Information
-
Patent Grant
-
6483679
-
Patent Number
6,483,679
-
Date Filed
Monday, June 18, 200122 years ago
-
Date Issued
Tuesday, November 19, 200221 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Mehrman; Michael J.
- Gardner Groff & Mehrman, P.C.
-
CPC
-
US Classifications
Field of Search
US
- 361 7
- 361 15
- 361 14
- 361 54
- 361 140
- 361 152
- 361 154
- 361 153
- 361 143
- 361 144
- 361 148
- 200 4308
- 200 48 R
- 200 48 P
-
International Classifications
-
Abstract
An interrupter switch mechanism 18, an actuator mechanism 20 for operating the switch mechanism 18, an engagement arm 30 such as a whip, a first resistor 22, a second resistor 26, a drive mechanism 64 for pivoting the engagement arm 30 into contact with the resistors 22 and 26, and a drive shaft 62. The drive mechanism 64 has a first hub 82, a second hub 84 that is biased relative to the first hub 82, and a pivotal latch member 66 that is biased towards an engaged position with the second hub 94. The drive shaft 62 sequentially operates the drive mechanism 64 to introduce the first resistor 22 and then the second resistor 26, and then operates the actuator 20 to close the switch mechanism 18, for reducing electrical disturbances when switching a capacitor bank 12 into an electric power circuit 16.
Description
TECHNICAL FIELD
The present invention relates to switches for connecting and disconnecting high voltage devices to electric power circuits and, more particularly, to a switch with external resistors and a high speed whip and drive mechanism for staged insertion of the resistors when connecting a capacitor bank to a circuit.
BACKGROUND OF THE INVENTION
Electric power delivery systems such as those operated by electric utilities, large industrial facilities, military bases, and airports typically include a number of high voltage devices such as capacitor banks, voltage regulators, transformers, reclosers, surge arrestors, circuit breakers, and so forth. These devices are used in the operation of the system to maintain the quality of the electric power delivered at a power factor close to 1.0, to deliver the electric power at a certain voltage, to increase system reliability, and/or for other functions. Typically, each of these devices is connectable to the power circuit by a switch.
Conventional electric power switches have a male and a female contact that can be moved between a “closed” position with the contacts in physical contact and an “open” position with the contacts physically separated. For an electric power line that carries a high voltage and/or high current, it is desirable to open and close the male and female contacts very quickly in order to avoid a pre-strike, in which the electric current arcs across a physical gap between the contacts. Pre-strikes impose high current spikes and serious voltage disturbances on the power line, and can also physically degrade the components of the switch, especially the contacts. These current spikes and voltage disturbances can also damage other pieces of equipment connected to the circuit.
Pre-strikes occur when the switch's contacts are not yet in physical contact in the closing operation, but are still close enough to each other to permit electric current to arc through the air or other media between the contacts. When the contacts of a properly designed switch are fully separated in the open position, the distance between the contacts is sufficient to minimize pre-strikes. However, a pre-strike can occur as the contacts are moved through a “closing stroke” from the fully separate, open position to the fully connected, closed position. Likewise, an arc can occur across a gap between the contacts as the contacts are moved through an “opening stroke” from the closed position to the open position.
In order to minimize the occurrence of pre-strikes and their associated problems, “interrupter” switches are often provided with high-speed mechanisms for closing the contacts either at voltage zero or after the voltage is minimized by a pre-insertion impedance which minimizes the closing transients. Such mechanisms are sometimes provided by spring-loaded mechanisms. Also, the contacts of interrupter switches are sometimes provided in a sealed housing with a dielectric gas, vacuum, or other media for quenching the arc. Additionally, interrupter switches are sometimes provided with a linkage connected to an actuator having an electric motor, fluid cylinder, or the like. Such linkages and actuators are designed for generating a large force to increase the velocity of the opening and closing strokes, operating the contacts of a three-phase switch simultaneously, and/or operating the switch remotely.
Typically, interrupter switches are designed to prevent restrikes when “opening” the switch under a load. However, when “closed” switching a charged capacitor bank into the power circuit, conventional interrupter switches often are not able to prevent pre-strikes.
Charged capacitor banks are switched into the power circuit to correct the power factor during high-load periods, and later switched out of the circuit when the load drops. Capacitor banks store a charge, for example, 1 “per unit” (PU), and electric power systems operate at a system voltage, plus or minus 1 PU. Therefore, a conventional system-rated capacitor switch for connecting a 1 PU capacitor to the power circuit will be subjected to a 0 to 2 PU voltage surge when closing to connect the charged capacitor bank to the circuit, often resulting in intense high overvoltages. Additionally, capacitor banks are often connected and disconnected to the power circuit several times a day as the system load varies, resulting in multiple overvoltages each day.
Specialized capacitor switches have been developed in an effort to address this problem. One such type of capacitor switch has a series of sacrificial contacts that are designed to deteriorate over time as a result of current surges. However, these contacts must be regularly monitored and replaced as they deteriorate, thereby increasing the cost of using this type of switch. Because capacitor banks are often connected and disconnected to the power circuit more than once a day, the contacts must be monitored and replaced on a very strict basis. These switches do not prevent pre-strikes when connecting a charged capacitor bank to the power line, so the electric power system is still subjected to damaging current spikes and voltage disturbances. This is in part because these switches are generally based on conventional interrupter switch designs which prevent restrikes upon opening the switch, but for capacitor switching the potential for pre-strikes is greatest upon closing of the switch.
Another type of known capacitor switch includes a resistor in series with the capacitor when the capacitor is first connected into the circuit in order to reduce the current spikes. However, these devices tend to be unwieldy, bulky, and very difficult to time so that they are introduced into the circuit just as the capacitor is connected to reduce these inrush currents.
Accordingly, there is a need in the art for a capacitor switch for connecting a charged capacitor bank to an electric power circuit with controlled current spikes, that is easy to adjust for properly timing the switching operation, that is durable and reliable over thousands of operations, and that can be made and used at an affordable cost.
