This invention relates to dielectric liquids for use in high voltage transformers, oil-insulated cables, and other oil-insulated high voltage devices.
The majority of high voltage components, such as paper insulated oil impregnated cables and high voltage power transformers in use today rely on mineral oil, also called transformer oil, as a vital piece of their electrical insulation system [I, 2]. The numbers in brackets refer to the references appended hereto. The contents of all of these references are incorporated by reference herein. The widespread use of transformer oils for high voltage insulation and power apparatus cooling is due to their greater electrical breakdown strength and thermal conductivity than gaseous insulators, while their ability to conform to complex geometries and self-heal means that they are often of more practical use than solid insulators. As such, the electrical insulation strength and characteristics of transformer oil has become the de facto standard for high voltage liquid insulation.
Due to the major implications which an insulation failure in electric power apparatus can have, scientists and engineers have for many years studied the insulating properties of dielectric liquids, particularly transformer oils, with a view to understanding the mechanisms behind electrical breakdown in an effort to reduce their likelihood [1]. Much of their work has focused on the formation of electrical streamers.
These are low density conductive structures that form in regions of oil that are over-stressed by electric fields on the order of 1×108 V/m or greater [10]. Once a streamer forms it tends to elongate, growing from the point of initiation towards a grounding point. The extent of a streamer's development and velocity depends upon the nature of the electrical excitation (i.e., magnitude, duration, rise time, etc.) which caused it. Sustained over-excitation can result in a streamer short circuiting the oil gap between electrodes. When this happens an arc will form and electrical breakdown will occur.
The important role which streamers play in the electrical breakdown of dielectric liquids has meant that they have been the subject of significant scientific investigation. Much of the research on streamers in dielectric liquids has been empirical in nature and has led to the formation of a large literature on the subject of which the references [1, 7-19] are representative.
Within the past decade there has been considerable interest in finding a green, environmentally friendly replacement for transformer oil. In particular, much of the work has focused on vegetable-based oils composed of natural or synthetic esters [3-6] that are biodegradable. Unfortunately, ester liquids have been shown to have electrical insulation characteristics that greatly differ from transformer oil at extremely high voltages [4-6]. While ester liquids have similar breakdown voltage Vb (50% probability) as transformer oil, their breakdown time delay (i.e., the time between voltage application and breakdown) at slightly higher applied voltages in lightning impulse tests are extremely short or conversely the average streamer propagation velocity is very high (>>10 km/s) [4-6]. This differs from transformer oil where above its breakdown voltage Vb the average streamer velocity is low (i.e., 1-5 km/s) over a wide voltage range [6-9]. For example, it has been experimentally recorded in the literature that streamers in transformer oil travel 1-5 km/s for an applied voltage Vapp that ranges between Vb<Vapp<2Vb [7, 9]. Above a certain voltage, called the acceleration voltage Va, the streamer in transformer oil accelerates and travels at average velocities greater than 10 km/s [7].
For ester liquids to be considered as a viable replacement to transformer oils, their electrical insulating strength at high voltages must be improved. Specifically, their transition to fast streamer velocities (>10 km/s) must be pushed to higher voltages such that the time to breakdown is increased, which is significant because a slower streamer requires more time to traverse the liquid gap between electrodes to cause breakdown. This allows more time for the applied impulse voltage to be extinguished.
The work by Lesaint and Jung [32] with cyclohexane with a pyrene additive has shown that the addition of low ionization potential additives to these materials will create a space charge shielding effect whereby the additives will ionize and create a slow 2nd mode streamer at a lower inception voltage. The creation of these streamers and their associated space charge shield the higher applied lightning impulse voltage levels and regulate the electric field enhancement at the streamer tip. Therefore, a greater applied voltage is needed to generate fast traveling streamers such as 3rd and 4th mode streamers such that the acceleration voltage occurs at high voltages in these non-ester liquids.
