tap switch with an improved monitoring system

专利摘要:
The present invention relates to an on-load tap-changer that has a plurality of modules, each of which is operable to change taps in a transformer winding. The tap-changer includes a motor connected to rotate at least one rod. The at least one stem is connected to the tap-switch modules and is rotationally operable to cause each of the tap-switch modules to perform a sequence of operations that effect a tap-switch. A multi-turn absolute encoder is connected to at least one rod. A monitoring system is connected to the encoder and is operable to determine, from the position of the at least one rod, where the tap-switch modules are in the sequence of operations.
公开号:BR112013025007B1
申请号:R112013025007-0
申请日:2012-03-27
公开日:2021-05-25
发明作者:William James Teising；Robert Alan Elick
申请人:Abb Schweiz Ag；
IPC主号:

专利说明:

BACKGROUND OF THE INVENTION
The present invention relates to tap-changers and more particularly to on-load tap-changers. It is known that a transformer converts electricity at one voltage to electricity at another voltage, both of a higher value and a lower value. A transformer achieves this voltage conversion through the use of a primary winding and a secondary winding, each of which are wound around a ferromagnetic core and comprise a series of turns of an electrical conductor. The primary winding is connected to a voltage source and the secondary winding is connected to a load. By changing the ratio of secondary turns to primary turns, the ratio of output to input voltage can be changed, thereby controlling or regulating the output voltage of the transformer. This ratio can be changed by effectively changing the number of turns in the primary winding and/or the number of turns in the secondary winding. This is done by creating connections between different connection points or “taps” within the winding(s). A device that can create such selective tap connections is called a “tap switch”. Generally, there are two types of tap-changers: on-load tap-changers and off-load or “off-load tap-changers.” An off-load tap-changer uses a circuit breaker to isolate a transformer from a voltage source and then switch from one source to another. one tap to another. An on-load tap-changer (or simply “load tap-changer”) switches the connection between taps while the transformer is connected to the voltage source. A load tap-changer may include for each phase winding, a selector switch assembly, a bypass switch assembly, and a vacuum switch assembly. The selector switch assembly creates the connections to the transformer taps, while the bypass switch assembly connects the taps, through two branch circuits, to one main power circuit. During a tap-changer, the vacuum interrupter assembly securely isolates a branch circuit. The drive stem moves the selector switch assembly, the bypass switch assembly and the vacuum switch assembly. The operation of the selector switch assembly, bypass switch assembly and vacuum switch assembly are interdependent and carefully choreographed. The present invention is directed to a monitoring system to monitor these operations. SUMMARY OF THE INVENTION
In accordance with the present invention, an on-load tap-changer is provided to create tap-changers in a winding transformer. The tap-changer includes a tap-changer module connected to the winding transformer. The tap-changer module includes a bypass switch assembly, a vacuum switch assembly, and a selector switch assembly. A motor is wired to turn at least one shaft. The at least one axis is connected to the tap-switch module and is operable upon rotation to cause the tap-switch module to perform a sequence of operations that effect a tap-switch.
Operations include actuating the bypass switch assembly, actuating the vacuum switch assembly, and actuating the selector switch assembly. A multi-turn absolute encoder is connected to at least one axis and is operable to determine a position of the at least one axis. A monitoring system is connected to the encoder to receive the position of the at least one axis and is operable for a tap change monitoring method. The method includes determining the position of the at least one axis where the tap switching module is in the sequence of operations. BRIEF DESCRIPTION OF THE DRAWINGS
The features, aspects, and advantages of the present invention will be better understood in connection with the following description, appended claims, and accompanying drawings of which:
Figure 1 shows a front elevation view of a tap-changer of the present invention;
Figure 2 shows a schematic view of the tap-changer;
Figure 3 shows tap-changer circuit diagrams in linear, plus-minus, and coarse-fine configurations;
Figure 4 shows a schematic drawing of an electrical circuit of the tap-changer;
Figure 5 shows the electrical circuit progressing through a tap switch;
Figure 6 shows a front view of the interior of a tap-changer tank;
Figure 7 shows a rear view of a front support structure of the tap-changer;
Figure 8 shows a schematic view of a drive system and a tap-changer monitoring system;
Figure 9 shows a front view of a balance panel of a housing for the drive system;
Figure 10 shows a schematic view of the power and communication connections between the components of the drive system and the monitoring system;
Figure 11 shows a schematic sectional view of a servomotor of the drive system;
Figure 12 shows a schematic view of a servodrive of the drive system;
Figure 13 shows a perspective view of the interior of the housing that contains the drive system and the monitoring system;
Figure 14 shows a close-up view of a manual lever assembly and other components of the drive system;
Figure 15 shows a close-up view of a Geneva cam and wheel of the drive system;
Figure 16 shows a perspective view of the cam;
Figure 17 shows a schematic view of a vacuum interrupter monitoring system;
Figure 18 shows a graphical representation of a tap switching map stored in the memory of the monitoring system;
Figure 19 shows a flowchart of a power restoration routine performed by the monitoring system;
Figure 20 shows a flowchart of a first monitoring routine that can be performed by the monitoring system; and
Figure 21 shows a flowchart of a second monitoring routine that can be performed by the monitoring system. DETAILED DESCRIPTION OF ILLUSTRATIVE MODALITIES
It should be noted that in the detailed description that follows, identical components have the same reference numerals, regardless of whether they are shown in different embodiments of the present invention. It should also be noted that in order to clearly and concisely reveal the present invention, the drawings may not necessarily be to scale and certain features of the invention may be shown schematically in some manner.
Referring now to Figures 1 and 2, there is shown a load tap-changer (LTC) 10 incorporated in accordance with the present invention. The LTC 10 is adapted for tank mounting to a transformer. Generally, the LTC 10 comprises a tap-switch assembly 12, a drive system 14 and a monitoring system 16. The tap-switch assembly 12 is enclosed in a tank 18, while the drive system 14 and the monitoring system. monitoring 16 are enclosed in a housing 20, which can be mounted below tank 18. Tank 18 defines an inner chamber within which tap-changer assembly 12 is mounted. The inner chamber holds a volume of dielectric fluid sufficient to emerge from the tap-switch assembly 12. Access to the tap-switch assembly 12 is provided through a door 24, which is pivotable between the open and closed positions.
The tap switching assembly 12 includes three circuits 30, each of which is operable to switch taps in a regulation winding 32 to a phase of the transformer. Each circuit 30 can be used in a linear configuration, a plus-minus configuration, or a coarse-fine configuration, as shown in Figures 3a, 3b, 3c, respectively. In the linear configuration, the voltage across the regulating winding 32 is added to the voltage through a body (low voltage) winding 34. In the plus-minus configuration, the regulating winding 32 is connected to the main winding 34 by a switching switch 36, which allows the voltage across the regulating winding 32 to be added to or subtracted from the voltage across the main winding 34. In the coarse-fine configuration, there is a coarse regulating winding 38 in addition to the regulating (fine) winding 32. A key switch 40 connects the regulating (fine) winding 32 to the main winding 34, either directly or in series with the coarse regulating winding 38.
Referring now to Figure 4, there is shown a schematic drawing of one of the electrical circuits 30 of the tap switch assembly 12 connected to the regulation winding 32 in a plus-minus configuration. The electrical circuit 30 is arranged in first and second branch circuits 44, 46 and generally includes a selector switch assembly 48, a bypass switch assembly 50 and a vacuum switch assembly 52 comprising a vacuum switch 54.
The selector switch assembly 48 comprises first and second movable contact arms 58, 60 and a plurality of stationary contacts 56 that are connected to the leads of the winding 32, respectively. The first and second contact arms 58, 60 are connected to reactors 62, 64, respectively, which reduce the amplitude of the circulating current when the selector switch assembly 48 bridges two taps. The first contact arm 58 is located on the first branch circuit 44 and the second contact arm 60 is located on the second branch circuit 46. The bypass switch assembly 50 comprises first and second bypass switches 66, 68, with the first switch Bypass switch 66 which is located in the first branch circuit 44 and the second bypass switch 68 which is located in the second branch circuit 46. Each of the first and second bypass switches 66, 68 is connected between its associated reactor and the power circuit main. Vacuum interrupter 54 is connected between first and second branch circuits 44, 46 and comprises a fixed contact and a movable contact enclosed in a bottle or housing which has a vacuum therein.