SUMMARY OF THE INVENTION
The present invention satisfies the aforementioned needs by providing a switch for gradually stepping a capacitor bank into an electric power circuit to compensate for power factor deviations. This is accomplished by providing two (or another number of resistors or other current limiting devices) and a conventional interrupter switch mechanism configured in series with the capacitor bank. Current flow is initiated in a staged sequence through the first resistor, then the second resistor, then the switch mechanism. The first resistor has a significantly higher resistance than the second resistor, which in turn has a significantly higher resistance than the switch mechanism. In this fashion, current flow from the charged capacitor bank is gradually stepped into the circuit, thereby significantly reducing electrical disturbances in the capacitor bank, the switch, and the circuit.
Additionally, the staged sequence of introducing the resistors and the switch mechanism is accomplished by the provision of a drive mechanism for operating an engagement arm to introduce the first and second resistors into the circuit, and an actuator for operating the switch mechanism. The drive mechanism and the actuator are operatively coupled together by a drive shaft or another linkage, with the drive mechanism, the actuator, and/or the drive shaft being readily adjustable to accomplish the desired timing of the sequence. The drive mechanism and the actuator are operable by the drive shaft to sequentially introduce the resistors into the circuit, then to introduce the switch mechanism and remove the resistors from the circuit so that the circuit has the full benefit of the capacitor bank for achieving power factor correction. Furthermore, the drive mechanism, the actuator, the switch mechanism, and the drive shaft can be provided by or made of relatively simple, readily available components, so that the switch is reliable, durable, and cost effective to implement in large quantities. For example, the switch mechanism can be provided by a conventional interrupter switch mechanism having a housing containing the contacts and a dielectric gas such as SF6, with the resistors disposed external of the housing.
Generally described, the switch includes a switch mechanism having a first contact and a second contact, an actuator mechanism coupled to the switch mechanism and operable to move the switch contacts between an open position and an closed position, a first resistor, a second resistor, an engagement arm such as a whip, a drive mechanism coupled to the engagement arm and operable to pivot the engagement arm between an open position and a closed position, and a drive shaft coupled to and operating the actuator mechanism and the drive mechanism. When the drive shaft rotates in a closing stroke, it operates the drive mechanism to pivot the engagement arm into contact with the first resistor then into contact with the second resistor, and operates to cause the actuator to close the switch mechanism contact just after the engagement arm contacts the second resistor.
In one aspect of the invention, the first and second resistors each have a contact adapted to receive the engagement arm, with each of the contacts positioned so that, when the engagement arm moves from the open to the closed position, the contact end of the first resistor receives the engagement arm before the contact end of the second resistor receives the engagement arm. Thus, the first resistor contact can have a length that is greater than a length of the second resistor contact.
In another aspect of the invention, the drive mechanism has a first hub that is coupled to the drive shaft and that moves between a first hub open position and a first hub closed position in response to rotation of the drive shaft, with the first hub having a latch release member. Also, the drive mechanism can have a second hub that is spring-biased to move between a second hub open position and a second hub closed position in response to rotation of the first hub, with the second hub having a catch member and where the engagement arm is coupled to the second hub. Additionally, the drive mechanism can have a movable latch member that is biased towards an engaged position where the latch member contacts the catch member and prevents movement of the second hub from the second hub open position to the closed position. The latch release member can be positioned so that, when the first hub is moved from the first hub open position toward the closed position, the latch release member contacts and moves the latch member away from the second hub into a disengaged position, thereby permitting the second hub and the engagement arm to move from the open position to the closed position at a high velocity under the force of the spring.
In yet another aspect of the invention, the latch member has an adjustable closing latch member that is positioned so that, when the first hub is moved from the first hub open position toward the closed position, the latch release member contacts the adjustable closing latch member. Also, the second hub can have an adjustable stop member positioned thereon so that, when the first hub moves from the first hub closed position toward the open position, the latch release member contacts the stop member and causes the second hub to move from the second hub closed position to open position. Additionally the latch member can have an opening latch surface defined thereon so that, when the second hub moves from the second hub closed position to the open position in response to movement of the first hub from the first hub closed position to the open position, the catch member contacts the opening latch surface and moves the latch member from the latch engaged position to the disengaged position.
In a further aspect of the invention, there are provided three of the switches forming a three-pole switch for use in a three-phase electric power circuit. Additionally, a three-pole operator mechanism with an operator can be connected to the three-pole switch, for remote operation of the three-pole switch.
Another aspect of the invention is that the switch can be configured with the resistors and the interrupter switch mechanism in series, with the drive mechanism configured for generating a whip action during the opening stroke. In this manner, the switch can be used to split the voltage during and achieve a smoother opening of the switch.
In yet another aspect of the invention, a separate whip or other engagement arm can be provided for each resistor and contact. In this manner, there is provided greater flexibility and reliability of the switch.
In still a further aspect of the invention, there is provided a method for switching an electrical device into an electric power circuit. The method can include the steps of providing a switch mechanism, a first resistor, and a second resistor, initiating a current flow through the first resistor, initiating a current flow through the second resistor and limiting the current flow through the first resistor, and initiating a current flow through the switch mechanism and limiting the current flow through the first and second resistors. Also, the steps of initiating a current flow through the first and second resistors can include providing an engagement arm pivotally coupled to the switch mechanism and pivoting the engagement arm from an open position separated from the first and second resistors to a closed position in contact with the first and second resistors so that the engagement arm contacts the first resistor before the engagement arm contacts the second resistor.
Additionally, the step of pivoting the engagement arm from the open position to the closed position can include providing at least one drive mechanism coupled to the engagement arm, providing a rotary drive shaft operatively coupled to the drive mechanism, rotating the drive shaft, preventing pivoting of the engagement arm and generating a spring-loaded force urging the engagement arm to pivot from the open position to the closed position, releasing the engagement arm, and pivoting the engagement arm in response to the spring force. Furthermore, the step of initiating a current flow through the switch mechanism can include providing an actuator mechanism operatively coupled to the switch mechanism and coupled to the rotary drive shaft, and actuating the actuator, in response to rotation of the drive shaft, to close the contacts of the switch mechanism to initiate current flow through the switch mechanism and limit the current flow through the first and second resistors.
