Information
-
Patent Grant
-
6828895
-
Patent Number
6,828,895
-
Date Filed
Thursday, May 29, 200321 years ago
-
Date Issued
Tuesday, December 7, 200420 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Mickney; Marcus R.
- Goodman; Alfred N.
- Bicks; Mark S.
-
CPC
-
US Classifications
Field of Search
-
International Classifications
-
Abstract
A disconnector assembly is provided for an arrester. A non-conductive housing has first and second opposite ends separated by an internal chamber. A first electrical terminal is connected at the first end. A second electrical terminal is connected at the second end. A capacitor assembly engages and extends between the first and second terminals in the internal chamber. The capacitor assembly includes a capacitor and a resistor electrically connected in series. A sparkgap is electrically parallel the capacitor assembly between the first and second terminals. A cartridge with an explosive charge is positioned in the internal chamber, and the cartridge is electrically parallel to the capacitor assembly and electrically in series with the spark gap.
Description
FIELD OF THE INVENTION
The present invention relates to a disconnector assembly for an arrester. The arrester is isolated upon arrester failure. More particularly, the present invention relates to a pair of electrical terminals coupled by a capacitor assembly, a spark gap and an explosive cartridge. The capacitor assembly includes a capacitor and resistor connected electrically in series, and is electrically parallel to the spark gap.
BACKGROUND OF THE INVENTION
100021 Lighting or surge arresters are typically connected to power lines to carry electrical surge currents to ground, thereby preventing damage to lines and equipment connected to the arresters. Arresters offer high resistance to normal voltage across power lines, but offer very low resistance to surge currents produced by sudden high voltage conditions caused by, for example, lighting strikes, switching surge currents or temporary overvoltages. After the surge, the voltage drops and the arrester normally returns to a high resistance state. However, upon arrester malfunction or failure, the high resistance state is not resumed, and the arrester continues to provide an electrical path from the power line to ground. Ultimately, the line will fail due to a short circuit condition or breakdown of the distribution transformers, and the arrester will require replacement.
To avoid line lockout, disconnector assemblies are commonly used in conjunction with arresters to separate a malfunctioning arrester from the circuit and to provide a visual indication of arrester failure. Conventional disconnector assemblies have an explosive charge to destroy the circuit path and physically separate the electrical terminals. Examples of such disconnector assemblies are disclosed in U.S. Pat. No. 5,952,910 to Krause and U.S. Pat. Nos. 5,057,810 and 5,113,167 to Raudabaugh, as well as U.S. Pat. No. 5,434,550 to Putt, U.S. Pat. No. 4,471,402 to Cunningham and U.S. Pat. No. 4,609,902 to Lenk, the subject matter of each of which are hereby incorporated by reference.
Traditionally, polymer-housed distribution class arresters are assembled with a ground end insulating bracket that physically supports the arrester, as well as isolating the ground end of the arrester from the system ground in the event of arrester service failure. A ground lead connector, or isolator, connects the ground end of the isolator to the system neutral or ground wire.
In normal service conditions, the arrester grading current flows through the ground lead isolator. If the arrester fails, the arrester 60 Hz fault current flows through the failed arrester and through the ground lead disconnector, which causes the ground lead disconnector to operate. The disconnector disconnects from ground, thereby effectively isolating the failed arrester from ground. Separating the arrester from ground allows the utility to provide uninterrupted service to its customers. This also facilitates identifying the failed arrester so that it may be replaced with a new arrester.
Existing disconnectors typically have a grading component in parallel with a sparkgap. The grading component and sparkgap are located close to a detonating device, such as an unprimed cartridge. The grading component conducts the arrester grading current under normal service conditions. If arrester failure occurs, the arrester grading current increases from a few milliamperes to amperes or thousands of amperes, depending on the utility system grounding at the arrester location. This high current flow causes voltage to develop across the disconnector grading component. When voltage reaches a predetermined level, the parallel sparkgap sparks over, thereby causing heat build-up on the cartridge. The cartridge then detonates and separates the ground lead connection.
Typically, the grading component is a low voltage precision resistor, a high power resistor, or a semi-conductive polymer material. However, these grading components tend to fail during prolonged temporary overvoltage situations. Failure of the grading components can prevent disconnectors from properly detonating. A need exists for a disconnector providing a more reliable cartridge detonation.
Furthermore, existing grading components are often significantly damaged during durability testing, which results in deterioration of the electrical integrity of the disconnector. A deteriorated grading component may result in a degraded time-current deterioration characteristic. A need exists for a grading component that is not significantly deteriorated by durability testing.