The first and second contact arms 58, 60 of the selector switch assembly 48 can be positioned in a non-bridged position or a bridged position. In a non-bridged position, the first and second contact arms 58, 60 are connected to a single one of a plurality of taps in the winding 32 of the transformer. In a bridged position, the first contact arm 58 is connected to one of the leads and the second contact 60 is connected to another one adjacent to one of the leads. In Figure 4, the first and second contact arms 58, 60 are both connected to the tap 4 of the winding 32, i.e. the first and second contact arms 58, 60 are in a non-bridged position. In a steady state condition, the contacts 164, 166 of the vacuum interrupter 54 are closed and the contacts in each of the first and second bypass switches 66, 68 are closed. Load current flows through the first and second contact arms 58, 60 and the first and second bypass switches 66, 68. Substantially no current flows through the vacuum interrupter 54 and there is no current circulating in the reactor circuit.
A tap change in which the first and second contact arms 58, 60 are moved to a bridged position will now be described with reference to Figures 5a to 5e. The first bypass switch 66 is first open (as shown in Figure 5a), which causes current to flow through vacuum interrupter 54 of first contact arm 58 and reactor 62. Vacuum interrupter 54 is then open to isolate the first branch circuit 44 (as shown in Figure 5b). This allows the close first contact arm 58 to be moved to tap 5 without arcing (as shown in Figure 5c). After this movement the vacuum interrupter 54 is first closed (as shown in Figure 5d) and then the first switch bypass 66 is closed (as shown in Figure 5e). This completes tap switching. At this point, the first contact arm 58 is connected to the tap 5 and the second contact arm 60 is connected to the tap 4, i.e. the first and second contact arms 58, 60 are in a bridged position. In a steady state condition, the vacuum interrupter contacts 54 are closed and the contacts in each of the first and second bypass switches 66, 68 are closed. The 15 reactors 62, 64 are now connected in series and the voltage at their midpoint is half the voltage per tap selection. Circulating current now flows in the reactor circuit.
Another tap switching can be made to move the second contact arm 60 to tap 5 so that the first and second 20 contact arms 58, 60 are on the same tap (tap 5), i.e. to be in a position at not bridge. To do this, the routine described above is performed for the second branch circuit 46. i.e., the second bypass switch 68 is first opened, then the vacuum interrupter 54 is opened, the second contact arm 60 is moved to tap 5 , the vacuum switch 54 is first closed and then the second bypass switch 68 is closed.
In the tap changes described above, current flows continuously during the tap changes, while the first and second contact arms 58, 60 are moved in the absence of current. 30 As best shown in Figure 4, the selector switch assembly 48 can have eight stationary contacts 56 connected to eight taps on winding 32 and one stationary contact 56 connected to a neutral tap (mid range) of winding 32. toggle switch 36 on Terminal B (as shown), toggle switch assembly 48 can move between a neutral position and sixteen distinct (more) rise positions (ie, eight non-bridged positions and eight bridged positions) . With toggle switch 36 on terminal A, selector switch assembly 48 can move between a neutral position and sixteen distinct (minus) down positions (ie, eight non-bridged positions and eight bridged positions). Consequently, the selector switch assembly 48 can move between a total of 33 positions (a neutral position, 16 raise(R) positions and 16 lower(L) positions).
Referring now to Figure 6, three support structures 80 are mounted within tank 18, one for each electrical circuit 30. Support structures 80 are composed of a rigid dielectric material, such as fiber reinforced dielectric plastic. For each electrical circuit 30, the bypass switch assembly 50 and the vacuum switch assembly 52 are mounted on a first side (or front) of a support structure 80, while the selector switch assembly 48 is mounted at the rear of the support structure 80.
Referring now to Figure 7, a second side of one of the support structures 80 is shown. A bypass gear 82 and a vacuum interrupter gear (VI) 92 are mounted on the second side. An isolated shaft 83 is shown connected to the deflection gear 82. The shaft 83 is connected by a drive system 120 (shown in Figure 8) to a main drive shaft 122 (shown in Figure 8) of the drive system 14 The deflection gear 82 is attached to a deflection shaft which extends through the support structure 80 and to the first side of the support structure 80. The deflection gear 82 is connected by a chain 90 to the gear VI 92, which is attached to a VI shaft 94. The VI shaft 94 also extends through the support structure 80 and into the first side of the support structure 80. When the drive system 14 is activated to effect a tap change, the transmission system 120 and shaft VI 83 carry the rotation of the main drive shaft 122 to the deflection gear 82, thereby causing the deflection gear 82 and the deflection shaft VI to rotate. The turning of the deflection gear 82, in turn, is carried. by chain 90 to gear VI 92, which causes gear VI 92 and shaft VI 94 to rotate.
Details of the transmission system 120 are disclosed in Provisional Patent Application No. US 61/467,455 filed March 25, 2011, entitled "Selector Switch Assembly for Load Tap Changer" and Provisional Patent Application No. US 61 /467,822 filed March 25, 2011, entitled “An Improved Tap Changer”, both of which are incorporated herein by reference. On the first side of support structure 80, the offset shaft VI is attached to a cam The offset cam rotates with the rotation of the offset shaft VI and the cam VI rotates with the rotation of the VI axis 94. The offset cam rotates the first and second shift switches 66, 68, while rotating cam VI opens and closes vacuum switch contacts 54. VI shift gears 82, 92 are sized and arranged to rotate the shift cam through 180 degrees to each tap change and to rotate cam VI through 360° to c all tap switching.
Referring now to Figure 8, driveline 120 also connects each selector switch assembly 48 to main driveshaft 122 of drive system 14. More specifically, driveline 120 translates the rotation of main driveshaft 122 into rotational movement of the first and second contact arms 58, 60. This rotational movement is indexed to a common geometric axis and is around it at the center of a circular configuration of the stationary contacts 56. The first and second contact arms 58, 60 are aligned, with the second contact arm 60 disposed on the first contact arm 58 when they are connected to the same stationary contact 56 (in a non-bridged position). The stationary contacts 56 are arranged in a circle, with the neutral N stationary contact which is located at the top and a maximum drop contact 16L and a maximum rise contact 16R which is located towards the bottom. The 56 stationary contact adjacent to the counterclockwise (CCW) neutral contact is hereinafter referred to as the 1L contact. Rotating the first contact arm 58 between neutral contact N and contact 1L drives commutation switch 36. More specifically, rotating the first contact arm 58 in CCW from neutral contact N to contact 1L moves commutator switch 36 to terminal A, while turning clockwise (CW) from the first contact arm 58 of contact 1L to neutral contact N moves switching switch 36 to terminal B. In the mode described above, in which there are 16 positions R, 16 positions L and a neutral position (the neutral N stationary contact), since the first and second contact arms 58, 60 have been moved in CCW and are in the 16L position (both at 16L contact), the first and second contact arms 58, 60 must be moved back in CW to the neutral position before the first and second contact arms 58, 60 can move to any of positions 1 to 16R. Similarly, since the first and second contact arms 58, 60 have been moved in CW and are in position 16R (both at contact 16R), the first and second contact arms 58, 60 need to be moved back in CCW to neutral position before the first and second contact arms 58, 60 can be moved to any of positions 1 to 16L. Moving the first and second contact arms 58, 60 of each circuit 30 between the neutral positions, positions 1L to 16L and 1R to 16R (and the associated operation of each bypass switch assembly 50 and each vacuum interrupter assembly 52 ) can be moved by moving tap switch assembly 12 between taps.
Now also referring to Figures 9 and 10, drive system 14 generally includes a servo motor 124, a servo drive 126, a gearbox 128, and a hand lever assembly 130. Drive system 14 interacts with monitoring system 134 and is controlled by it. As shown above, drive system 14 and monitoring system 134 are mounted within housing 20, which has a front opening through which drive system 14 and monitoring system 134 can be accessed.
