BACKGROUND OF THE INVENTION
Field of the Invention
[0001] The present invention relates to a disc shaped, zinc oxide-based varistor for high
voltage or high current applications, and more particularly relates to improvements
in the physical stability thereof.
Description of the Prior Art
[0002] A zinc-oxide-based varistor, as typically manufactured, comprises a sintered disc
of zinc oxide and additives, the disc having a pair of electrodes on opposite faces.
It is also typical for the electrode on the face to only extend part way to the rim
of the disc, in order to avoid arcing, also called fringing current or flash over.
See, for example, U.S. Patent Numbers 4,460,497 to Tapan K. Gupta et al., 4,451,815
to Eugene Sakshaug et Ano., and 4,450,426. In addition, the rim is usually protected
from the elements or some aspect of the manufacturing process by an electric insulator.
See, for example, U.S. Patent Numbers 4,371,860 to John E. May et Ano., and 3,138,686
to Steven P. Mitoff et Ano.
[0003] The zinc oxide varistor exhibits a non-linear current-voltage relationship, thought
to be in the form I= C X V
a, where "a" is greater than 1. In other words, it acts as an insulator for low voltages,
and as a conductor for high voltages. It thereby provides overvoltage protection or
acts as a voltage stabilizer, surge absorber or arrester, and may be subjected to
current surges.
[0004] Because of Joule heating, the interior of the disc may reach a high temperature while
the rim remains close to ambient temperature. The situation is exacerbated by the
anti-arcing design in which the margin of the face is left bare. The electric field
drops suddenly near the rim, as does the temperature, resulting in a thermal shock
condition. This may result in physical cracking on the rim, and substantial damage
to the device.
[0005] The following patents are hereby referenced as being typical of known prior art in
so far as they disclose means for discouraging arcing and thereby minimize this problem
and in which it appears that the electrode extends at least as far as the rim:
[0006] In Shogi, Goedde and 3,905,006, the process for manufacturing and attaching the insulator
is complicated and may involve temperatures over 500 degrees C, which may damage the
varistor.
[0007] It is an object of this invention to provide an improved zinc oxide varistor disc
which has more uniform Joule heating without causing arcing between the face electrodes,
and which is thus less likely to crack on the rim and thus would provide more stability
than prior art zinc varistor discs.
[0008] It is a further object of this invention to provide a system based on infrared thermal
measurements to predict the energy handling capacity of a particular varistor disc.
DETAILED DESCRIPTION OF THE DRAWINGS
[0009] Figure 1 is a cross sectional view of a prior art zinc oxide varistor.
[0010] Figure 2 is a perspective view of the prior art zinc oxide varistor shown in Figure
1.
[0011] Figure 3 is a cross section view of a zinc oxide varistor in accordance with the
present invention.
[0012] Figure 4 is a perspective view of the zinc oxide varistor illustrated in Figure 3.
[0013] Figure 5 is a cross sectional view of the zinc oxide varistor comprising a second
embodiment of the invention.
[0014] Figure 6 is a drawing illustrating the contours of equal temperature of a typical
varistor.
[0015] Figure 7 is a block diagram illustrating the process for predicting the thermal stability
of a varistor disc.
DETAILED DESCRIPTION OF THE INVENTION
[0016] Referring now to the drawings, Figures 1 and 2 illustrate the prior art zinc oxide
varistor, generally indicated at 10. This varistor comprises a disc of sintered zinc-oxide
and additives, the disc having a bulk interior 25 and a cylindrical surface 30 extending
between the opposite faces 40 and 41. A pair of electrodes 50 and 51 are affixed to
the opposite faces 40 and 41, but extend only part-way to the cylindrical surface
30 in order to avoid arcing. The margin 60 is that part of the face 40 or 41 not covered
by the electrodes. The cylindrical surface 30 is generally covered with an insulator
(not shown), usually a thin glass coating, to protect it from the elements or some
aspect of the manufacturing process.
[0017] When the prior art varistor 10 is exposed to high current for a short period of time,
the interior 25 of the disc will have a generally uniform electric field. The margin
region 60 is narrow and will be subject to a severe electric field gradient.
[0018] Because of Joule heating the interior 25 may briefly reach a temperature as high
as 160 degrees C. above the ambient temperature. The regions of the disc near the
cylindrical surface 30 will remain near ambient temperature since any heat would be
rapidly dissipated to the environment. Additionally, this region has a significantly
lower current flow. Due to the current gradient and the dissipation characteristics
of the disc severe thermal gradients may develop across the disc. These thermal gradients
may produce a thermal shock condition, which may result in physical cracking of the
disc.
[0019] Figures 3 and 4 illustrate a zinc oxide varistor of known composition according to
the present invention, generally indicated at 100. The varistor comprises a disc-shaped
body 155 of sintered zinc-oxide and additives, the disc having a cylindrical outer
surface 130 and opposite faces 140 and 141. A pair of electrodes 150 and 151 are affixed
opposite faces 140 and 141 and extend up to the edge of the outer cylindrical surface
130. A collar 160 with high dielectric and high temperature insulating properties
is then positioned around the outer cylindrical surface 130. In the preferred embodiment,
the collar 160 is a high temperature polymer.