A need exists for an improved disconnector assembly for an arrester.
SUMMARY OF THE INVENTION
Accordingly, it is a primary objective of the present invention to provide an improved disconnector assembly.
A further objective of the present invention is to provide a disconnector assembly for an arrester that provides a more reliable cartridge detonation.
A still further objective of the present invention is to provide a disconnector assembly for an arrester having a grading component that is not significantly deteriorated by durability testing.
The foregoing objects are basically attained by providing a disconnector assembly for an arrester. A non-conductive housing has first and second opposite ends separated by an internal chamber. A first electrical terminal is connected at the first end. A second electrical terminal is connected at the second end. A capacitor assembly engages and extends between the first and second terminals in the internal chamber. A sparkgap is electrically parallel to the capacitor assembly between the first and second terminals. A cartridge with an explosive charge is positioned in the internal chamber, the cartridge being electrically parallel to the capacitor and electrically in series with the spark gap.
In another embodiment, the foregoing objects are basically attained by providing a disconnector assembly for an arrester. A non-conductive housing has first and second opposite ends separated by an internal chamber. A first electrical terminal is connected at the first end. A second electrical terminal is connected at the second end. A capacitor assembly engages and extends between the first and second terminals in the internal chamber. The capacitor assembly includes a capacitor and a resistor electrically connected in series. A sparkgap is electrically parallel to the capacitor assembly between the first and second terminals. A cartridge with an explosive charge is positioned in the internal chamber, the cartridge being electrically parallel to the capacitor assembly and electrically in series with the sparkgap. The capacitance characteristic of the capacitor allows the capacitor to withstand prolonged temporary overvoltage conditions that cause linear resistors to fail, thereby providing a more reliable disconnector assembly.
Other objects, advantages and salient features of the invention will become apparent from the following detailed description, which, taken in conjunction with the annexed drawings, discloses preferred embodiments of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
Referring now to the drawings that form a part of the original disclosure:
FIG. 1
is a side elevational view in partial cross section of a disconnector assembly according to the present invention;
FIG. 2
is a bottom plan view in cross section taken along line
2
—
2
of
FIG. 1
of the present invention;
FIG. 3
is a schematic electrical diagram according to a first embodiment of the present invention showing the capacitor assembly connected electrically parallel the spark gap;
FIG. 4
is a schematic electrical diagram according to a second embodiment of the present invention showing the capacitor connected electrically parallel the spark gap;
FIG. 5
is an elevational view of the capacitor assembly taken in cross section along a plane through the longitudinal axis of the capacitor assembly of the present invention; and
FIG. 6
is a bottom plan view of the capacitor assembly of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
As shown in
FIGS. 1-5
, the present invention relates to a disconnector assembly
10
for an arrester
13
. A non-conductive housing
21
has first and second opposite ends
91
and
93
separated by an internal chamber
27
. A first electrical terminal
12
is connected at the first end
91
. A second electrical terminal
41
is connected at the second end
93
. A capacitor assembly
95
engages and extends between the first and second terminals
12
and
41
in the internal chamber
27
. The capacitor assembly includes a capacitor
31
and a resistor
81
electrically connected in series. A cartridge
51
with an explosive charge is positioned in the internal chamber
27
. The cartridge is electrically parallel to the capacitor
31
. A spring spacer
53
receives the cartridge
51
. The spring spacer
53
is adjacent the first terminal
12
and spaced from the second terminal
41
.
Referring initially to
FIGS. 1 and 2
, a disconnector assembly
11
, according to the present invention, comprises a first, upper electrical terminal
12
electrically connected to arrester
13
, and a second, lower electrical terminal, or stud,
41
electrically connected to ground
17
. Arrester
13
is electrically connected to power line
15
, which is representative of a power system. Terminals
12
and
41
are mechanically and electrically coupled to each other.
Arrester
13
is conventional, and thus, is not described in detail. The arrester may be formed according to U.S. Pat. No. 4,656,555 to Raudabaugh, the subject matter of which is hereby incorporated by reference.
Terminals
12
and
41
are mechanically connected to one another by a bracket
21
. Bracket
21
may be formed of any suitably strong insulating material, such as a non-conductive plastic. Preferably, the bracket is made of a glass filled polyester material. As noted above, the bracket
21
has a base
23
and a wall
25
extending substantially perpendicularly from base
23
, with wall
25
defining an internal cavity
27
extending between surface
22
of base
23
and surface
28
of wall
25
. The upper end of cavity
27
is connected to bracket surface
26
by cylindrical upper bore
30
. The lower end of cavity
27
is connected to surface
28
of wall
25
by a stepped lower chamber
32
. The transverse diameter of lower chamber
32
is greater than the transverse diameter of internal cavity
27
.