The insulating liquid, or dielectric composition, according to the invention includes an ester liquid or water, and an additive to the ester liquid having a lower ionization potential than the ionization potential of the ester liquid. The ester liquid can further include vegetable oil, animal oil, mineral oil, and synthetic oil. In a preferred embodiment, the ester liquid is rapeseed oil, and a suitable additive is pinoresinol. Other suitable esters are sunflower, soybean, corn, cottonseed and sesame oils. Other suitable additives for use with the ester liquids are low ionization potential phenolic compounds such as 1-acetoxypinoresinol.
In another aspect, the insulating liquid, or dielectric composition, includes the further addition of conducting nanoparticles to offset the lower breakdown voltage caused by the addition of the low ionization potential additive.
In another aspect, the invention can be an electrical device that includes a housing, at least two electrodes, and a dielectric fluid contained within the housing, wherein the dielectric fluid includes an ester liquid and an additive having a lower ionization potential than the ionization potential of the ester liquid. In another aspect, the insulating liquid, or dielectric composition, includes the further addition of conducting nanoparticles to offset the lower breakdown voltage caused by the addition of the low ionization potential additive.
In another aspect, the invention can be a method of preparing a dielectric fluid. The steps of the method include combining an additive with a solution of an ester liquid, wherein the additive has an ionization potential lower than the ionization potential of the ester liquid.
This invention has many advantages. For example, the invention can increase the acceleration voltage of a dielectric fluid. As another example, the invention can increase both the acceleration voltage and the breakdown voltage of a dielectric fluid. Increasing the acceleration and breakdown voltage of a dielectric fluid can reduce the formation of electrical streamers in a dielectric fluid by increasing the inception voltage at which electrical streamers form. In particular, the invention can reduce the formation of fast electrical streamers. The inception voltage for fast streamers of vegetable-based oils composed of natural or synthetic esters can be increased by adding low ionization potential additives in small concentrations that inhibit fast streamers by space charge shielding at the high voltage electrode. Therefore, the invention can provide a more environmentally friendly insulating material for use in an electrical power apparatus than transformer oil while at the same time reducing the likelihood of electrical failure or other catastrophic event.
The foregoing will be apparent from the following more particular description of example embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating embodiments of the present invention.
a is a graph of stopping length versus applied voltage in rapeseed oil comprising natural esters as described in References 4, 5, and 34.
b is a graph of average velocity versus applied voltage in rapeseed oil as described in References 4, 5, and 34.
c is a graph of streamer charge versus applied voltage in rapeseed oil as described in References 4, 5, and 34.
A description of example embodiments of the invention follows.
While this invention has been particularly shown and described with references to example embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention encompassed by the appended claims.
Ester liquids, whether natural or synthetic, have pre-breakdown characteristics that are extremely different from transformer oil. This should not come as a surprise as esters have very different chemical compositions than transformer oil.
As in transformer oil, the onset of the streamer modes in ester liquids is dependent on the magnitude of the voltage excitation. Once again, the 2nd mode initiates at the breakdown voltage Vb which denotes 50% probability of breakdown, while the 3rd mode initiates at the acceleration voltage Va where the streamer propagation velocity rises dramatically [7]. The 2nd, 3rd, and 4th modes have velocities on the order of 1 km/s, 10 km/s, and 100 km/s, like in transformer oil [4-6]. Furthermore, the breakdown voltage Vb of ester liquids and transformer oil, where 2nd mode streamers initiate, has been shown to be very close in magnitude for the same experimental setup [4-6].
The key difference between ester liquids and transformer oil is the acceleration voltage Va level where streamers transition to very fast 3rd and 4th mode streamers. For transformer oil the acceleration voltage is much higher than the breakdown voltage. Therefore, in transformer oil the applied voltage range, where the slower 2nd mode streamers dominate, is large and the voltage at which the dangerous 3rd and 4th mode streamers propagate is pushed to exceedingly high voltages. This ensures a lower probability for propagation of fast streamers that quickly traverse the oil gap to the counter electrode causing electrical breakdown before the applied voltage impulse can be extinguished.