In view of the foregoing, it will be appreciated that the present switch provides a substantial improvement over the prior art by significantly reducing the electrical disturbances caused when connecting a capacitor bank to an electric power circuit. The specific techniques and structures employed by the invention to improve over the drawbacks of the prior systems and accomplish the advantages described above will become apparent from the following detailed description of the embodiments of the invention and the appended drawings and claims.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a schematic diagram of an exemplary embodiment of the present invention, showing a staged introduction a first resistor, a second resistor, an interrupter switch mechanism, and a capacitor bank into an electric power circuit.
FIG. 1A
is a schematic diagram of an alternative embodiment of the present invention, showing an alternative configuration of the first and second resistors.
FIG. 2
is a side view of the interrupter switch mechanism of
FIG. 1
, showing the contacts and an actuator for operating the switch mechanism.
FIG. 3
is a front elevation view of a three-pole configuration of the switch of
FIG. 1
, also showing an operating mechanism for remotely operating all three poles of the switch simultaneously.
FIG. 4
is a plan view of the three-pole switch of FIG.
3
.
FIG. 5
is a side elevation view of the three-pole switch of FIG.
3
.
FIG. 6
is a detail rear elevation view of one pole of the switch of
FIG. 3
, showing a drive mechanism for operating the engagement arm.
FIG. 7
is a front perspective view of the drive mechanism of FIG.
6
.
FIG. 8A
is a side elevation view of the drive mechanism of
FIGS. 6 and 7
, showing the engagement arm in an open position.
FIG. 8B
is a side elevation view of the drive mechanism of
FIG. 8A
, showing the operation of the drive mechanism as the engagement arm is released to pivot through a closing stroke.
FIG. 8C
is a side elevation view of the drive mechanism of
FIG. 8A
, showing the operation of the drive mechanism as the engagement arm begins to pivot through the closing stroke.
FIG. 8D
is a side elevation view of the drive mechanism of
FIG. 8A
, showing the operation of the drive mechanism as the engagement arm pivots through the closing stroke.
FIG. 8E
is a side elevation view of the drive mechanism of
FIG. 8A
, showing the engagement arm in a closed position.
FIG. 9A
is a side elevation view of the drive mechanism of
FIGS. 6 and 7
, showing the operation of the drive mechanism as the engagement arm begins to pivot through an opening stroke.
FIG. 9B
is a side elevation view of the drive mechanism of
FIG. 9A
, showing the operation of the drive mechanism as the engagement arm pivots through the opening stroke.
FIG. 9C
is a side elevation view of the drive mechanism of
FIG. 9A
, showing the operation of the drive mechanism as the engagement arm begins to be locked into the open position.
FIG. 9D
is a side elevation view of the drive mechanism of
FIG. 9A
, showing the operation of the drive mechanism as the engagement arm pivots into the open position.
FIG. 10
is a schematic diagram of an alternative embodiment of the present invention, showing a staged introduction a first resistor, a second resistor, and an interrupter switch mechanism to disconnect a load from an electric power circuit.
FIG. 11
is a front elevation view of a portion of an alternative switch of the present invention, showing a separate engagement arm for each resistor and contact.
FIG. 12
is a plan view of the switch of FIG.
11
.
FIG. 13
is a side elevation view of the switch of FIG.
12
.
DETAILED DESCRIPTION OF THE EXEMPLARY EMBODIMENTS
Referring now to
FIG. 1
, there is shown an exemplary embodiment of the present invention, referred to generally as the switch
10
. The switch
10
is electrically connected to an electrical device such as a capacitor or a bank of capacitors
12
, or another high voltage device, by electrically connections known in the art. Also, the switch
10
is electrically connected to a power line
16
that delivers electric power from a power source
14
to one or a number of loads
17
. The capacitor bank
12
, power line
16
, and power source
14
are typically grounded by conventional ground wires.
The switch
10
includes a conventional interrupter switch mechanism
18
, at least one current initiation device such as a relatively high resistance first resistor
22
with a first contact
24
and a relatively low resistance second resistor
26
with a second contact
28
, and a movable engagement arm
30
. The resistors
22
and
26
and contacts
24
and
28
are configured in parallel with the switch mechanism
18
. Accordingly, when the switch
10
is operated through a closing stroke, the engagement arm
30
moves from an open position A, through an intermediate position B, a first resistor contact position C, and a second resistor contact position D, and to a closed position E.
In the open position A, the engagement arm
30
is spaced sufficiently apart from the resistors
22
and
26
and the resistor contacts
24
and
28
to form a gap across which current strikes and pre-strikes normally can not occur. In the intermediate position B, the gap is approaching the point where current strikes might occur, but the current is significantly limited by the first resistor
22
such that over-voltages normally will not occur.
In the first resistor contact position C, the engagement arm
30
comes into electrical contact with the first resistor
22
via the first contact
24
, thereby forming a first current path and initiating a limited current flow through the first resistor
22
to significantly dampen the initial electrical disturbances of closing the switch. In the second resistor contact position D, the engagement arm
30
comes into electrical contact with the second resistor
26
via the second contact
28
, thereby forming a second current path. The second resistor
26
has a substantially lower electrical resistance relative to the first resistor
22
such that, at position D, the first resistor
22
is effectively shorted out from the circuit. Thus, an increased current then flows through the second resistor
26
, thereby providing a staged introduction of the capacitor bank
12
into the power line
16
.
As the engagement arm
30
approaches the closed position E, or just after or simultaneously therewith, the switch mechanism
18
is closed. This effectively shorts out the first and second resistors
22
and
26
, so that substantially all of the current then flows through the switch mechanism
18
. This staged arrangement of the first resistor
22
, the second resistor
26
, and the switch mechanism
18
provides a smooth introduction of the capacitor bank into the circuit with reduced electrical disturbances.
Referring to
FIG. 1A
, there is shown an alternative switch
10
a
, with a first resistor
22
a
and contact
24
a
, a second resistor
26
a
and contact
28
a
, a switch mechanism
18
a
, and an engagement arm
30
a
that are similar to the like-named components of the above-described exemplary switch
10
. In this arrangement, the resistors
22
a
and
26
a
are configured differently as shown in the drawing figures, but provide the same smooth introduction of the capacitor bank into the power circuit upon closing of the switch
10
a.