As shown in Figure 1, an outer door 136 is pivotally mounted to housing 20 and is operable to close the front opening. Now with particular reference to Figure 9, a balance plate 138 is pivotally mounted to the housing 20, facing inwardly of the outer door 136. The balance plate 138 has a plurality of openings through which the interface devices within the housing 20 are accessible. when the balance plate 138 is in a closed position. For example, a mode switch 140, a socket 142, a mechanical tap position indicator 144, and a human machine interface (HMI) 146 all extend through the openings in the balance plate 138 and/or are accessible through them when balance plate 138 is closed. In addition to providing access to the preceding interface devices, the balance plate 138 has a series of interface devices directly mounted thereon. For example, a neutral state return switch 150 and an up/down switch 152 mount directly to the balance plate 138. The balance plate 138 functions as a second door that protects equipment within the housing 20, while providing access to interface devices
With particular reference to Figure 10, one or more heaters 158, one or more fans 159, one or more temperature sensors, and one or more humidity sensors are installed within housing 20. These devices are electrically connected to monitoring system 134 and controlled by it so as to maintain a suitable environment for the servo drive 126, the monitoring system 134 and the other devices within the housing 20.
Also mounted within housing 20 are a 24 VDC 160 power supply, a 5 VDC 162 first power supply and a 5 VDC 164 second redundant power supply. Servo drive 126, heater 158, fan 159, 24 VDC power supply 160, and first 5 VDC power supply 162 are provided with 120 VAC power to 240 VAC power from a mains supply 165. The second source 5 VDC power supply 164 can be connected to a recovery power supply 166. The monitoring system 134 is powered by the first power supply 5 VDC 162 or, in the event of a failure of mains supply 165, the second 5 VDC 164 power supply.
Referring now to Figure 11, a cross-sectional view of one embodiment of the servomotor 124 is shown. In that embodiment, the servomotor 124 is a brushless AC induction motor having a fixed stator 170 and a rotating rotor 172 attached to a shaft. 174 When voltage is applied to stator 170, current flows in stator 170 and causes current to flow in rotor 172 through magnetic induction. The interaction of the magnetic fields in stator 170 and rotor 172 causes rotor 172 and thus shaft 174 to rotate. The stator 170 is located radially outwardly from the rotor 172 and can be comprised of laminations and turns of an electrical conductor. The rotor 172 may have a "'squirrel cage" construction comprised of stacks of steel laminations separated by spaces filled with conductive material, such as copper or aluminum.
Servomotor 124 may include a brake 176 which holds the position of shaft 174 when power to servodrive 126 and thus servomotor 124 is cut off. Brake 176 may be a spring-type brake or a permanent magnetic-type brake.
Servomotor 124 is provided with feedback device 180, which may be a magnetic decoder or a multi-turn absolute encoder. Magnetic decoders are described in the paragraphs immediately below, while a multi-turn absolute encoder is described further below.
In one embodiment, the feedback device 180 is a single-speed magnetic decoder transmitter, as shown in Figure 11.0. The magnetic decoder transmitter is essentially a rotary transformer that has a rotor winding 182 rotatably disposed within a stationary pair. of SIN and COS stator windings 184, 186, which are positioned 90 degrees apart. Rotor winding 182 is somehow connected to drive shaft 174 so as to rotate therewith. Rotor winding 182 is excited by an AC voltage called the reference voltage (Vr). The voltages induced in the stator windings SIN and COS 184.186 are equal to the value of the reference voltage multiplied by the SIN or COS of the drive shaft angle 174 of a fixed zero point. In this way, the magnetic decoder transmitter supplies two voltages whose ratio represents the absolute position of the shaft. (SIN θ / COS θ = TAN θ, where θ = shaft angle.) The voltages induced in the stator windings SIN and COS 184, 186 are supplied to a micro magnetic decoder controller, which analyzes the signals and generates a signal The feedback signal contains information about the speed and angular position of the drive shaft 174. The microcontroller then delivers the feedback signal to the servo drive 126. In one embodiment of the invention, the feedback signal comprises a series of pulses or beads, in that, for example, 16,384 counts are generated for each 360° turn of driveshaft 174. Thus, one count is generated for about every 0.02 degree movement of driveshaft 174. The counts are positive when servomotor 124 is performed in a first direction, such as to create tap switching from 1R to 2R, and are negative when servomotor 124 is performed in a second direction, such as to create tap switching from 1L to 2L. When viewed from a top, front perspective, as in Figure 13, the first direction is in CW and the second direction is in CCW.
The magnetic decoder transmitter described above is considered a single speed magnetic decoder transmitter due to the fact that the output signals go through only one sine wave (and one cosine wave) as drive shaft 174 rotates through 360° .
It should be appreciated that rather than being a single speed magnetic decoder transmitter, the feedback device 180 may be a multiple speed magnetic decoder transmitter, such as a 4-speed magnetic decoder transmitter in which the output signals follow. through four sine waves as drive shaft 174 rotates 360°. In addition, the feedback device 180 may be a magnetic decoder control transformer, which has two stator windings and two rotor windings. The two rotor windings are provided with excitation signals and position information is derived from the signals of the stator windings. Still further, the feedback device 180 may be a synchronizer, which is similar to a magnetic decoder transmitter, except that there are three stator windings, 120° apart. A magnetic decoder transmitter (single or multiple speed) and a magnetic decoder control transformer are generically referred to as a "magnetic decoder".
Referring now to Figure 12, servodrive 126 controls the operation of servomotor 124 by controlling the power supplied to servomotor 124. Servodrive 126 generally includes a low voltage section 187 and a high voltage section 194. The low voltage section voltage 187 includes a controller 188 and a plurality of associated registers, including a speed register 189, an interrupt register plus 190, an interrupt register minus 191, and a feedback register 192. Controller 188 is microprocessor based and receives 20 command signals from the monitoring system 134 or local devices such as the up/down switch 152. Additionally, the controller 188 receives the feedback signal from the feedback device 180 and derives feedback information from it (e.g., angular position , velocity). Controller 188 compares command information and feedback to generate an error which controller 188 then acts to eliminate. Controller 188 acts on the error using an algorithm such as a proportional integral (PI) algorithm or a proportional integral and derivative (PID) algorithm. Algorithm release is a low power level control signal, which is supplied to high voltage section 194. With 30 using power from mains source 165, high voltage section 194 amplifies the control signal from low power level to a higher power level which is then supplied to servomotor 124. High voltage section 194 can convert AC power to DC power in a rectifier 196 and generate an output to servomotor 124 using a pulse width modulation inverter 198. It is generally observed that higher voltage levels are required to run servomotor 124 at appropriate higher levels and higher current levels are required to provide torque to move larger loads.
As shown above, there are a plurality of registers associated with controller 188. These registers store information that is used by controller 188 to control the operation of servomotor 124. Speed register 189 stores the speed at which servomotor 124 should operate when creating a tap switching. The interrupt register plus 190 stores the number of positive feedback units (eg, beads) of the feedback device 180 that correspond to an interrupt location in the first direction of rotation of the drive shaft 174. Similarly, the register interrupt minus 191 stores the total number of negative feedback units (eg, accounts) of the feedback device 180 that correspond to an interrupt location in the second direction of rotation of the drive shaft 174. The feedback register 192 stores the feedback information drive shaft positions 174 obtained from the feedback signal. In the embodiment described above in which the feedback signal comprises a series of bills, the feedback register 192 stores a running total of the received bills. Since drive shaft 174 rotates twenty times for each tap changeover and 16,384 counts are generated for each turn, the recorder will store 327,680 counts for each tap changer. speed 189, interrupt register plus 190, interrupt register minus 191, and feedback register 192 are lost and, upon restoration of power, the values in the registers are set to zero.
The number of feedback units stored in the interrupt register plus 190 is used by controller 188 to automatically interrupt the rotation of shaft 174 of servomotor 124 in the first direction after it has moved tap switching assembly 12 to tap position 16R or slightly beyond. In the modality described above where the feedback signal comprises a series of beads, the number of beads stored in the interrupt register plus 190 may be +5,242,880 beads or slightly higher. The number of feedback units stored in the interrupt register minus 191 are used by the controller 188 to automatically interrupt the rotation of the axis 174 of the servomotor 124 in the second direction after it has moved the tap switching assembly 12 to the tap position 16L or slightly further In the modality described above where the feedback signal comprises a series of beads, the number of beads stored in the interrupt register minus 190 can be -5,242,880 beads or slightly more (negative beads). From the foregoing, it should be appreciated that controller 188, with the use of feedback units (eg accounts) stored in interrupt register plus 190 and interrupt register minus 191, performs a "sudden electronic interrupt ” which prevents tap switching assembly 12 from going from position 16R through neutral and then to position 1R, and prevents tap switching assembly 12 from going from position 16L through neutral and then to position 1L.