For ester liquids, the acceleration voltage Va occurs almost directly above the breakdown voltage as shown by the two different experimental results from Duy et al. [4, 5, 34] and ABB [6] in FIGS. 1 and 2. Therefore, when the breakdown voltage is reached the streamers easily transition to streamers that propagate at average velocities greater than 10 km/s since Vb˜Va for ester liquids and are not well-suited to insulate high-voltage systems.
According to the invention, the acceleration voltage of a pure ester liquid such as rapeseed oil is increased by adding a secondary molecule in low concentrations. The secondary molecule has an ionization potential that is lower than the main family of molecules comprising the ester liquid.
Many ester liquids are largely composed of oleic acid which has an ionization potential of 8.6 eV. Thus, additives such as pinoresinol with an ionization potential of 6.6 eV and other low ionization potential phenolic compounds such as 1-acetoxypinoresinol with an ionization potential of 6.8 eV are suitable additives according to some embodiments of the invention.
While the acceleration voltage Va of esters is increased by adding the lower ionization potential additive according to this aspect of the invention, the breakdown voltage Vb is decreased. This lower breakdown strength of an insulating dielectric liquid due to the addition of a low ionization potential additive can be offset by the further addition of conducting nanoparticles of typical diameter around 10 nm, that raises the breakdown strength of a dielectric liquid and decreases positive streamer velocity [37,38]. This breakdown strength increase is due to the conversion of fast electrons produced by ionization of the dielectric liquids to slow negatively charged nanoparticle charge carriers with effective mobility reduction by a factor of about 105 [38]. This also raises the acceleration voltage. Therefore, the use of conducting nanoparticles together with a low ionization potential additive can result in both an increased breakdown voltage for slow 2nd mode streamers and an increased acceleration voltage for fast 3rd and 4th mode streamers.
A mixture of rapeseed oil and pinoresinol can be prepared by adding pinoresinol to rapeseed oil. The concentration of the pinoresinol additive can be about five percent by volume of the rapeseed oil. The breakdown voltage of the mixture is slightly decreased while the acceleration voltage is increased as compared to pure rapeseed oil. An acceptable range of concentration for the additive is about 3% to about 10% by volume. Other suitable esters are sunflower oil, soybean oil, corn oil, cottonseed oil and sesame oil, and other suitable additives are low ionization potential phenolic compounds such as 1-acetoxypinoresinol.
A mixture of rapeseed oil and pinoresinol can be prepared by adding pinoresinol to rapeseed oil. The concentration of the pinoresinol additive can be about five percent by volume of the rapeseed oil. Magnetite nanoparticles having a dielectric relaxation time of about 10−14 seconds and sized about 10 nm in diameter can be added to the mixture of rapeseed oil and pinoresinol at a concentration about 1020 nanoparticles/m3. The breakdown voltage and acceleration voltage of the mixture is increased as compared to pure rapeseed oil. An acceptable range of concentration for the pinoresinol additive is about 3% to about 10% by volume. Other suitable esters are sunflower oil, soybean oil, corn oil, cottonseed oil and sesame oil, and other suitable additives are low ionization potential phenolic compounds such as 1-acetoxypinoresinol. Other suitable nanoparticles can be any material with dielectric relaxation time less than about 50 microseconds, such as any iron oxide, zinc oxide, aluminum, copper, steel, titanium, or any metal or conducting material whose dielectric relaxation time is shorter than about 50 microseconds.
It is recognized that modifications and variations of the invention will be apparent to those of ordinary skill in the art and it is intended that all such modifications and variations be included within the scope of the appended claims.
This application claims the benefit of U.S. Provisional Application No. 61/316,524, filed on Mar. 23, 2010. The entire teachings of the above application are incorporated herein by reference.
Number | Date | Country | |
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61316524 | Mar 2010 | US |