Referring now to
FIG. 2
, the switch mechanism
18
can be provided by a conventional interrupter switch mechanism having a housing
21
, a first contact
23
, and a second contact
25
, as are known in the art. A dielectric gas such as SF6 or another medium such as a vacuum can be provided within the housing for quenching potential arcs. Alternatively, the switch mechanism can be provided by a conventional airbreak switch, a non-interrupter switch, or another switch mechanism having linear, pivotal, rotary, or other arrangements of contacts, as are known in the art. Additionally, an actuator mechanism
20
can be operatively connected to the switch mechanism
18
for closing the contacts
23
and
25
in a timely fashion relative to closing of the engagement arm with the resistors. A suitable switch mechanism
18
and actuator mechanism
20
are disclosed by U.S. patent application Ser. No. 09/448,198 filed Nov. 23, 1999, which is hereby incorporated by reference in its entirety.
Referring now to
FIGS. 3-5
, which show a three-pole arrangement of three of the switches
10
, each switch mechanism
18
has a first end
32
and a second end
34
. Terminal pads
36
are provided at each of the ends
32
and
34
for connection thereto of conventional electric conductors. The contacts
23
and
25
of each switch mechanism
18
are electrically connected to the ends
32
and
34
, forming a current path through the contacts
23
and
25
, the switch mechanism ends
32
and
34
, and the terminal pads
36
, when the switch mechanism is closed.
The engagement arm
30
is coupled to the switch mechanism second end
34
by a drive mechanism (described below) that causes movement between the open and closed positions. Thus, the engagement arm
30
can be coupled to the switch mechanism
18
for permitting a motion that is pivotal, or another motion such as rotary or linear. The engagement arm
30
can be provided by a conventional whip made of a conductive material such as a metal. Alternatively, the engagement arm
30
can be provided by a blade, bar, pipe, or other structure known in the art.
The first resistor
22
and the second resistor
26
are connected to the first end
32
of the switch mechanism
18
by resistor support brackets
38
. The resistor support brackets
38
can be made of an electrically conductive material such as a metal for forming a current path from the resistors to the terminal pads. Alternatively, the current path can be formed by a separate wire, bar, pipe, or other conductor.
The resistor contacts are arranged with the first contact
24
electrically connected to and extending from the first resistor
22
and the second contact
28
electrically connected to and extending from the second resistor
26
. The first contact
24
has an engagement end
40
and the second contact
28
has an engagement end
42
that are positioned so that, when the engagement arm
30
pivots from the open to the closed position, first contact engagement end
40
receives the engagement arm
30
before the second contact engagement end
42
receives the engagement arm. For example, the first resistor contact
24
can have a length that is greater than a length of the second resistor contact
28
. The contacts
24
and
28
are made of an electrically conductive material such as a metal, and can be provided by a generally rigid wire, or another structure such as a bar or pipe.
Because of the position of the resistor contacts
24
and
28
, a first current path is formed through the engagement arm
30
and the first resistor
22
when the engagement arm contacts the first resistor contact
24
, a second current path is formed through the engagement arm
30
and the second resistor
26
when the engagement arm
30
contacts the second resistor contact
28
, and a third current path is formed through the contacts
23
and
25
of the switch mechanism
18
when the contacts are closed. The position of the engagement arm
30
, the first resistor
22
, the second resistor
26
, and the switch mechanism
18
can be selected so that the first, second, and third current paths are in an electrically parallel configuration.
As described above, when the engagement arm
30
pivots from the open position to the closed position, the engagement arm
30
contacts the first contact engagement end
42
before the second contact engagement end
44
, and the engagement arm
30
contacts the second contact engagement end
44
before the actuator
20
closes the switch contacts. Therefore, in order to provide the staged introduction of the capacitor bank into the electric circuit, the first resistor
22
has an electrical resistance that is substantially greater than an electrical resistance of the second resistor
26
. For example, the first resistor
22
can be provided with an electrical resistance of 1,000 ohms, and the second resistor
26
can be provided with an electrical resistance of 10 ohms. Of course, other resistance ratings can be used, and/or the switch
10
can be provided with only one resistor or with three or more resistors. Also, other current initiation devices can be used, such as other current limiting devices or inductors, alone or in combination with one or more resistors, as may be desired in a given application.
In the three-pole arrangement shown, the switches
10
are each mounted on a support insulator
44
, with the support insulators mounted onto a frame
46
. Alternatively, the switch
10
can be provided in one-pole, two-pole, or other arrangement, as may be desired for a particular circuit. A pivotal drive arm
48
can be operatively coupled to each actuator
20
and to each engagement arm
30
(as described below), and driven by an operator mechanism
50
. The operator mechanism
50
can have a drive rod
52
connected to each drive arm
48
, an interphase rod
54
interconnecting the drive rods
52
for simultaneous operation of the three switches
10
, a control rod
56
connected to the interphase rod
54
, and a control actuator
58
connected to the control rod
56
. The operator mechanism
50
thus provides for remote operation of the switch
10
, as may be desired for substation control of a switch that is positioned out on a power line. It will be understood that the support insulator
44
, the frame
46
, the operator mechanism
50
, and the control actuator
58
can be suitably provided by conventional structures and devices well known in the art. For example, the control actuator
58
can be provided with spur gears and a reversible ¼ HP, 125 volt DC motor.
Referring now to
FIGS. 6 and 7
, the switch mechanism actuator
20
and an engagement arm drive mechanism
64
are sequentially operated in response to movement of a drive member
62
such as a rotary drive shaft. The actuator
20
includes a trigger mechanism
61
that initiates operation of the actuator
20
, thereby causing the switch mechanism
18
to operate between the open and closed positions. The trigger mechanism can be provided by a contact plunger
63
that is engaged by a cam
65
on the drive shaft
62
, as described in U.S. patent application Ser. No. 09/448,198 filed Nov. 23, 1999. Of course, other trigger mechanisms can be suitably employed. The drive mechanism
64
is operable by the drive shaft
62
to move the engagement arm
30
between the open position and the closed position so that the engagement arm
30
contacts the first and second resistors
22
and
26
before the actuator
20
closes the contacts
23
and
25
. The drive shaft
62
can be rotationally mounted to a support member
60
that is disposed between the switch mechanism
18
and the actuator
20
. Alternatively, the drive shaft
62
can be mounted directly to the switch mechanism
18
or to an adjacent structure.