The operation of servodrive 126 is controlled by signals received by controller 188 from monitoring system 134. Two of these signals are hardware (H/W) enabled and software (NMS) enabled in normal mode. When the H/W allowed signal is received, the controller 188 only allows controlling algorithms in the monitoring system 134 to control the tap switching assembly 12. When the NMS allowed signal is received, the controller 188 additionally allows the servo drive. 126 is controlled by command signals from local devices (e.g., up/down switch 152), HMI 146 and remote devices. If neither of the permitted H/W signal or the permitted NMS signal is received, servodrive 126 is “latched”. The servodrive 126 can only be moved from the locked state by pressing a clear button on the HMI 146 by an operator after the problem causing the locked state has been corrected. There is bi-directional communication between servodrive 126 and monitoring system 134 on a CAN 200 bus. Additionally, monitoring system 134 sends digital command signals to servodrive 126 on a drive interface 202 (shown in Figure 8). Digital signals can also be sent from servo drive 126 to monitoring system 134 at drive interface 202. 10 A dynamic braking resistor 206 can be provided to stop rotation of motor rod 174. When turned on, dynamic braking resistor 206 bleeds a voltage from servomotor 124 Dynamic braking resistor 206 can be internal or external to servodrive 126 and can be connected by a transistor. Dynamic braking resistor 206 is operable to stop rotation of motor rod 174 with less than half a revolution (<180°) of additional rotation of motor rod 174. In this regard, it should be noted that the controller 188 of servo drive 126 uses acceleration and deceleration values stored in a non-volatile memory (eg, EEPROM) of servo drive 126 20 to control the rate at which motor rod 174 is started and stopped, respectively. These values can be changed by an authorized service person when the tap-changer 10 is turned off for service.
Referring again to Figure 8, servomotor 124 is connected to planetary gearbox 128, which is operable to multiply the torque of servomotor 124 and increase its torsional stiffness. This allows the 124 servo motor to be reduced in size and operate over its optimum range. In addition, the 128 planetary gearbox minimizes reflected inertia for maximum acceleration. Planetary gearbox 128 includes an output shaft and planetary gears and is secured to the servomotor shaft 124 by self-allocation of input pinion clamps. In one embodiment, planetary gearbox 128 is operable to produce one turn of its output rod for every ten ten revolutions of motor rod 174.
Referring now also to Figure 13, planetary gearbox output rod 128 is connected to main drive rod 122, which extends upwardly through an opening in a shelf 208 secured between two interior side walls. Above shelf 208, main transmission rod 122 extends upward through an opening in housing 20 and into tank 18. Main transmission rod 122 enters tank 18 through a through assembly 210 secured within a opening in a bottom wall of tank 18. Pass-through assembly 210 includes a gasket to seal the opening in tank 18. Within tank 18, main drive rod 122 is connected to selector switch assemblies 48, to key assemblies bypass 50 and to vacuum interrupter assemblies 52 via drive system 120. A turn of main drive rod 122 effects a tap-changer as described above. More specifically, a 720° turn of the main drive rod 122 results in a complete tap-changer. Since ten revolutions of motor rod 174 produces a rotation of main drive rod 122, servomotor 124 rotates 20 times for each tap-changer. The rigid control provided by the drive system 14 allows the rotation of the main transmission rod 122 to be stopped at the end of a tap-changer with less than 15° of additional rotation of the main transmission rod 122.
Referring now also to Figures 14 and 15, the manual lever assembly 130 includes an enlarged manual lever gear 214 and a propulsion device 216. The manual lever gear 214 is secured to the main drive rod 122 above the shelf 208. A block 218 is secured to an underside of the hand lever gear 214. The drive device 216 is mounted on the shelf 208, next to the hand lever gear 214. The drive device 216 includes a gear that engages the drive gear 208. Handlever r 214 and an internal mechanism that transforms a turn of a crank 220 (shown in Figure 13) into a turn of the gear and thereby the handlever gear 214 and the main drive rod 122. The handle 220 is It is normally stored elsewhere and is only used when manual movement of the main drive rod 122 is required. The crank 220 has a recessed end adapted to securely receive a contoured rod 222 of the internal mechanism. Stem 222 is disposed within socket 142 in propulsion device housing 216. Stem 222 may have a hexagonal cross-section as shown. When the end of crank 220 is inserted into socket 142 and engaged with rod 222, crank 220 may be manually rotated to rotate main drive rod 122, such as to make a full or partial tap changeover.
Mode switch 140 is mounted adjacent to propulsion device 216. (It should be noted that although mode switch 140 is not shown in Figure 13, it should be considered present). Mode switch 140 is connected to servo actuator 126 and monitoring system 134 and includes four positions: hand lever, off, local and remote. In local mode, mode switch 140 integrates signals from local control devices (such as up/down switch 152) to control servo drive 126 and thereby servo motor 124. In remote mode, switch mode 140 integrates signals from remote locations to control servo drive 126 and thus servo motor 124. In manual lever mode, mode switch 140 disconnects a power to servo drive 126 and signals monitoring system 134 to denying the H/W enable signal to the servo drive 126, and thereby rendering the servo motor 124 inoperative. Mode switch 140 has a rotatable crank 223 for moving between the four positions. An irregularly shaped plate 224 with an enlarged opening is connected to crank 223 so as to rotate therewith. Plate 224 is pivotable between a non-locking position where the opening is aligned with socket 142 in the housing and a locking position where plate 224 locks socket 142 in the housing. Plate 224 is in the non-locking position only when crank 223 is in a position that places mode switch 140 in hand lever mode. Thus, crank 220 can only be inserted into socket 142 and in engagement with rod 222 when 5 mode switch 140 is in hand lever mode. In that way, the propulsion device 216 can only be used to manually move the main drive rod 122 when a power is cut to the servo motor 124.
Below the hand lever gear 214, a first gear 226 (shown schematically in Figure 8) is secured to the main drive shaft 122. The first gear 226 is driveably engaged with a second enlarged gear 230 which is secured to a first side shaft 232. The first and second gears 226, 230 are sized so that two turns of the main transmission rod 122 causes the first side rod 232 to make one turn, ie there is a reduction of two to one. In this way, the first side rod 232 will rotate 360° for each tap-changer. Position marks are provided on a top surface of the second gear 230. These marks, relative to a reference point 234, provide a visual indication of where the tap-changer assembly 12 is located in a tap-changer. The marks and reference point 234 are visible to an operator who manually moves the main drive rod 122 with the use of the propulsion device 216, and thereby helps the operator to properly move the tap changer assembly 12 into a position. desired. A pinion 236 (shown schematically in Figure 8) is attached to the second gear 230 and extends upwards therefrom. Pinion 236 is located towards the center of second gear 230 and actionably engages the teeth of a Geneva wheel 238, 30 which is sized and constructed to rotate 10 degrees for each complete rotation of second gear 230, i.e., to each tap-changer. The Geneva wheel 238 is secured to a second side rod 240 which is actionably connected to a mechanical tap position indicator 242 which shows tap switch positions N, 1-16L and 1-16R arranged at a circular configuration, similar to a clock face. Second side rod 240 is also connected to an extension rod that extends through a plurality of circuit boards 244. Conductive wiper arms are secured to the extension rod and engage contacts mounted on circuit boards 244 during rotation of the extension rod, and thereby generate signals representative of the position of the main transmission rod 122 (and the current tap position of the tap switching assembly 12). These signals are provided to external devices.
