, but they are difficult to machine into complex shapes and may be easily cracked when under stress.
In applications with such contradictory requirements, it can be advantageous to use multiple materials to form the insulator, where the properties of each material can be leveraged to obtain the desired performance. For example, an insulator design with a higher safety factor can be produced by reinforcing a weaker portion of the insulating material, such as when a quartz insulator is chosen and surrounded with impact-absorbing material. This approach, however, increases the size of the insulator assembly.
In some applications, not all sections of the insulator are subject to the same high temperatures, high energy fields, or mechanical stress levels. In such applications, it would be advantageous to build multi-piece insulators to take advantage of the superior characteristics of each material in the area that is needed. However, introducing breaks in the material provides a weak point, where electrical breakdown may occur. Epoxy may be used to attempt to prevent this breakdown, but epoxy is itself an insulating material with its own material properties that can negatively impact the desired insulator characteristics. For example, the epoxy may trap air bubbles, which contribute to partial breakdown and weakening of the material. It may also be possible to braze or deposit a material on top of an existing insulator, but this process can be time-consuming and may impart additional stress to the material.
The disclosed embodiment overcomes these and other shortcomings, and provide additional features and benefits, by providing insulator designs that include multiple sections of different material that are threaded to engage with one another without a need for epoxy or brazing. In some example embodiments, a threaded insulator combines plastic and ceramic materials to take advantage of each of their material benefits. The disclosed embodiments rely on precise machining of different materials (e.g., in some cases, less than 0.001″ tolerance) to combine the multiple sections onto a single continuous piece without a need for epoxy. The insulators that are produced according to the disclosed embodiments are suitable for use with plasma facing or high-voltage standoff applications. One example implementation includes a high-voltage insulator suitable for use in a dense plasma focus used to accelerate charged particles into a target.
The primary difficulty of building such an insulator assembly is the requirement to eliminate, as best as possible, the presence of gaps between the pieces. Small gaps during high-voltage operation may allow partial breakdown between the materials and degrade them over time to the point of failure. Furthermore, continuous paths between the insulators need to be made tortuous, and preferably with multiple inversions of the electric field to prevent, or reduce as much as possible, tracking between the anode and cathode that provide the electric field across the insulator. Such a tracking can cause material failures that reduce the insulation properties of the material and may lead to operation failures of the device.
By the way of example and not by limitation, the high-voltage insulators in the remainder of this document are described as consisting of two different materials engaged with each other via matching threads. It is, however, understood that high-voltage insulators with more than two sections and with more than two different materials can be constructed based on the disclosed technology.
It should be noted that in
The example insulator assembly in
According to the disclosed embodiments, each insulator piece can be designed independently except for the design of the interface between two pieces (sometimes referred to herein as the “joint”). The joint design falls into several sections.
In some embodiments, the lower gasket 108 is designed to have a volume that is slightly smaller than the volume of the corresponding lower groove 126 when the piece is assembled, but the vertical height (i.e., in the longitudinal or Z-direction, as shown in
The section of the bottom piece 102 above the lower groove 126 in the axial direction (e.g., Z-direction in
Another important characteristic is that the clocking on the thread start and end is identical (or as close as possible) in both the top and bottom pieces such that the locations of the thread start and stop points match. Otherwise, a portion of an incomplete thread on one piece is exposed and is not completely filled or complemented with a corresponding thread of the second piece.
The location of the threads in the transverse direction (e.g., Y-direction in the configuration of
Referring back to
In some embodiments, an optional chicane 116 is placed in the material with an upper gasket 112, as illustrated in the example configuration of
Another aspect of the disclosed embodiments relates to the process of assembly of the disclosed high-voltage insulators. First, the two parts with differing material properties are precision machined. Next, the top and bottom pieces are assembled without any gaskets. The two pieces are fully tightened to ensure all threads are engaged. Next, a marking is provided to identify aligned locations on the top and bottom pieces. In one example, the alignment marker can be a straight line that crosses the boundary between the top and bottom pieces. In another example, the alignment marker can be an adhesive tape. This marker, which is applied in the fully tightened state of the insulator with no gaskets, is used at a later stage of the assembly process to ensure proper alignment of the pieces.
