The foregoing aspects and other features of the invention are explained in the following description, taken in connection with the accompanying drawings, wherein:
Referring to
The vacuum recloser 10 is shown connecting a first electrical conductor 12 to a second electrical conductor 14. For example, the conductors 12, 14 could be high voltage overhead power distribution lines. However, the vacuum recloser 10 could be used in any suitable application. The vacuum recloser 10 forms a switch between the two conductors 12, 14. When the switch is open, the first and second conductors are not electrically connected to each other through the switch. When the switch is closed, the first and second conductors are electrically connected to each other through the switch. In this embodiment the vacuum recloser is an in-line design connected in-line between the two conductors 12, 14. However, in alternate embodiments, the vacuum recloser could be provided other than in an in-line design.
Referring also to
In this embodiment, the first and second sections 22, 24 are substantially mirror images of each other. However, in alternate embodiments the two sections 22, 24 could be different. The first connection section 22 is preferably comprised of metal, such as cast metal for example. The first connection section 22 generally comprises an integral wedge section 30 for use with a wedge connector shell 32 for connecting the first connection section 22 with the first conductor. One example of a wedge connector shell is described in U.S. Pat. No. 5,507,671 which is hereby incorporated by reference in its entirety. However, in alternate embodiments, any suitable system for mechanically and electrically connecting the first conductor 12 to the first connection section 22 could be provided. For example, a non-wedge compression connection or a non-wedge mechanical connection could be used. The first connection section 12 comprises two leg sections 34 and a bottom platform section 36. The leg sections 34 are connected to the sections 28 of the electrical isolation section 26. The bottom platform section 36 extends between and beneath the two leg sections. However, in alternate embodiments, the first connection section 22 could comprise any suitable shape. The second connection section 24 is identical to the first connection section; just reversely orientated.
The electrical connection section 18 generally comprises a first end 38 movably connected to the first connection section 22 and an opposite second end 40 movably connected to the second connection section 24. In this embodiment the first end 38 is pivotably connected to the platform section 36 of the first connection section by a pivot connection 42. However, in alternate embodiments, any suitable type of movable connection could be provided. The pivot connection 42 electrically connects the first end 38 to the first connection section 22. The second end 40 is removably connected to the platform section of the second connection section by a latch assembly 44. The latch assembly 44 electrically connects the second end 40 to the second connection section 24. The latch assembly could comprise a primarily friction latch assembly, for example, and could comprise a detent system for preventing unintentional disconnection of the second end 40 from the latch assembly 44.
The electrical connection section 18 forms a movable arm connected between the first and second sections 22, 24. The arm comprises the first and second ends 38, 40 and a vacuum bottle section 46 between the two ends 38, 40. The vacuum bottle section comprises an outer housing 48 and at least two contacts 50, 52 located inside the housing 48. The first contact 50 is adapted to be moved into contact with and out of contact with the second contact 52. The housing 48 could comprise a window to allow a user to view the location of the contacts 50, 52 relative to each other, or the vacuum bottle section 46 could have any other suitable type of visual indicator to signal a user of the open or closed state of the contacts 50, 52. When the contacts 50, 52 are in an open state, the first and second connection sections are not electrically connected to each other. When the contacts 50, 52 are connected to each other in a closed state (with the electrical connection section 18 in the closed configuration shown in
The control 20 generally comprises three sections; an inductively coupled power supply section 54, a recloser electronic control section 56, and a capacitive discharge and solenoid actuation section 58. These three sections could be mounted on a single printed circuit board as separate modules for example. The inductively coupled power supply section 54 generally comprises a current transformer. Electricity can be inductively generated by the power supply section which is stored by the capacitors and powers the control section 56. The recloser electronic control section 56 generally comprises a voltage monitoring section. The control section 56 can continuously monitor the voltage from the current transformer and, thus, monitor the current being transmitted through the vacuum closer 10 between the two conductors 12, 14. A memory is provided on the printed circuit board which contains pre-installed action criteria. The recloser electronic control section 56 can use this pre-installed action criteria and sensed real time conditions to determine if the contacts 50, 52 of the vacuum bottle section 46 should be opened to stop transmission of current through the vacuum recloser 10.
The capacitive discharge and solenoid actuation section 58 generally comprises capacitors and a solenoid 60. Electricity from the transformer can be stored in the capacitors for use in actuating the solenoid 60 when directed by the recloser electronic control section 56. The solenoid 60 is connected to the first contact 50 of the vacuum bottle section 46 by an armature mechanism 62. When the solenoid relay piston of the solenoid is moved outward, the armature mechanism 62 is adapted to move the first contact 50 out of contact with the second contact 52. Similarly, when the solenoid relay piston of the solenoid is moved inward, the armature mechanism 62 is adapted to move the first contact 50 into contact with the second contact 52. In one type of embodiment the solenoid is a bi-polar solenoid. However, any suitable solenoid could be used. Alternatively, any suitable type of armature drive system could be used.