Referring now also to Figure 16, a cam 248 is secured to the Geneva wheel 238 so as to rotate therewith. A side surface of a central region of cam 248 helps define an endless ridge 250. The central region is substantially circular except for an indentation 252. Thus, the ridge 250 has a radially outer portion (outside of indentation 252) and a radially internal portion (inside the indentation). A cam follower 254 (shown in Figure 13) is disposed on ridge 250 and is secured to an arm 256 that is pivotally mounted at a first end to shelf 208. A frame with a block 260 projecting therefrom is secured. to a second end of arm 256. Block 260 is movable between an engaged position and an disengaged position. In the engaged position, block 260 extends below hand lever gear 214, where it can be brought into contact with block 218. In the disengaged position, block 260 does not extend below hand lever gear 214 and, therefore, it cannot be brought into contact with block 218. Block 260 is moved between the engaged and disengaged positions by a movement of arm 256, which is controlled by the movement of ridge 250 relative to cam follower 254. cam follower 254 is on the radially outer portion of ridge 250, arm 256 is stationary and holds block 260 in the disengaged position. When cam follower 254 moves to the radially inner portion of ridge 250 (relatively), cam follower 254 moves radially inward, which causes arm 256 to rotate inward and move block 260 into position. engaged When block 260 moves to the engaged position, it will be placed in contact with block 218 in manual lever gear 214 if manual lever gear 214 completes its current revolution in its current direction and tries to continue moving in it direction. The contact between blocks 218, 260 prevents further movement of the hand lever gear 214 in its current direction and is considered a sudden mechanical interruption.
Mechanical sudden interruption is implemented to prevent tap switching assembly 12 from going from position 16R to neutral and then to position 1R, and to prevent tap switching assembly 12 from going from position 16L to neutral and then to the 1L position. In other words, mechanical sudden interruption prevents 360° or greater rotation of the first and second contact arms 58, 60 in one direction. Due to the contact location of blocks 218, 260, mechanical sudden interruption does not need to be implemented directly in 16L and 16R. Instead, the main drive rod 122 can be allowed to rotate about another 90° beyond 16L and beyond 16R. Electronic hard-stop and mechanical hard-stop can be configured to be deployed at almost the same time. Alternatively, electronic hard cut and mechanical hard cut can be configured so that one is deployed before the other. For example, Electronic Hard Cut and Mechanical Hard Cut can be configured so that Electronic Hard Cut is implemented first.
Since cam 248 rotates 10 degrees for each tap switch, movement from neutral to 16L and from neutral to 16R corresponds to a rotation of cam 248 of about 160°. In this way, cam 248 is constructed and positioned so that cam follower 254 will be in the radially external position of ridge 250 at 160° of rotation of cam 248 either in the CW or CCW direction from the neutral position and thereafter , will enter the radially inward (relatively) position to move block 260 into the engaged position. Thus, the radially inner portion of the Christian comprises about 40° of the Christian 250 and when the tap changer assembly 12 is in the neutral position, the center of the indentation 252 is disposed facing the cam follower 254.
Referring in particular to Figure 8, a disk 262 of a multi-turn absolute encoder ("MTAE") 264 is connected to the first side rod 232 so as to rotate therewith. Disc 262 is composed of glass or plastic and has a pattern formed thereon, such as by photographic deposition. The pattern comprises a series of trajectories that extend radially. Each trajectory is comprised of areas of different optical properties, such as areas of transparency and opacity. A detector unit 266 of the MTAE 264 reads these paths as the disk 262 rotates and outputs a position signal representative of the angular position of the first side rod 232. The detector unit 266 includes infrared emitters and receivers. Infrared emitters are mounted on one side of disk 262 and infrared receivers are mounted on the other side of disk 262. As disk 262 rotates, the light pattern of each path received by infrared receivers produces a unique code that represents an absolute position of the first side rod 232 at 360°.
A plurality of code carriers 267 of the MTAE 264 are also connected to the first side rod 232 so as to rotate with it, but sequentially slower. Each of the 267 code carriers is a magnetic body comprised of alternating north and south poles. The magnetic fields generated by the rotation of the 25 code carriers 267 are detected by the detector unit 266 to provide a measure of the number of rotations of the first side rod 264.
Since the positions of disk 262 and code carriers 267 are not changed upon a power failure, the MTAE 264 30 effectively has an on-board memory that is maintained in the event of a power failure. In one embodiment of the present invention, the MTAE 264 can determine and store up to 4,096 turns of the first side rod 232.
Also in this mode, the MTAE 264 has 33,554,432 positions per revolution of the first lateral rod 232. The absolute position of the first lateral rod 232 at 360° and measuring the number of turns of the first lateral rod 232 provides a multi-turn position ( or simply a position) of the first lateral rod 232. Through the relationships described herein, the position of the first lateral rod 232 is used to determine the position of the main transmission rod 122, the location of the tap changer assembly 12 in a tap-changer and the location of the tap-switch assembly 12 among the taps, i.e., a tap position. The MTAE 264 is connected to the monitoring system 134 through a communication line, such as an EnDat 2.2 interface cable, which is a bi-directional digital interface that is capable of transmitting the position of the MTAE 264's first side rod 232 thus how to transmit or update information stored in the MTAE 264 (such as diagnostic data). In addition to being connected to the MTAE 264, the monitoring system 134 is connected to the servodrive 126, a vacuum interrupter (VI) monitoring system 265 and various other inputs such as the environmental control/monitoring devices within the housing 20. Monitoring system 134 is confined in a housing unit 268 (shown in Figure 13) mounted within housing 20 Monitoring system 134 comprises HMI 146, at least one microprocessor 270 and non-volatile memory 272, such as as EEPROM. The HMI 146 includes a display and input devices such as a membrane keypad pushbutton.
Referring now to Figure 17, there is shown a schematic drawing of the VI monitoring system 265, which generally includes three current detector modules 276 (one for each circuit 30), three infrared emitters 278 (one for each circuit 30), three infrared receivers 280 (one for each circuit 30) and one differential signal transceiver 282.
In each circuit 30, current detector module 276 is connected in series to vacuum interrupter 54. When current in excess of 6 amps is passed through vacuum interrupter 54, current detector module 276 rectifies sinusoidal current to generate electrical pulses. which have a frequency corresponding to the frequency of the current, which is in the range of about 50 Hz to about 60 Hz. The sinusoidal current rectification can be a half wave rectification or a full wave rectification. In one embodiment of the present invention, the rectification of the sine current is half wave so as to produce a pulse per sine wave. The infrared emitter 278 converts the electrical pulses into light pulses and transmits them to the infrared receiver 280 through a fiber optic link 284. The infrared receiver 280 detects the light pulses and generates a pulsed electrical signal in answer to it. This signal, which is a one-end signal, is then transmitted to the differential signal transceiver 282. As is known, a one-end signal is transmitted over two cables, one of which carries a varying voltage. which represents the signal, while the other among them is connected to a reference voltage, normally ground. Differential signal transceiver 282 converts the signal at one end into a digital differential signal, that is, two complementary signals that are transmitted on two separate cables. Differential signal transceiver 282 can be built according to Ethernet, RS-422 or RS-485 protocols. In one embodiment, the differential signal transceiver 282 is constructed in accordance with the RS-485 protocol, which defines the electrical characteristics of drivers and receivers for use in balanced digital multipoint systems. Converting the signal from one end to the differential signal helps to isolate the signal from an environmental noise present in and around tap changer 10.
The differential signals generated by the differential signal transceiver 282 are transmitted to the monitoring system 134 via a cable. Within the monitoring system 134, the differential signal receivers convert the differential signals back to one-end signals, which are then supplied to the microprocessor 270. The microprocessor 270 analyzes the timing of the signals and the phase relationship between the signals. three signals to monitor and control a tap-changer. More specifically, during certain stages of a tap-changer, a current must not flow through any of the vacuum switches 54 and at other stages of the tap-changer, a current must flow through the vacuum switches 54 and it must be separated by 120° between the phases. The presence of pulses in a signal to a vacuum interrupter 54 provides an indication to the microprocessor 270 that a current flows through the vacuum interrupter 54. Conversely, the absence of pulses in a signal to a vacuum interrupter 54 provides a indication 10 to the microprocessor 270 that a current does not flow through the vacuum switch 54. Since the pulses in the signals have a frequency that corresponds to the frequency of the current through the vacuum switches 54, the displacement of the pulses between the three signals (when a current flows) must correspond to the 120° difference between the phases.