Next, the insulator pieces are disengaged from one another, and the gaskets are fully covered by a grease, gel, or lubricant material that is suitable for use in high-voltage applications. For example, the gaskets can be heavily greased using Krytox or Apiezon M. The grease further helps to displace air in the sections of the two pieces during assembly and can fill any potential imperfections in the parts. While, the grease is not the primary voltage standoff material it provides an additional barrier to mitigate surface tracking. Next, the gaskets are placed in the corresponding grooves, and the insulator pieces are assembled and fully tightened until the two marker locations on the top and bottom pieces align.
In some instances, the multi-piece insulator can be difficult to assemble and disassemble because the gaskets provide a high friction contact between the pieces and then act to seal them together. To facilitate disassembly of the insulator, in some embodiments, the insulator may be cooled to lower temperatures to allow some loosening of the joint due to different thermal expansion coefficients of the two components. For example, the insulator assembly may be cooled to around 32 F, which can be achieved, for example, by applying an ice bath to the insulator.
The design of the disclosed high-voltage insulators can further be improved by suitable selection of gasket thicknesses and their arrangement. For example, in a three-gasket configuration (e.g., configuration of
There are several additional considerations that can facilitate the design, performance and assembly of the disclosed high-voltage insulators. First, extremely precise machining may be required, particularly on the threaded section of the insulator. The allowable tolerances are specific to the application of the insulator, and specifically the applied voltage levels (or electric fields). Higher voltages are more likely to cause runaway breakdowns in trapped volumes in the insulator; therefore, the higher the expected operating voltage across the device, the more precise the tolerances will need to be. In this example, an expected voltage of 100 kV DC is applied, with intermittent (e.g., less than 10 ns long) spikes of up to 1 MV that are possible. These parameters lead to target thread tolerances of less than approximately 0.002 inch, calculated using a Townsend breakdown model.
Second, since the gaskets are compressed to provide a sufficient seal, the friction during assembly and disassembly can be high. Furthermore, if the gasket volume is not properly or uniformly cut, the gasket can bunch in a section and prevent the assembly from closing. To mitigate these issues, the gaskets should be greased and cut precisely. In some embodiments related to three-gasket configurations, the middle gasket can have an additional piece of a low friction material (e.g., having a lower coefficient of friction that other sections), such as Kapton or Teflon. The lower-friction section can be placed in series with the other sections of the gasket (e.g., stacked on top of the gasket) which may have higher-friction characteristics. For some applications, even when the insulator is not fully sealed (e.g., due to high friction), the insulator can still be effectively used if all gaskets are compressed. In such instances, small misalignments may be mitigated by the gaskets that can deform to conform to the surrounding shapes, and by the grease or gel that fills the gaps or voids in the joint.
It is further important to properly select the dielectric constants of the materials. Due to dissimilarity of materials chosen for the insulator assembly, one material effectively enhances the electric field on the other material, and this may potentially exceed that material's local electric field strength. This is particularly important to manage at the thread locations, where local field enhancements are likely to occur. In some embodiments, a finite element analysis, such as COMSOL or ANSYS, is used to better understand these electric enhancement effects and to determine if the insulator is able to survive the intended application. For example, if such an analysis indicates excessive electric enhancement effects, materials with different dielectric constants may be used.
The disclosed embodiments have several advantages over conventional bulk insulators. First, the disclosed insulator designs allow mating of two unlike materials to take advantage of their differing physical characteristics. Second, it does not require epoxy which can trap gas, requires curing, and often requires additional pieces to align the parts properly. Furthermore, epoxy may not allow implementations with long track lengths as part of the threaded section of the insulator. Third, the threaded section of the insulator assembly coupled with properly designed gaskets makes the track length across the material extremely long, which forces the insulator failure modes (if any) to manifest as arcs through the material (rather than breakdown caused via surface tracking). This mitigates a need to estimate tracking failures, and allows one to have higher confidence in the potential failure locations.
In some example embodiments, where the high-voltage insulator includes a bottom, a middle and a top gasket, each located at an axially and longitudinally offset location within the high-voltage insulator with respect to one another, assembling the insulator with at least two gaskets in place includes placing the bottom, the middle and the top gaskets at the corresponding grooves or ledges on the bottom piece and allowing the middle gasket to deform prior to the bottom and top gaskets.
One aspect of the disclosed embodiments relates to a high-voltage insulator that includes a first axially symmetric piece formed from a first material, a second axially symmetric piece formed from a second material, and an interface section where the first piece contacts with and forms a seal with the second piece. The interface section includes a first groove located on the first piece to accommodate a first gasket, a threaded section that includes two sets of matching threads, wherein a first set of the matching threads is formed on the first piece and a second set of the matching threads is formed on the second piece, and wherein a bottom section of the threaded section is proximate to the first groove. The interface section further includes a second groove located on the first piece and offset from the first groove in both a transverse direction and a longitudinal direction to accommodate a second gasket. In the above high-voltage insulator, the first material has a higher flexural strength than the second material, and the second material has a higher electric field standoff than the first material.