[0020] The collar 160 may be made of polyetherimide (ULTEM) which has a high dielectric
strength of 33 KV/mm in air @ 1.6 mm. Polyetherimide is a high temperature polymer
which can be used in applications where the temperature goes above 210⁰ C, well within
the range of expected use. Metal coatings 170 and 171 extend across the bottom and
top electrodes 150 and 151 and the junction between the polyetherimide collar 160
and the body 155 and may be formed by one of a variety of techniques, such as vacuum
metallization, flame/arc spraying. This metal coating effectively forms an extension
to the electrodes (150, 151) and produces a more uniform electric field gradient across
the disc body 155. In other embodiments, the collar 160 is made of porcelain enamel,
thermal plastic or a suitable polymer.
[0021] Polyetherimide has a higher coefficient of expansion than zinc oxide, so if a polyetherimide
collar is used, it will fit snugly on the disc 100 upon cooling down, and it will
be in a state of tension while slightly compressing the disc 100.
[0022] Figure 5 illustrates another embodiment 101 of the invention, differing from the
embodiment discussed above in that the electrodes 140 and 141 are not extended outwardly
beyond the cylindrical surface 130.
[0023] When the varistor 100 according to the present invention is exposed to high current
or voltage, the interior of the disc will have a generally uniform electric field
tending to equalize the current distribution. This is a result of the electrodes extending
entirely across the faces of the disc. Problems due to high electric fields in the
regions near the outer cylindrical surface are reduced by the high dielectric properties
of the collar. This results in more uniform heating of the varistor disc for a given
current and dissipation while reducing arcing problems associated with prior electrodes
when they extended to or beyond the cylindrical surface.
[0024] Accordingly, Joule heating is more uniformly distributed throughout the disc, resulting
in a lower thermal gradient across the disc. Reducing the thermal gradient reduces
susceptibility to physical cracking caused by a thermal shock condition, common in
prior art varistors.
[0025] The present invention further provides a method for determining the energy handling
capacity of a particular disc, that is the disc's resistance to cracking, prior to
assembly of the varistor. This permits discs having low or unacceptable dissipations
to be discarded to improve the quality of finished varistors.
[0026] It is known from both experiment and analysis that those varistor discs which are
most resistant to cracking exhibit axisymmetric Joule heating when a voltage is applied
across their faces. Conversely, those varistors which are least resistant to cracking
exhibit non-symmetric temperature distributions upon Joule heating, which distributions
result in thermal stress which can crack the discs. It is also known that temperature
contours on zinc oxide disc varistors subjected to high energy pulses are similar
to those seen after relatively low energy inputs over a longer period of time.
[0027] Figure 6 is a drawing illustrating typical curves corresponding to constant temperature
patterns, thermometry across the face of a typical varistor disc. In this illustration
only three curves, labeled "A", "B" and "C" are illustrated. However, in most applications
more profiles may be used. These profiles are used to predict the stability of the
finished varistor, as described below.
[0028] Figure 7 is a block diagram illustrating the process used to evaluate the thermal
characteristics of a particular varistor disc. Each of the newly manufactured zinc
oxide varistor discs 195 is subjected to a low energy pulse. For example, rapid application
of 27 kJ energy will increase the average temperature of the varistor by about 60
degrees C. The thermograph is produced using an infrared camera recorder and converted
to digital form. This data is analyzed by a digital computer to determine the thermal
stress of the varistor disc.
[0029] More specifically, the thermal stress analysis involves calculating the thermal stress
at various locations on the varistor disc, and especially on and near the outer cylindrical
surface, as this is the region of expected maximum stress. All calculations in this
thermal stress calculation step are performed directly from the thermal data, previously
described. That is they are performed in closed form, and thus need very little computer
memory, and numerical results are obtained rapidly. Once the thermal stresses near
the outer cylindrical surface have been calculated, the energy handling capability
step compares this data with known physical properties of the material, and determines
the maximum energy handling capability of the particular disc. Any disc having a thermal
capability lower than the desired value are discarded. This permits varistors of a
given capability to be manufactured with a lower disc volume.
1. A varistor having reduced thermal stress, comprising in combination:
a. a body comprising sintered zinc oxide in combination with other additives, said
body including a cylindrical outer surface and first and second substantially parallel
opposed surfaces;
b. first and second electrodes respectively affixed to said first and second opposed
surfaces, said electrodes extending outwardly to at least the edge of said first and
second opposed surfaces; and
c. an insulating member contacting said outer surface and extending between said electrodes.
2. A varistor having reduced thermal stress, in accordance with Claim 1 wherein said
first and second electrodes extend beyond said cylindrical surface of said disc.
3. A varistor having reduced thermal stress, in accordance with Claim 2, wherein the
said insulating member comprises a collar affixed to said outer cylindrical surface
and to portions of said electrodes which extend beyond said outer cylindrical surface.
4. A method for forming an improved varistor, including the steps of:
a. sintering zinc oxide and other additives to form a varistor disc;
b. subjecting said disc to predetermined pulses of electrical energy;
c. plotting the thermal distribution of energy in said disc;
d. calculating the thermal stress in said disc based on said thermal distribution;
e. selecting a varistor disc meeting predetermined stress conditions as a result of
said energy dissipation characteristics; and
f. affixing electrodes to opposed surfaces of a varistor disc meeting predetermined
dissipation characteristics.
5. The method for forming an improved varistor, in accordance with claim 4 further including
the step of selecting the dimensions of said varistors such that the diameter of said
electrodes is at least equal to the diameter of said disc.
6. The methods for forming a varistor in accordance with Claim 5 wherein said electrodes
are selected to have a diameter greater than the diameter of said disc.
7. The method for forming a varistor in accordance with Claim 6 further including the
step of affixing a collar to the outer diameter of said disc, said collar extending
between portions of said electrodes which extend beyond the edge of said disc.