Referring now to Figure 18, there is shown a simplified graphical representation of a tap switch map 288 that is stored in memory 272 of monitoring system 134 and that is used by monitoring system 134 to control and/or monitor operation. of the tap-changer assembly 12 during a tap-changer procedure. Map 288 includes stages or operations A to H delimited by dashed lines. Operations A to H correspond to "in position", "bypass switch open", "vacuum switch (VI) open", "selector switch open", "selector switch closed", "VI closed", "bypass switch closed" and "in position", respectively. The shaded blocks in the dashed lines indicate ± margins in degrees of rotation. The location of tap switch assembly 12 on map 288 is based on the position of the first side rod 232, which is obtained from the MTAE 264 position signal. The position just before the D operation (“switch switch open”) is designated as the point of no return (“PONR”). The selector switch (the first contact arm 58 or the second contact arm 60) is opened when it is moved out of an initiating tap (initial stationary contact 56) as it is moved to a terminating tap (final stationary contact 56) during a tap changer. the monitoring system 134 receives or generates an alarm on the PONR or after it, the monitoring 134 will cause tap switching assembly 12 to complete tap switching and then lock servo drive 126. If, however, monitoring system 134 receives or generates an alarm before PONR, monitoring system 134 will cause tap switch assembly 12 to interrupt tap switching, return to the previous tap position, and then lock servo driver 126.
Tap switch map 288 stored in memory 272 of monitoring system 134 is more detailed than what is graphically shown in Figure 18. Map 288 includes the A-H operations for a tap switch from one tap to the other. In addition, for the 1LaNeNa1L switching taps, the map 288 further includes data for the switching key 36, i.e., switching between open and closed. For each operation, map 288 includes the degrees of rotation of the first side rod 232 at which the operation begins, the elapsed time (from the start of tap switching) at which the operation is to start, the change in elapsed time (delta time ) that must occur from the start of the previous operation and the number of pulses that can/should be received from the VI 265 monitoring system during the delta time to indicate whether a current flows through the relevant vacuum interrupter 54. delta time is the time window in which the monitoring system 134 decides whether tap switching proceeds properly (in relation to a current through the vacuum interrupter 54). The elapsed time values stored in map 288 are in milliseconds. In relation to that. it is noted that the monitoring system 134 is programmed to control the servomotor 124 to perform a tap-changer in one or two time periods, that is, 1 second and 2 seconds. Thus, map 288 includes the data for the operations described above or for a 1 second tap switch or a 2 second tap switch. However, the values for map 288 can be changed from them for a 1 second tap change to the same for a 2 second tap change and vice versa at the factory in which the tap changer 10 is manufactured or by an authorized service person in the field when the tap-changer 10 is turned off for service. In another embodiment of the invention, the map 288 includes the data for the operations described above for both a 1 second tap switch and a 2 second tap switch and a user can select a 1 second tap switch or a tap change 2 second bypass via HMI 146 or from a remote location.
It should be noted that in addition to map 288, the rotation speed of motor rod 174 for a 1 second tap change and/or a 2 second tap change is/are stored in memory 272. Negative and positive feedbacks that are used to implement the electronic hard interrupt are stored in memory 272. The stored speed for the programmed/selected tap switching (1 or 2 seconds) is supplied to servodrive 126 (ie, the register of speed 189) if power is cut to servo drive 126, as described in more detail below. Similarly, negative and positive feedback units to implement electronic sudden interruption are provided to servodrive 126 (i.e., positive interruption register 190 and negative interruption register 191, respectively) if a power is cut to servodrive 126, also as described in more detail below.
Monitoring system 134 performs software-implemented routines to monitor and control the operation of the tap-switch assembly 12. The software code for these routines is stored in memory 272 of monitoring system 134 and is executed by microprocessor 270. One of the routines is a power restoration routine 290 (shown in Figure 19) that is implemented when a power to monitoring system 134 and/or servo drive 126 is cut and then restored. As defined above, when a power to servodrive 126 is lost, all data stored in speed register 189, positive interrupt register 190, negative interrupt register 191 and feedback register 192 is lost and upon a reset of power, the values in the registers in the registers. When power to monitoring system 134 is restored after a power failure, an initialization program is automatically started at step 292 of the power restoration routine 290. The initialization program performs a startup procedure that includes: (i. ) read parameters from memory 272, (ii.) establish communication with servo drive 126 (iii.) establish communication with MTAE 264, (iv.) determine current tap position of tap switching assembly 12 based on MTAE 264 information, (v.) define an event record and (v.) output 4 to 20 mA signals representative of the current tap position to the automatic voltage regulator for the transformer. Although communication is established with servodrive 126, monitoring system 134 does not provide H/W enable signal or NMS enable signal to servodrive 126.
Once the init program finishes running, an energized state enters step 294. The energized state has four sub-states or modes that are determined by the switch, namely: local, hand lever, remote and off. The three inputs (local, hand lever and remote) of the switch are mutually exclusive. If none of these inputs are asserted, the off substate is entered.
After monitoring system 134 enters the powered state, a determination is made in step 296 whether monitoring system 134 is in local mode or remote mode. If monitoring system 134 is in either local mode or remote mode, the routine 290 proceeds to step 298 in which the H/W enable signal is transmitted to servodrive 126 via digital inputs through drive interface 202. After step 298, monitoring system 134 proceeds to step 300, at that the position (0 to 360° and amount of rotations) of the first side rod 232 measured by the MTAE 264 is converted to the position units (eg counts) of the motor rod 174 measured by the feedback device 180, i.e. the position units of the motor rod 174 are calculated from the position output by the MTAE 264. The calculated position units are then transmitted to the servodrive 126 via the CAN bus 200 in step 302 and are stored in the reg feedback istrator 192 in it. Also in step 302, the values for the rotation speed of the motor rod 174 and the negative and positive feedback units to implement the electronic sudden interruption are transmitted to the servodrive 126 through the CAN bus 200 and are stored in the speed register 189 , in positive interrupt register 190 and negative interrupt register 191, respectively. Thereafter, the monitoring system 134 proceeds to step 306 in which routine 290 determines whether tap switching assembly 12 is off-tap, that is, between taps, using information from MTAE 264. tap 12 is not out of tap, the routine proceeds directly to step 308. If, however, tap switch assembly 12 is out of tap, the monitoring system 134 proceeds to step 310, in which the tap system. monitoring 134 determines whether tap switching assembly 12 is before the PONR, or is at or beyond the PONR. If tap switching assembly 12 is before PONR, monitoring system 134 sends an instruction in step 312 over CAN bus 200 to servo driver 126 to control servo motor 124 to move tap switching assembly 12 back to the previous derivation. If tap switching assembly 12 is at or beyond the PONR, monitoring system 134 sends an instruction in step 314 via CAN bus 200 to servo driver 126 to control servo motor 124 to move tap switching assembly 12 forward to the next lead. After step 312 or step 314, monitoring system 134 proceeds to step 316 in which monitoring system 134 polls servo driver 126 to determine whether movement of tap switch assembly 12 is complete. If so, the monitoring system 134 proceeds to step 308 in which an NMS enable signal is transmitted to the servo drive 126 via digital inputs via the drive interface 202. At that point, the tap-switch assembly 12 it is in normal operation-remote-powered mode or normal operation-local-powered mode, as appropriate.
If only servodrive 126 loses power, the initialization program is not started and the power restoration routine starts at step 298.
It should also be noted that when monitoring system 134 is in manual lever mode or off mode and then is moved to either local mode or remote mode, monitoring system 134 performs steps 298 and following. This happens regardless of whether there was a power failure or not.