Between cavity
27
and lower chamber
32
, the bracket has a radially extending lower annular shoulder
34
. An upper shoulder
36
extends radially at the interface of cavity
27
and upper bore
30
.
Upper electrical terminal
12
is of conventional construction, and has a head portion
38
located within cavity
27
and abutting upper shoulder
36
. An externally threaded shank portion
40
of terminal
12
extends from the head portion through upper bore
30
, such that the shank portion is at least partially exposed exteriorly of bracket
21
for coupling to arrester
13
. In this manner, head portion surface
42
engages upper shoulder
36
, while head portion surface
44
is exposed in cavity
27
.
An isolator assembly
11
is disposed in cavity
27
. The isolator assembly may include a capacitor
31
, a cartridge
51
, and a spring spacer
53
. The spring spacer
53
abuts surface
44
of terminal head portion
38
. Spring spacer
53
provides a biasing force to maintain electrical or physical contact of the isolator assembly components within cavity
27
, and facilitates electrically connecting upper terminal
12
to lower terminal (stud)
41
. Tab
55
extends downwardly from the spring spacer
53
into the cavity
27
and receives cartridge
51
.
Capacitor
31
is mounted in cavity
27
and extends between the spring spacer
53
and upper surface
47
of cap
46
, thereby providing an electrical connection between the upper and lower terminals
12
and
41
through conductive cap
46
.
FIG. 4
shows an electrical diagram of the isolator assembly
11
having a capacitor
31
between the arrester
13
and ground
17
. Preferably, the capacitor is formed of a high voltage material, such as ceramic. Preferably, the capacitor
31
is encased in an insulative sleeve or ceramic collar
71
to protect the capacitor from carbon contamination during a gap sparkover that causes the cartridge
51
to discharge.
The capacitance of the high-voltage capacitor
31
eliminates failure during periods of prolonged overvoltage conditions, which was a problem with the resistors. Failure of the resistors prevents proper detonation of the cartridge after an arrester has been exposed to a prolonged temporary overvoltage condition. Since the high-voltage capacitor
31
does not fail during the arrester overvoltage event it provides a more reliable cartridge detonation, thereby eliminating the nuisance associated with system lockouts experienced by utilities and their customers. The high-voltage capacitor
31
provides improved temporary overvoltage capabilities for the arrester during system overvoltage conditions than was available with resistors used alone in isolators, thereby eliminating capacitor failure and non-detonation of the cartridge. Thus, the high-voltage capacitor
31
improves temporary overvoltage capability for the arrester
13
under system overvoltage conditions.
The electrical and mechanical integrity of the high-voltage capacitor
31
, in conjunction with the good dielectric integrity of the ceramic collar or insulative sleeve
71
, prevents significant deterioration when the serially connected arrester is exposed to durability testing. Durability testing, such as
100
kA lightning impulse duty, does not significantly deteriorate the electrical integrity of the isolator assembly
11
having a high-voltage capacitor
31
. Isolators using a resistor alone may be significantly damaged by this type of duty, resulting in deterioration of the electrical integrity of the disconnector assembly. Such damage includes a degraded time-current detonation characteristic, which results in an unreliable cartridge detonation.
The isolator assembly
11
having the high-voltage capacitor
31
detonates at a lower current level, typically around a few hundred milliamperes, than existing isolator assemblies using resistors, since the high-voltage capacitor has a high impedance. The high impedance allows sparkover of the sparkgap when the arrester
13
has only partially failed or fails in a high-impedance grounded or delta system configuration, thereby providing a more reliable cartridge
51
detonation and a more reliable isolator assembly
11
.
In another preferred embodiment, a capacitor assembly has a capacitor
31
connected electrically in series with a resistor
81
, as shown in
FIGS. 3 and 5
, to provide the electrical path between the arrester
13
and the ground
17
. The resistor
81
improves the capability of the capacitor to withstand high frequency oscillations associated with the gap sparkover
75
, thereby minimizing the probability of damaging the capacitor. Preferably, both the capacitor
31
and resistor
81
are housed in an insulative sleeve
71
to protect the capacitor from carbon contamination during a gap sparkover occurring during arrester operations, as shown in FIG.