The drive mechanism
64
has a latch member
66
that is coupled to the support member
60
to permit the latch
66
to move between an engaged position and a disengaged position. For example, the latch member
66
can be pivotally coupled to the support member
60
by a conventional pivotal mounting
70
. Alternatively, the latch member
66
can be coupled to the support member
60
to permit the latch
66
to move linearly, rotationally, or otherwise between the engaged and disengaged positions. The latch
66
is biased toward the engaged position by a spring
72
such as a coil, leaf, or other spring mechanism.
The latch member
66
has an opening surface
74
, a catch surface
76
, and a closing surface
78
formed thereon. The opening surface
74
and the catch surface
76
can be defined on opposite sides of a wedge-shaped protruding portion of the latch member
66
. Alternatively, the protruding portion can have another regular or irregular shape, or be formed by a hook, wing, bar, arm, rod, or other structure. Also, the opening and catch surfaces
74
and
76
can be formed on adjustable members for adjusting the position of the surfaces
74
and
76
. The closing surface
78
can be provided on a closing adjusting member
80
such as a threaded bolt received in a threaded aperture in the latch member
66
. Alternatively, the closing adjusting member
80
can be provided by a threaded screw, a notched pin, a spring-loaded member, or another adjustable member, or the closing surface can be defined directly on a portion of the latch member
66
.
The drive mechanism
64
also has a first hub
82
and a second hub
84
that are coupled to the drive shaft
62
. The first hub
82
can be fixedly coupled to the drive shaft
62
to permit the hub
82
to rotate between a first hub open position and a first hub closed position in response to rotation of the drive shaft
62
. The second hub
84
can be rotationally coupled to the drive shaft
62
and biased relative to the first hub
82
to permit the hub
84
to rotate between a second hub open position and a second hub closed position in response to rotation of the first hub
82
. Thus, the second hub
84
can biased against rotation by a spring
86
such as a coil, leaf, or other spring structure connected between the second hub
84
and the first hub
82
or the drive shaft
62
.
The engagement arm
30
is coupled to the second hub
84
so that the engagement arm
30
is pivoted from the open position to the closed position when the drive shaft
62
is rotated. Because a current path is formed through the engagement arm
30
and through the drive mechanism
64
, selected components of the drive mechanism
64
(such as the first and second hubs
82
and
84
) and the drive shaft
62
are made of electrically conductive material such as a metal. Alternatively, the current path can be provided through a separate wire or other conductor connected between the engagement arm
30
and the terminal pad
36
at the second end
34
of the switch mechanism
18
.
The first hub
82
has a latch release member
88
and the second hub
84
has a catch member
94
that cooperate with the latch member
66
to pivot the engagement arm
30
closed, as described below. The release member
88
can be provided by a bar that extends over a portion of the first hub
82
. Alternatively, the release member
88
can be provided by a rod or by an adjusting bolt or other adjusting member. The catch member
94
can be provided by a roller
96
rotationally mounted to a roller bracket
98
. Alternatively, the catch member
94
can be provided by a wedge-shaped member, a rod, a bar, or by an adjusting bolt or other adjusting member.
The second hub
84
also has a stop member
90
that cooperates with the latch member
66
and the catch member
94
to pivot the engagement arm
30
open, as described below. The stop member can be provided by a stop adjusting member
92
such as a threaded bolt received by a threaded aperture in a bar, or by another adjusting mechanism. Alternatively, the stop member
90
can be formed integrally on the second hub
84
.
Referring now to
FIGS. 8A-8E
, there is illustrated the operation of the drive mechanism
18
to pivot the engagement arm from the open to the closed position.
FIG. 8A
shows the engagement arm
30
in the open position A (see also FIG.
1
), while the switch mechanism
18
is also in the open position. The latch member
66
is biased into the engaged position where the latch member catch surface
76
contacts the catch member
94
and prevents rotation of the second hub
94
from the second hub open position to the closed position.
As shown in
FIG. 8B
, as the drive arm
48
is rotated, the first hub
82
rotates from the first hub open position toward the closed position, but the second hub
84
and the engagement arm
30
are held in position by the latch member
66
, thereby loading the spring
86
. As shown in
FIG. 8C
, as the drive arm
48
and the first hub
82
are further rotated, the latch release member
88
contacts the latch member closing surface
78
and pivots the latch member
66
away from the second hub into the disengaged position. The second hub
84
is now free to rotate.
As shown in
FIG. 8D
, under the force of the loaded spring
86
, the second hub
84
and engagement arm
30
rotate at great velocity from the open position to the closed position. The engagement arm
30
thus pivots through the intermediate position B, the first resistor contact position C, and the second resistor contact position D (see FIG.
1
), thereby providing the staged introduction of the first and second resistors
22
and
26
to significantly dampen the initial electrical disturbances of closing the switch.
FIG. 8E
shows the second hub
84
and engagement arm
30
in the closed position E (see also FIG.
1
). As the engagement arm
30
approaches the closed position, or just after or simultaneously therewith, the rotating drive shaft
62
triggers the actuator
20
to close the switch mechanism
18
. The actuator
20
is timed for this sequential operation by selecting the position of (or by adjusting) the latch release member
88
on the first hub
84
, and by adjusting (or selecting the position of) the closing adjusting member
80
. For example, the operation of the switch mechanism
18
can be timed for closing the switch mechanism contacts about 100-200 milliseconds after the engagement arm
30
reaches the second resistor contact position D (see FIG.
1
), depending on the control operator selected. The first and second resistors
22
and
26
are thereby shorted out in a few cycles, so that substantially all of the current then flows through the switch mechanism
18
.