In addition to performing power restoration routine 290, monitoring system 134 also performs monitoring routine 320 that supervises each tap switching operation. The monitoring system 134 uses the tap switching map 288 stored in memory 272, the position of the first side rod 232 of the MTAE 264, and the information from the monitoring system VI 265 to perform the monitoring routine 320. When a command stops a tap-changer is made (e.g., a raise command is issued from the up/down switch 152), the monitoring system 134, in step 322, first determines whether tap switching starts from a valid tap position. . If tap switching assembly 12 is out of tap, monitoring system 134 proceeds to step 323, where monitoring system 134 neutralizes the 30 NMS enable signal to servo drive 126 and then returns to routine 290 and performs step 310 and the steps thereafter. Upon completion of step 308, monitoring system 134 returns to routine 320 and then allows tap switching to proceed to open bypass switches (66 or 68) in a B operation. to be in bypass in step 322, monitoring system 134 allows bypass switching to proceed directly to open bypass switches (66 or 68) in operation B. Monitoring system 134 in step 324 determines whether the bypass switches (66 or 68) in step 324 bypass (66 or 68) have opened (as determined from the position of the first side rod 232) within a predetermined period of time from the start of tap switching. If the bypass switches open at the right time, monitoring system 134 proceeds to step 326, where monitoring system 134 determines whether a current flows through all vacuum switches 54. Whether a current flows through all the vacuum switches 54, the monitoring system 134 allows tap switching to proceed to open the contacts of the vacuum switches 54 in a C operation. The monitoring system 134, in step 328, determines whether the contacts of the vacuum switches 54 have been opened (as determined from the position of the first side rod 232) within a predetermined time period of the bypass switches (66 or 68) being opened. If the vacuum interrupter contacts 54 have opened at the right time, the monitoring system 134 proceeds to step 330 to determine if no current flows through any of the vacuum interrupters 54 If the vacuum interrupter contacts 54 have opened on time and no current flows through the vacuum switches 54, the monitoring system 134 allows tap switching to continue to move 25 the first contact arms 58 or the second contact arms 60 to the next tap and to close the vacuum interrupter contacts 54 At step 332, the monitoring system 134 determines whether a current flows through the vacuum interrupters 54 within a predetermined period of time from the closure of the vacuum interrupter contacts 54 (as determined from the position of the first side rod 232). If a current flows through the vacuum switches 54 within the predetermined period of time from the closing of the contacts of the vacuum switches 54, the monitoring system 134 allows tap switching to continue to close the bypass switches (66 or 68 ). At step 334, the monitoring system 134 determines whether the bypass switches (66 or 68) have closed (as determined from the position of the first side rod 232) within a predetermined period of time from the closing of the switch contacts to vacuum 54. If the bypass switches (66 or 68) closed at the right time, the monitoring system 134 determines in step 336 that the bypass switch has successfully completed.
If during said monitoring routine 320, any one of the determinations is negative, the monitoring system 134 will first stop tap switching and return to the initial tap or complete tap switching, depending on where the negative determination is and then will lock servodriver 126. If the determination is negative in step 332 or thereafter, monitoring system 134 will instruct servodrive 126 to complete tap switching in step 338 and then lock the servodrive 126 at step 340. If the determination is negative at step 330 or earlier, the monitoring system 134 will instruct servodrive 126 to stop tap switching and return to the initial tap at step 344 and then lock the servodrive 126 at step 346.
After each determination in monitoring routine 320, monitoring system 134 makes an entry in the event log that describes the result of the determination. For some of the negative determinations, monitoring system 134 will input the probable cause of the problem. For example, if there is a negative determination at step 324, monitoring system 134 will include in the event log entry that there is a bypass key failure.
After a tap change has been successfully performed, the monitoring system 134 monitors the servo drive 126 to ensure that the servo drive 126 is holding the servo motor 124 in place so as to maintain the current tap position. If monitoring system 134 watches the output of servodrive 126 move within a predetermined amount of deviation, monitoring system 134 will move the output of servodrive 126 again. If, however, the output of servo drive 126 moves beyond the predetermined amount of deviation, monitoring system 134 will issue an alarm and lock servo drive 126.
In place of monitoring routine 320, other monitoring routines can be implemented to supervise a tap switching operation. For example, in another modality, a monitoring routine 420 can be implemented, as shown in Figure 21.
When a command for a tap change is made (for example, an up command is issued from the up/down switch 152), the monitoring system 134 in step 422 first determines whether the tap change is at the beginning from a valid tap position. If tap switching assembly 12 is out of tap, monitoring system 134 proceeds to step 423, where monitoring system 134 overrides the NMS enable signal to servo drive 126 and then returns to routine 290 and performs step 310 and the steps thereafter. Upon completion of step 308, monitoring system 134 returns to routine 420 and then allows tap switching to proceed to open bypass switches (66 or 68). If the tap switching assembly is determined to be tapped in step 422, the monitoring system 134 allows tap switching to proceed directly to open bypass switches (66 or 68) in operation B. In step 424, monitoring system 134 determines whether current is detected through all vacuum switches 54 for a minimum amount of time in the period between operations B and C. If current is detected through all vacuum switches 54 by the minimum amount of time, the monitoring system 134 allows tap switching to proceed to open the contacts of the vacuum switches 54 in operation C. In step 426, the monitoring system 134 determines that no current has been detected across all of the switches a. vacuum 54 in the period between operations C and D. If no current is detected across all vacuum switches 54, monitoring system 134 allows switching proceed to open the first contact arms 58 or the second contact arms 5 60 in operation D, ie to move the first contact arms 58 or the second contact arms 60 out of the initial leads (initial stationary contacts 56 ) on tap switching. In step 428, the monitoring system 134 determines that no current is detected through all vacuum switches 54 in the period between 10 operations D and E. If no current is detected through all vacuum switches 54, the system monitoring 134 allows tap switching to proceed to close the first contact arms 58 or the second contact arms 60 in the AND operation, i.e. to move the first contact arms 58 or the second contact arms 60 in 15 engagement with the final taps (end stationary contacts 56) in tap switching. In step 430, monitoring system 134 determines that no current is detected through all vacuum switches 54 in the period between operations E and F. If no current is detected through all vacuum switches 54, the system monitors - 20 turning 134 allows tap switching to proceed to close the contacts of the vacuum switches 54 in operation F. In step 432, the monitoring system 134 determines whether current is detected through all of the vacuum switches 54 by an amount minimum time in the period between operations F and G. If current is detected across 25 all vacuum switches 54 for the minimum amount of time, monitoring system 134 allows tap switching to proceed to close the bypass switches (66 or 68) in operation G and complete tap switching in operation H. In step 436, monitoring system 134 determines whether all tap switching has been completed within 30 the required amount of time, which is a little less than 1 second for a 1 second tap and a little less than 2 seconds for a 2 second tap changeover. If tap switching was completed in the appropriate time, monitoring system 134 determines that tap switching was successfully completed in step 438. If tap switching was not completed successfully, monitoring system 134 determines that there is a problem and locks servodrive 126 in step 442.
If during said monitoring routine 420, any one of the determinations is negative, the monitoring system 134 will either stop tap switching first and return to the initial tap or complete tap switching, depending on where the determination is made. negative is, and will then lock servodriver 126. If the determination is negative in step 428 or thereafter, monitoring system 134 will instruct servodrive 126 to complete tap switching at step 440 and lock, then , servodrive 126 at step 442. If the determination is negative at step 426 or earlier, monitoring system 134 will instruct servodrive 126 to stop tap switching and return to the initial tap at step 444 and lock, then servodrive 126 in step 446.
Unlike monitoring routine 320, monitoring routine 420 does not check the timing of operations during tap switching performance. Routine 420 only checks the total tap switching time upon completion of tap switching in step 436. It should be noted that routine 420 can be modified to additionally include one or more time checks during tap switching performance. For example, a time determination can be made before the PONR, such as whether the vacuum interrupter contacts 54 have opened in operation C within a predetermined amount of time from the start of tap switching in operation A. of the vacuum switches 54 not opening within the predetermined amount of time, the monitoring system 134 may proceed to step 444 and then lock servodrive 126 at step 446. Additionally, or alternatively, a time determination may be made after the PONR. For example, a determination can be made whether the vacuum interrupter contacts 54 have closed in operation F within a predetermined amount of time from the closing of the first contact arms 58 or the second contact arms 60 in operation E. vacuum switches 54 did not close within the predetermined amount of time, monitoring system 134 can proceed to step 440 and then lock servodrive 126 in step 442.