5
. The capacitor assembly
95
has the capacitor
31
housed between the resistor
81
and a terminal
97
. The resistor
81
has a conductive surface
82
and the terminal
97
has a conductive surface
98
(
FIG. 6
) to provide an electrical connection from the upper terminal
12
through the capacitor assembly
95
to the lower terminal
41
. The insulating sleeve
71
may have an RTV type material oriented in the interface between the sleeve and the resistor
81
, capacitor
31
and terminal
97
to enhance the dielectric integrity of the interface.
Cartridge
51
with an explosive charge is mounted in cavity
27
adjacent capacitor
31
. Cartridge
51
is elongated along a cartridge axis that is substantially perpendicular to the longitudinal axis of terminals
12
and
41
and of bracket cavity
27
. Cartridge
51
receives the spring spacer tab
55
between its head
61
and body
62
, as shown in
FIG. 1
, to secure the cartridge in cavity
27
proximal the spring spacer
53
.
Second terminal, or lower terminal,
41
is a conventional stud. The second terminal
41
has a head portion, or cap,
46
and a threaded shank portion
64
. Head portion
46
has an upper surface
47
facing into cavity
27
and abutting the housing lower shoulder
34
. Terminal
41
is maintained in position in housing
21
by engagement of its head portion
46
with housing lower shoulder
34
and by a suitable adhesive
56
, such as an epoxy.
An adhesive
56
between the shoulder
48
of head portion
46
and the wall
25
secures the second terminal within the housing
22
. Any suitable adhesive may be used, but preferably the adhesive is a thick epoxy that has a fast curing time in air to avoid contaminating the disconnector assembly during the manufacturing process.
A gasket
57
is positioned between the upper surface of the shoulder
48
of the head portion
47
and the lower shoulder
34
of the cavity
27
. The gasket further ensures adhesive
56
docs not enter cavity
27
, thereby possibly damaging any of the components of the disconnector assembly.
As illustrated in
FIG. 1
, a spark gap
75
, shown schematically in
FIGS. 3 and 4
, is provided between the head
61
of the cartridge
61
and the upper surface
27
of the lower terminal
41
. The spark gap
75
is connected electrically in parallel to the capacitor
31
between the first and second terminals
12
and
41
, as shown in FIG.
4
. In another embodiment shown in
FIG. 3
, the spark gap
75
is connected electrically in parallel to the capacitor assembly
95
. The cartridge
51
is connected electrically in series with the spark gap
75
, as shown in
FIGS. 3 and 4
, so that when the gap sparks over during arrester failure the cartridge detonates, thereby isolating the arrester
13
from ground
17
.
Assembly and Disassembly
A fully assembled disconnector assembly
11
is shown in
FIGS. 1 and 2
. Upper electrical terminal
12
is inserted through bore
30
to connect bracket
21
to an arrester
13
. The isolator assembly
11
is then simply dropped into cavity
27
over terminal
12
. Cavity
27
is then sealed by securing gasket
57
and lower terminal stud
41
to wall
25
of bracket
21
with adhesive
56
. Disconnector assembly
11
is then completed by allowing the adhesive
56
to cure, thereby sealing the isolator assembly
11
in cavity
27
.
During normal non-fault operation of the arrester
13
, little or no current passes through isolator assembly
11
due to the high resistance of the arrester. When subjected to lighting or surge currents, the arrester discharges high pulse currents which travel through arrester
13
and isolator assembly
11
. Within the isolator assembly, the current will arc over between the spring spacer
55
of the cartridge
51
and upper surface
47
of the lower terminal
41
and to ground
17
.
When the arrester is properly functioning, the gaps spark over for high current, short duration pulses which last less than 100 milliseconds for lightening and less than several milliseconds for switching currents. For such short sparkovers, insufficient energy is generated to activate or denote the cartridge. However, if the lightening arrester fails to withstand the voltages, the arcs are generated over a sufficiently extended period to activate the unprimed cartridge, causing an explosion that separates the terminals
12
and
41
mechanically from one another. The force of the exploded charge forces at least one of the terminals, usually lower terminal
41
, from the housing
21
. This action electrically disconnects arrester
13
from the system, and provides a visual indication of the need for arrester replacement.
While advantageous embodiments have been chosen to illustrate the invention, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the scope of the invention as defined in the appended claims.
Claims
- 1. A disconnector assembly for an arrester, comprising:a non-conductive housing having first and second opposite ends separated by an internal chamber; a first electrical terminal connected at said first end; a second electrical terminal connected at said second end; a capacitor assembly engaging and extending between said first and second terminals in said internal chamber, said capacitor assembly including a capacitor and a resistor connected electrically in series; a sparkgap connected electrically in parallel to said capacitor; and a cartridge with an explosive charge positioned in said internal chamber, said cartridge being electrically parallel to said capacitor and electrically in series to said sparkgap.