Referring now to
FIGS. 9A-9D
, there is illustrated the operation of the drive mechanism
18
to pivot the engagement arm from the closed to the open position.
FIG. 9A
shows the engagement arm
30
in the closed position E (see also FIG.
1
), while the switch mechanism
18
is also in the closed position. As shown in
FIG. 9B
, as the drive arm
48
and the first hub
82
rotate from the closed position toward the open position, the latch release member
88
contacts the stop member
90
and causes the second hub
84
to rotate from the second hub closed position to open position, thereby pivoting the engagement arm
30
toward the open position. As the engagement arm
30
begins to pivot open, or just thereafter, the rotating drive shaft
62
triggers the actuator
20
to open the switch mechanism
18
. Similar to the closing operation, the actuator
20
is timed for this sequential operation by selecting the position of (or by adjusting) the latch release member
88
on the first hub
84
, and by adjusting (or selecting the position of) the stop member
90
.
As shown in
FIG. 9C
, as the second hub
84
rotates further, the catch member
94
contacts the latch member opening surface
74
and pivots the latch member
66
from the latch engaged position to the disengaged position. As shown in
FIG. 9D
, as the second hub
84
rotates further and into the open position A, the catch member
94
moves past the latch member opening surface
94
, permitting the latch member
66
to pivot back to the latch engaged position where the second hub
84
is prevented from rotating from the open to the closed position. The drive mechanism
64
is now set for the next closing operation.
Referring now to
FIG. 10
, there is shown an alternative switch
110
that is similar to the switch
10
, and includes an interrupter switch mechanism
118
, an actuator mechanism
120
for the interrupter switch, at least one current initiation device, for example, first and second resistors
122
and
126
, an engagement arm
130
, and a drive mechanism
164
for the engagement arm, with the drive mechanism and the actuator mechanism operatively coupled together by, for example, drive member
162
. However, the switch
110
is used to connect a load
117
to a power line
116
, and is adapted for introducing the resistors
122
and
126
into the circuit upon opening of the switch
110
to the split the voltage and thereby reduce electrical disturbances in the lines. These adaptations can include configuring the interrupter switch
118
in series with the resistors
122
and
126
, and reversing the orientation of the drive mechanism
164
so that the whip action is produced during the opening stroke of the engagement arm
130
. The resistors
122
and
126
can be configured in a staged arrangement so that the engagement arm
130
first contacts both and then only one of the resistors, so that it first contacts one then the other resistor, or in other configurations. Also, it will be understood that two (or another number) of drive mechanisms
164
, engagement arms
130
, resistor pairs
122
and
126
, and interrupter switches
118
can be provided for generating the whip action on both the opening and closing stroke of the engagement arm, as may be desired.
Referring now to
FIGS. 11-13
, there is shown a portion of another alternative switch
210
that is similar to the switch
10
. This embodiment includes an interrupter switch mechanism
218
, an actuator mechanism
220
for the interrupter switch, at least one current initiation device, for example, first and second resistors
222
and
226
, an engagement arm such as a whip for each current initiation device, for example, first and second engagement arms
230
and
231
, and a drive mechanism
264
for the engagement arms, with the drive mechanism
264
and the actuator mechanism
220
operatively coupled together. The resistors have contacts for receiving the engagement arms, with a first contact
224
electrically connected to and extending from the first resistor
222
and a second contact
228
electrically connected to and extending from the second resistor
226
, with the resistors and contacts configured in parallel with the interrupter switch.
In this embodiment, separate engagement arms are provided for each resistor contact, with the engagement arms positioned so that, when they pivot from the open to the closed position, the first contact
224
receives the first engagement arm
230
before the second contact
228
receives the second engagement arm
231
. For example, the first engagement arm
230
can have a length that is less than a length of the second engagement arm
231
, so the first engagement arm does not engage or interfere with the second contact, and the second engagement arm does not engage or interfere with the first contact. In this embodiment, there is provided additional flexibility in positioning the engagement arms and adjusting the timing of the introduction of the resistors into the switching circuit. Also, if one of the engagement arms mechanically fails, the other arm can still operate to provide some dampening of electrical disturbances upon closing of the switch
210
, thereby providing greater reliability.
In addition to the above-described switches, there is provided a new method for switching an electrical device into an electric power circuit. The method can include providing a switch mechanism such as switch mechanism
18
, a first resistor such as first resistor
22
, and a second resistor such as second resistor
26
. The first and second resistors can be disposed external of the switch mechanism
18
. The method further includes initiating a current flow through the first resistor, initiating a current flow through the second resistor and limiting the current flow through the first resistor, and initiating a current flow through the switch mechanism and limiting the current flow through the first and second resistors. The method thereby provides for a smooth, staged introduction of a capacitor bank or another device into an electric circuit with reduced electrical disturbances.
In the present method, the step of initiating a current flow through the first resistor and the step of initiating a current flow through the second resistor can include providing the first and second resistors coupled to a first end of the switch mechanism, providing an engagement arm pivotally coupled to a second end of the switch mechanism, and pivoting the engagement arm from an open position separated from the first and second resistors to a closed position in contact with the first and second resistors so that the engagement arm contacts the first resistor before the engagement arm contacts the second resistor. Additionally, the step of pivoting the engagement arm from the open position to the closed position can include providing at least one drive mechanism coupled to the engagement arm, providing a rotary drive shaft operatively coupled to the drive mechanism, rotating the drive shaft, preventing pivoting of the engagement arm and generating a spring-loaded force urging the engagement arm to pivot from the open position to the closed position, releasing the engagement arm, and pivoting the engagement arm in response to the spring force.
Furthermore, the step of initiating a current flow through the switch mechanism can include providing an actuator mechanism operatively coupled to the switch mechanism and coupled to the rotary drive shaft, and actuating the actuator, in response to rotation of the drive shaft, to close at least two contacts of the switch mechanism to initiate current flow through the switch mechanism and limit the current flow through the first and second resistors.