In one example embodiment, the two sets of matching threads form a continuous path and have mated rounded edges. In another example embodiment, the two sets of matching threads have a sinusoidal profile. In yet another example embodiment, a start point of the first set of threads matches an end point of the second set of threads to form a complete thread around a circumference of the interface section. In still another example embodiment, the two sets of matching threads are configured to match one another within 0.002 inch or less.
According to an example embodiment, the second material is capable of withstanding higher temperatures than the first material, the first material is more readily shaped via machining operations compared to the second material, and the second material has a higher dielectric constant than the first material. In one example embodiment, the high-voltage insulator includes the first gasket and the second gasket, and a dielectric constant of the first gasket material or the second gasket material has a value that is between dielectric constant values associated with the first material and the second material. In another example embodiment, the first gasket has a smaller volume than the first groove, and a height in the longitudinal direction of the first gasket is larger than a height of the first groove. In one example embodiment, the first material is poly-ether-ether-ketone (PEEK) and the second material is machinable ceramic.
In another example embodiment, the high-voltage insulator includes a chicane formed as part of the first piece, one end of the chicane positioned proximate to a top section of the threaded section, the chicane being offset in the transverse and longitudinal directions from the first groove and the second groove. In one example embodiment, a circumference of the chicane is smaller than a circumference of the first groove and is larger than a circumference of the second groove. In another example embodiment, the high-voltage insulator further includes an additional gasket proximate to the top section of the threaded section and the chicane. In still another example embodiment, the additional gasket includes multiple sections, where a first section of the multiple sections has a lower coefficient of friction than other sections thereof. In yet another example embodiment, a height of the additional gasket in the longitudinal direction is selected to allow the additional gasket to provide a point of contact between the first and the second piece when the high-voltage insulator is being tightened, so as to allow the middle gasket to deform prior to the first and second gaskets.
According to yet another example embodiment, thicknesses of the first material and the second material at the threaded section in transverse direction depend on electrical standoffs of the first material and the second material. In one example embodiment, a product of an electrical standoff of the first material and a thickness of the first material in the transverse direction at the threaded section is substantially equal to a product of an electrical standoff of the second material and a thickness of the second material in the transverse direction at the threaded section. In another example embodiment, the two sets of matching threads, the first gasket and the second gasket enable formation of a tight seal between the first and the second pieces without a need for an epoxy.
Another aspect of the disclosed embodiments relates to a multi-piece high-voltage insulator assembly that includes a top piece formed from a first material having a first set of flexural, heat resistance, and electrical standoff characteristics suitable for a first environment, and a bottom piece formed from a second material having a second set of flexural, heat resistance and electrical standoff characteristics suitable for a second environment. The high-voltage insulator further includes an interface section comprising a threaded section including matching threads on the top and bottom pieces, a first groove to accommodate a first gasket, and a second groove to accommodate a second gasket. In this multi-piece high-voltage insulator assembly, the first groove is offset from the second groove in both axial and longitudinal directions, the threaded section enables assembly of the high-voltage insulator by mating the top piece and the bottom piece via the matching threads, and the first gasket and the second gasket enable formation of a tight seal between the top and bottom pieces without using an epoxy.
The foregoing description of embodiments has been presented for purposes of illustration and description. The foregoing description is not intended to be exhaustive or to limit embodiments of the present invention to the precise form disclosed, and modifications and variations are possible in light of the above teachings or may be acquired from practice of various embodiments. The embodiments discussed herein were chosen and described in order to explain the principles and the nature of various embodiments and its practical application to enable one skilled in the art to utilize the present invention in various embodiments and with various modifications as are suited to the particular use contemplated. While operations are depicted in the drawings in a particular order, this should not be understood as requiring that such operations be performed in the particular order shown or in sequential order, or that all illustrated operations be performed, to achieve desirable results. The features of the embodiments described herein may be combined in all possible combinations of methods, apparatus, modules, and systems.
The United States Government has rights in this invention pursuant to Contract No. DE-AC52-07NA27344 between the U.S. Department of Energy and Lawrence Livermore National Security, LLC, for the operation of Lawrence Livermore National Laboratory
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