- 2. A disconnector assembly for an arrester according to claim 1, whereina spring spacer is disposed between said capacitor assembly and said first electrical terminal.
- 3. A disconnector assembly for an arrester according to claim 2, whereina tab extends from said spring spacer for receiving said cartridge.
- 4. A disconnector assembly for an arrester according to claim 1, whereinsaid sparkgap is formed between a head of said cartridge and said second electrical terminal.
- 5. A disconnector assembly for an arrester according to claim 1, whereinsaid capacitor is a high voltage capacitor.
- 6. A disconnector assembly for an arrester according to claim 1, whereinsaid capacitor is made of ceramic.
- 7. A disconnector assembly for an arrester according to claim 1, whereinan adhesive secures said second electrical terminal to said housing.
- 8. A disconnector assembly for an arrester according to claim 7, whereina gasket is positioned between said second terminal and said housing to prevent said adhesive from entering said internal chamber.
- 9. A disconnector assembly for an arrester according to claim 8, whereinan inner surface of said housing is stepped for receiving said gasket.
- 10. A disconnector assembly for an arrester according to claim 1, whereinsaid housing is made of a non-conductive plastic.
- 11. A disconnector assembly for an arrester according to claim 1, whereinsaid capacitor assembly includes a sleeve to receive said capacitor and said resistor.
- 12. A disconnector assembly for an arrester, comprising:a non-conductive housing having first and second opposite ends separated by an internal chamber; a first electrical terminal connected at said first end; a second electrical terminal connected at said second end; a capacitor assembly engaging and extending between said first and second terminals in said internal chamber, said capacitor assembly including a capacitor and resistor electrically connected in series; and a cartridge with an explosive charge positioned in said internal chamber, said cartridge being electrically parallel to said capacitor assembly.
- 13. A disconnector assembly for an arrester according to claim 12, whereinsaid capacitor is a high voltage capacitor.
- 14. A disconnector assembly for an arrester according to claim 12, whereinsaid capacitor is made of ceramic.
- 15. A disconnector assembly for an arrester according to claim 12, whereina spring spacer has a tab for receiving said cartridge, said spring spacer being adjacent said first terminal and spaced from said second terminal.
- 16. A disconnector assembly for an arrester according to claim 12, whereinan adhesive connects said second terminal to said housing.
- 17. A disconnector assembly for an arrester according to claim 16, whereina gasket is positioned between said second terminal and said housing to prevent said adhesive from entering said internal chamber.
- 18. A disconnector assembly for an arrester according to claim 17, whereinan inner surface of said housing is stepped for receiving said gasket.
- 19. A disconnector assembly for an arrester according to claim 12, whereinsaid housing is made of a non-conductive plastic.
- 20. A disconnector assembly for an arrester according to claim 12, whereinsaid capacitor assembly includes a sleeve to receive said capacitor and resistor.
- 21. An arrester assembly, comprising:an arrester; a non-conductive housing having first and second opposite ends separated by an internal chamber; a first electrical terminal connected at said first end; a spring spacer disposed adjacent and engaging said first electrical terminal and having a tab extending downwardly therefrom; a second electrical terminal connected at said second end of said housing to ground; a capacitor assembly engaging and extending between said spring spacer and said second terminal in said internal chamber, said capacitor assembly including a sleeve, a high voltage capacitor disposed in said sleeve, and a resistor disposed in said sleeve and connected electrically in series to said capacitor; a sparkgap connected electrically parallel to said capacitor assembly; and a cartridge with an explosive charge positioned in said internal chamber and received by said tab, said cartridge being electrically parallel to said capacitor assembly and electrically in series to said sparkgap.
- 22. An arrester assembly according to claim 21, wherein said capacitor is made of ceramic.
- 23. A disconnector assembly for an arrester according to claim 21, whereinan adhesive connects said second terminal to said housing.
- 24. A disconnector assembly for an arrester according to claim 23, whereina gasket is positioned between said second terminal and said housing to prevent said adhesive from entering said internal chamber.
- 25. A disconnector assembly for an arrester according to claim 24, whereinan inner surface of said housing is stepped for receiving said gasket.
- 26. A disconnector assembly for an arrester according to claim 21, wherein said housing is made of a non-conductive plastic.
US Referenced Citations (20)
Foreign Referenced Citations (2)
Number |
Date |
Country |
19884 |
Dec 1980 |
EP |
63294218 |
Nov 1988 |
JP |