Thus, it will be appreciated that the switching apparatus and/or method provide for a staged introduction of the capacitor bank into the electric power circuit with significantly reduced electrical disturbances. Furthermore, the switch is easy to adjust for properly timing the staged switching operation, is durable and reliable over thousands of operations, and can be made and used at an affordable cost.
In the embodiments described above and in the following claims, the words “a,” “an,” and “one” are not intended to mean only “one” but can also mean any number greater than one, unless specified otherwise herein. While certain embodiments are described above with particularity, these should not be construed as limitations on the scope of the invention. It should be understood, therefore, that the foregoing relates only to the exemplary embodiments of the present invention, and that numerous changes may be made therein without departing from the spirit and scope of the invention as defined by the following claims.
Claims
- 1. A switch for an electric power circuit, comprising:a) a switch mechanism having a first contact and a second contact movable between an open position with the contacts separated and a closed position with the contacts in contact, and having a first end and a second end; b) a first resistor coupled to the first end of the switch mechanism; c) a second resistor coupled to the first end of the switch mechanism; and d) at least one engagement arm coupled to the second end of the switch mechanism and movable between an open position separated from the resistors and a closed position in contact with the resistors, wherein the first resistor and the second resistor are positioned so that when the engagement arm moves from the open position to the closed position, the engagement arm contacts the first resistor before the second resistor and the engagement arm contacts the second resistor before the switch contacts close.
- 2. The switch of claim 1, wherein the first resistor has an electrical resistance that is different from an electrical resistance of the second resistor.
- 3. The switch of claim 2, wherein the electrical resistance of the first resistor is substantially greater than the electrical resistance of the second resistor.
- 4. The switch of claim 1, wherein the first and second resistors each have a contact adapted to receive the engagement arm.
- 5. The switch of claim 4, wherein each of the resistor contacts has an engagement end, wherein the resistor contact ends are positioned so that, when the engagement arm moves from the open to the closed position, the contact end of the first resistor receives the engagement arm before the contact end of the second resistor receives the engagement arm.
- 6. The switch of claim 4, wherein the first resistor contact has a length that is greater than a length of the second resistor contact.
- 7. The switch of claim 1, wherein a first current path is formed by the engagement arm and the first resistor when the engagement arm contacts the first resistor, a second current path is formed by the engagement arm and the second resistor when the engagement arm contacts the second resistor, and a third current path is formed by the contacts of the switch mechanism when the contacts are closed, wherein the first, second, and third current paths are arranged in an electrically parallel configuration.
- 8. The switch of claim 7, wherein the first current path has an electrical resistance that is greater than an electrical resistance of the second current path, and the electrical resistance of the second current path is greater than an electrical resistance of the third current path.
- 9. The switch of claim 1, further comprising an actuator mechanism coupled to the switch mechanism and operable to move the switch contacts between the open position and the closed position.
- 10. The switch of claim 9, further comprising at least one drive mechanism coupled to the engagement arm and the actuator mechanism, wherein the drive mechanism is operable to move the engagement arm between the open position and the closed position so that the engagement arm contacts the first and second resistors before the actuator closes the contacts.
- 11. The switch of claim 8, wherein the at least one engagement arm comprises a first engagement arm and a second engagement arm, wherein the first and second resistors and the first and second engagement arms are positioned so that, when the engagement arms move from the open position to the closed position, the first engagement arm contacts the first resistor before the second engagement arm contacts the second resistor and the second engagement arm contacts the second resistor before the switch contacts close.
- 12. The switch of claim 11, wherein the first engagement arm has a length that is less than a length of the second engagement arm.
- 13. A switch for an electric power circuit, comprising:a) a switch mechanism having a first contact and a second contact movable between an open position with the contacts separated and a closed position with the contacts in contact, and having a first end and a second end; b) at least one actuator mechanism coupled to the switch mechanism and operable to move the switch contacts between the open position and the closed position; c) at least one current initiation device coupled to the first end of the switch mechanism; d) at least one engagement arm coupled to the second end of the switch mechanism and movable between an open position separated from the current initiation device and a closed position in contact with the current initiation device; and e) at least one drive mechanism coupled to the engagement arm and to the actuator mechanism, wherein the drive mechanism is operable to move the engagement arm between the open position and the closed position so that the engagement arm contacts the current initiation device before the actuator mechanism moves the contacts into the closed position.
- 14. The switch of claim 13, wherein the current initiation device comprises at least one resistor.
- 15. The switch of claim 13, further comprising a drive member, wherein the actuator mechanism and the drive mechanism are coupled to the drive member and operate in response to movement of the drive member.
- 16. The switch of claim 15, wherein the drive member comprises a rotary drive shaft with a drive arm coupled thereto.
- 17. The switch of claim 15, wherein the drive mechanism comprises:a) a first hub that is coupled to the drive member and that moves between a first hub open position and a first hub closed position in response to movement of the drive member, the first hub having a latch release member; b) a second hub that is biased to move between a second hub open position and a second hub closed position in response to movement of the first hub, the second hub having a catch member; wherein the engagement arm is coupled to the second hub; and c) a movable latch member that is biased towards an engaged position wherein the latch member contacts the catch member and prevents movement of the second hub from the second hub open position to the closed position, and wherein the latch release member is positioned so that, when the first hub is moved from the first hub open position toward the closed position, the latch release member contacts and moves the latch member away from the second hub into a disengaged position permitting the second hub to move from the second hub open position to the closed position.
- 18. The switch of claim 17, wherein the latch member has an adjustable closing latch member that is positioned so that, when the first hub is moved from the first hub open position toward the closed position, the latch release member contacts the adjustable closing latch member.
- 19. The switch of claim 17, wherein the second hub has an adjustable stop member positioned thereon so that, when the first hub moves from the first hub closed position toward the open position, the latch release member contacts the stop member and causes the second hub to move from the second hub closed position to open position.
- 20. The switch of claim 19, wherein the latch member has an opening latch surface defined thereon so that, when the second hub moves from the second hub closed position to the open position in response to movement of the first hub from the first hub closed position to the open position, the catch member contacts the opening latch surface and moves the latch member from the latch engaged position to the disengaged position.