Additionally, there will be a mechanical mechanism affixed to armature 60 that acts as a spring loaded trip mechanism where and when actuated by hand or hot stick 56 will trip (open) the contacts 50/52 of the vacuum bottle 18 to effectively disconnect electrical path 12 from 14. As a safety feature, there is preferrably no provisions for mechanically reconnecting (closing electrical continuity) between 12 and 14 by a manual action of closing 50/52 on vacuum bottle 10.
The control 20, in combination with the armature mechanism 62 and the vacuum bottle section 46 form a first system for opening and closing a path between the first and second connection sections 22, 24. This first system can function automatically based upon real time conditions, such as opening the switch when a downstream fault or other system overload is occurring. In addition to this first system, the vacuum recloser 10 comprises a second system for opening and closing the path between the first and second connection sections 22, 24. The second system allows a user to manually open and close the path by manually connecting and disconnecting the second end 40 of the vacuum bottle section with the second connection section 24. Referring also to
The invention relates to the development of components and devices to modify and improve the application of an in-line switch and will enable it to act as a vacuum recloser. The application of this switch in this fashion eliminates several costly processes and component parts to dramatically reduce production costs while offering similar performance with several additional labor saving and safety related enhancements. Key features include reduced cost, and an ability to unlock a vacuum bottle switch component and swing it down to visually and electrically isolate the downstream circuit for safety reasons. The invention is modular so as to allow offering a 1 phase version and 3 individual 1 phase versions acting in concert to perform single phase trip, 3 phase lockout. The present invention reduces the number of additional products typically required and associated with a typical vacuum recloser installation.
The invention could be offered as a switching device product that requires installation with a WEJTAP system, such as with the shells 32. The WEJTAP system is offered by FCI USA, Inc. under the BURNDY line of products. However, in alternate embodiments, any suitable type of connection system for connecting the assembly 10 with the electrical conductors 12, 14 could be provided. The invention could be incorporated into a distribution class (15-35 KVolt) switching device that is installed directly onto an aluminum bare conductor. The switching device can serve as a vacuum recloser, similar to conventional vacuum reclosers now commonly used and understood in their traditional, but the invention can comprise a novel feature that it is spliced directly in-line and mid span on the bare overhead conductor and not mounted on any supporting structure as they are now traditionally done. By suspending the switching device mid span, many expensive insulating and heavy mounting components are eliminated reduce its installation cost by 30% or more.
The invention can comprise an in-line switch frame, a vacuum bottle connected between energized sections of the in-line switch frame to serve as the switching medium, a driver circuit consisting of at least one solenoid relay for opening and closing the vacuum bottle mechanism, a voltage/current sensing and control circuit to continuous monitor electrical readings and provide intelligence for energy interruption during predetermined conditions that otherwise could be detrimental to the electrical system and other connected electrical components. The system could also comprise a one-way or a two-way communication circuit 66 (see
The set of contacts 50/52 can open and close to energize and de-energize the circuit while the switch remains in the visual representation shown in
After installation, when the line is energized, the power supply module takes power inductively from the energized circuit and allocates it to the recloser control module and the capacitive module section. The recloser electronic control supplies the intelligence to make open/close decisions. Signals from the current transformer and the voltage monitoring section of the power supply module are fed into the electronic control and are continuously monitored. Its decision to act is based on a comparison of what it is seeing (real-time) on the line with what is stored into its pre-installed memory as action criteria. If a line fault or disturbance occurs, it will be fed real-time to the closure control module. If the sensed real-time conditions meet the criteria required for an opened or closed action, it will instruct one or more of the power capacitors to discharge. The discharging capacitors have the required power to cause the solenoid to open or close causing the solenoid relay piston to move forward or backward. The piston is connected through a mechanism that is, in turn, connected to the vacuum bottle armature. The completed action results in the vacuum bottle contacts being opened or closed rapidly.
It should be understood that the foregoing description is only illustrative of the invention. Various alternatives and modifications can be devised by those skilled in the art without departing from the invention. Accordingly, the invention is intended to embrace all such alternatives, modifications and variances which fall within the scope of the appended claims.
This application claims priority under 35 U.S.C. §119(e) to U.S. provisional patent application No. 60/816,654 filed Jun. 26, 2006 which is hereby incorporated by reference in its entirety.
Number | Date | Country | |
---|---|---|---|
60816654 | Jun 2006 | US |