- 21. A switch for an electric power circuit, comprising:a) a switch mechanism having a first contact and a second contact movable between an open position with the contacts separated and a closed position with the contacts in contact, and having a first end and a second end; b) at least one actuator mechanism coupled to the second end of the switch mechanism and operable to move the switch contacts between the open position and the closed position; c) a first resistor coupled to the first end of the switch mechanism and having a contact with an engagement end, wherein the first resistor has an electrical resistance; d) a second resistor coupled to the first end of the switch mechanism and having a contact with an engagement end, wherein the second resistor has an electrical resistance that is less than the electrical resistance of the first resistor; e) at least one engagement arm pivotally coupled to the second end of the switch mechanism and pivotal between an open position separated from the resistor contacts and a closed position in contact with the resistor contacts; f) at least one drive mechanism coupled to the engagement arm and operable to pivot the engagement arm between the open position and the closed position, wherein the drive mechanism is operable to pivot the engagement arm between the open position and the closed position so that the engagement arm contacts the contact end of the first resistor before the engagement arm contacts the contact end of the second resistor; and g) a rotary drive shaft coupled to the actuator mechanism and the drive mechanism, wherein the actuator mechanism and the drive mechanism operate in response to rotation of the drive shaft.
- 22. The switch of claim 21, wherein the drive mechanism comprises:a) a first hub that is coupled to the rotary drive shaft and that rotates between a first hub open position and a first hub closed position in response to rotation of the drive shaft, the first hub having a latch release member; b) a second hub that is biased to rotate between a second hub open position and a second hub closed position in response to rotation of the first hub, the second hub having a catch member; wherein the engagement arm is coupled to the second hub; and c) a pivotal latch member that is biased towards an engaged position wherein the latch member contacts the catch member and prevents rotation of the second hub from the second hub open position to the closed position, and wherein the latch release member is positioned so that, when the first hub is rotated from the first hub open position toward the closed position, the latch release member contacts and pivots the latch member away from the second hub into a disengaged position permitting the second hub to rotate from the second hub open position to the closed position.
- 23. The switch of claim 22, wherein the latch member has an adjustable closing latch member that is positioned so that, when the first hub is rotated from the first hub open position toward the closed position, the latch release member contacts the adjustable closing latch member.
- 24. The switch of claim 22, wherein the second hub has an adjustable stop member positioned thereon so that, when the first hub rotates from the first hub closed position toward the open position, the latch release member contacts the stop member and causes the second hub to rotate from the second hub closed position to open position.
- 25. The switch of claim 22, wherein the latch member has an opening latch surface defined thereon so that, when the second hub rotates from the second hub closed position to the open position in response to rotation of the first hub from the first hub closed position to the open position, the catch member contacts the opening latch surface and urges the latch member to pivot from the latch engaged position to the disengaged position.
- 26. The switch of claim 21, wherein the engagement arm comprises a whip.
- 27. The switch of claim 21, wherein the switch mechanism includes a sealed housing and a dielectric gas contained within the housing, wherein at least a portion of the contacts are disposed within the housing and the resistors are disposed external of the housing.
- 28. The switch of claim 21, further comprising at least one additional resistor coupled to the first end of the switch mechanism.
- 29. A three-pole switch for an electric power circuit, comprising three of the switches of claim 21.
- 30. The three-pole switch of claim 29, further comprising at least one three-pole operator mechanism operatively connected to the three-pole switch.
- 31. A method for switching an electrical device into an electric power circuit, comprising:a) providing a switch mechanism, a first resistor, and a second resistor, wherein the first and second resistors are disposed external of the switch mechanism; b) initiating a current flow through the first resistor; c) initiating a current flow through the second resistor and limiting the current flow through the first resistor; and d) initiating a current flow through the switch mechanism and limiting the current flow through the first and second resistors.
- 32. The method of claim 31, wherein the step of initiating a current flow through the first resistor and the step of initiating a current flow through the second resistor comprise:a) providing the first and second resistors coupled to a first end of the switch mechanism; b) providing an engagement arm pivotally coupled to a second end of the switch mechanism; and c) pivoting the engagement arm from an open position separated from the first and second resistors to a closed position in contact with the first and second resistors so that the engagement arm contacts the first resistor before the engagement arm contacts the second resistor.
- 33. The method of claim 32, wherein the step of pivoting the engagement arm from the open position to the closed position comprises:a) providing at least one drive mechanism coupled to the engagement arm; b) providing a rotary drive shaft operatively coupled to the drive mechanism; a) rotating the drive shaft; b) preventing pivoting of the engagement arm and generating a spring-loaded force urging the engagement arm to pivot from the open position to the closed position; c) releasing the engagement arm; and d) pivoting the engagement arm in response to the spring force.
- 34. The method of claim 33, wherein the step of initiating a current flow through the switch mechanism comprises:a) providing an actuator mechanism operatively coupled to the switch mechanism and coupled to the rotary drive shaft; and b) actuating the actuator, in response to rotation of the drive shaft, to close at least two contacts of the switch mechanism to initiate current flow through the switch mechanism and limit the current flow through the first and second resistors.
- 35. A switch for an electric power circuit, comprising:a) a switch mechanism having a first contact and a second contact movable between an open position with the contacts separated and a closed position with the contacts in contact; b) at least one actuator mechanism coupled to the switch mechanism and operable to move the switch contacts between the open position and the closed position; c) at least one current initiation device configured in series with the switch mechanism; d) at least one engagement arm configured in series with the switch mechanism and movable between an open position separated from the current initiation device and a closed position in contact with the current initiation device; and e) at least one drive mechanism coupled to the engagement arm and to the actuator mechanism, wherein the drive mechanism is operable to move the engagement arm between the closed position and the open position so that the engagement arm contacts the current initiation device before the actuator mechanism moves the contacts into the open position.
- 36. The switch of claim 35, wherein the current initiation device comprises a first resistor and a second resistor configured in a staged arrangement.
- 37. The switch of claim 35, further comprising a drive member, wherein the actuator mechanism and the drive mechanism are coupled to the drive member and operate in response to movement of the drive member.
US Referenced Citations (19)