In the referred descriptions of routines 320, 420, references to the monitoring system 134 which allows tap switching to continue after a determination should not be interpreted as meaning that the tap switching procedure waits for the monitoring system 134 to make the determination of the same before the tap switching procedure continues. The tap switching proceeds in a continuous fashion and the monitoring system 134 makes the same determinations within the time deltas between various 15 operations. Tap switching is interrupted only if an error is detected.
In addition to routine monitoring 320 or 420, monitoring system 134 also performs other monitoring activities. For example, monitoring routine 134 continuously monitors the position 20 of the first side rod 232 measured by the MTAE 264 and the position of the motor rod 174 measured by the feedback device 180. If the two measurements do not match (after conversion), the monitoring system 134 will generate an alarm and lock servodrive 126 (after allowing a tap changeover to continue or moving back to an initial tap, as the case may be). The monitoring system 134 also monitors the three signals from the VI monitoring system 265 to ensure that the compensation of the pulses between the three signals (when current is flowing) matches the 120° difference between the phases. If negative, monitoring system 134 will generate an alarm. In addition to generating an alarm, monitoring system 134 can also lock servodrive 126 as described above.
Another operation performed by monitoring system 134 is a return to neutral operation. Return to neutral operation can be performed when monitoring system 134 is in local mode or in remote mode. When this operation is initiated, the monitoring system 134 causes the servomotor 126 to move the tap switching assembly 12 to the neutral position, regardless of where the tap switching assembly 12 is currently located. The neutral return operation can be initiated by an operator activating the neutral return switch 150 on the balance board 138, or through an activation of a neutral return switch located at a remote location, such as like a control room or a nearby control booth.
An additional operation performed by monitoring system 134 is a step-by-step shift operation, which can only be performed when monitoring system 134 is in local mode. The step-by-step shift operation is performed together with an up/down operation, which will be described first. Up/down operation can be performed in a continuous mode (which is the default) or in a step-by-step mode. The up/down operation can be performed using the up/down switch 152 on the balance board 138 when the monitoring system 134 is in local mode, or an up/down switch at a remote location when the monitoring 134 is in remote mode. When an up/down switch is actuated in continuous mode, tap switch assembly 12 continues to make tap switches (to reduce or raise the voltage across the main winding 34, depending on whether the switch is actuated to lower or raise ) while the switch is held in the activated position. When an up/down switch is actuated in step-by-step mode, tap switch assembly 12 only makes one tap switch (to reduce or raise the voltage across the main winding 34, depending on whether the switch is actuated to reduce or raise) regardless of how long the switch is held in the actuated position. In order to make another tap changeover, the switch must be moved to the off state of the switch and then actuated again to raise or lower. The step-by-step shift operation is initiated by an operator who first actuates a step shift button on the HMI 146 and then actuates the up/down switch 152 on the balance plate 138 When stepping operation is initiated, monitoring system 134 causes servo drive 126 to move servo motor 124 at a much slower rate than when a normal up/down operation is performed. For comparison, the speed of motor rod 174 during a 1 second tap change is 1300 RPM and during a 2 second tap change is 650 RPM. During stepping operation, the speed of motor rod 174 is approximately 150 RPM. Consequently, the speed of the motor rod 174 during the step shift operation is approximately 8.6 times slower than a 1 second tap changeover.
Yet another operation performed by monitoring system 134 is a transformer turns ratio (TTR) operation. TTR operation can be performed when monitoring system 134 is in local mode or in remote mode. When TTR operation is initiated, monitoring system 134 causes servomotor 126 to move tap switch assembly 12 through a predetermined sequence of tap switches for testing purposes. The predetermined sequence can be from neutral to 16 R, then back to neutral and then 1 to 16 L, or only neutral to 16 R, or only neutral to 16 25 L, or some other sequence. As for the step-by-step shift operation, the TTR operation is performed together with an up/down operation. More specifically, a TTR command button on HMI 146 or a TTR command button at a remote location is triggered first. Then, the up/down switch 152 on the balance plate 138 or a remote up/down switch is actuated.
Regardless of whether the up/down switch is engaged for up or down, monitoring system 134 causes servo motor 126 to move tap switching assembly 12 through the sequence. set of tap switches.
It is to be understood that the description of the exemplary embodiment(s) referred to is intended to be illustrative only, rather than exhaustive, of the present invention. Those individuals of ordinary skill in the art will be able to make certain additions, deletions and/or modifications to the embodiment(s) of the disclosed subject matter without departing from the spirit of the invention or the scope thereof, as defined by the appended claims.

权利要求:
Claims (15)
[0001]
1. On-load tap-changer (10) for making tap-changer switches in a transformer winding, characterized in that the tap-changer comprises: (a.) a tap-changer module connected to the transformer winding and comprising a bypass switch assembly (50), a vacuum switch assembly (52) and a selector switch assembly (48); (b.) a motor (124) connected to rotate at least one rod (174, 122, 232), wherein the at least one rod (174, 122, 232) is connected to the tap-switch module and is operable by rotation to make the tap-switch module perform a sequence of operations that effect a tap-switch, the operations comprising actuating the bypass switch assembly (50), actuating the vacuum interrupter assembly (52) and actuating the selector switch assembly (48); (c.) a multi-turn absolute encoder (264) connected to the at least one rod (174, 122, 232) and operable to determine a position of the at least one rod (174, 122, 232); and (d.) a monitoring system (134) connected to the encoder (264) to receive the position of the at least one rod (174, 122, 232) and operable to perform a method of monitoring a tap change, wherein the method comprises determining, from the position of the at least one rod (174, 122, 232) where the tap-switch module is in the sequence of operations.
[0002]
2. On-load tap-changer (10), according to claim 1, characterized in that the tap-change monitoring method further comprises: measuring the time required to perform at least one of the operations; and determining that an error has occurred if at least one of the operations was not performed at the appropriate time.
[0003]
3. On-load tap-changer (10), according to claim 2, characterized in that the time measurement step comprises measuring the total time required to perform all operations; and where an error is determined to have occurred if the total time required to perform all operations is greater than a predetermined amount of time.
[0004]
4. On-load tap-changer (10) according to claim 2, characterized in that the monitoring system (134) is additionally operable to measure the current flowing through the vacuum interrupter assembly (52 ), and wherein the method of monitoring tap switching further comprises: determining whether current through the vacuum interrupter assembly (52) is appropriately present or absent after at least one of the operations has been completed; and determining that an error has occurred if the current through the vacuum interrupter assembly (52) is not properly present or absent after at least one of the operations has been completed.
[0005]
5. On-load tap-changer (10) according to claim 4, characterized in that the monitoring system (134) is operatively connected to the motor (124) to control the operation of the motor (124 ); wherein the selector switch assembly (48) comprises a moving contact, wherein the moving contact is no longer connected to an initial tap of the transformer winding to be connected to a final tap of the transformer winding during a tap change, and wherein when the monitoring system (134) determines that an error has occurred, the monitoring system (134) performs an error handling method comprising: controlling the motor (124) to continue tap switching and moving the contact moveable to be connected to the final tap, or cancel tap switching and move the movable contact again to be connected to the initial tap, depending on where the tap switching module is in the sequence of operations.
[0006]
6. On-load tap-changer (10) according to claim 5, characterized in that the error handling method further comprises: after controlling the motor (124) to continue tap switching or cancel tap switching, the monitoring system (134) cuts power to the motor.
[0007]
7. On-load tap-changer (10) according to claim 5, characterized in that the bypass switch assembly (50) comprises a bypass switch (66, 68) and the switch assembly a vacuum (52) comprises a vacuum switch (54) having a pair of contacts arranged on a vacuum flask, and wherein the sequence of operations comprises: (a.) opening the bypass switch (66, 68) ; (b.) after operation (a.), open the vacuum interrupter contacts (54); (c.) after operation (b.), move the moving contact from the initial tap to the final tap; (d.) after operation (c.), close the vacuum interrupter contacts (54); and (e.) after operation (d.), close the bypass switch (66, 68).
[0008]
8. On-load tap-changer (10) according to claim 7, characterized in that if an error is determined to have occurred before operation (d.) has been completed, the monitoring system (134) cancels tap switching and moves the moving contact back to the initial tap.
[0009]
9. On-load tap-changer (10), according to claim 7, characterized in that after operation (a.) and before operation (b.), the monitoring system (134) determines whether current is flowing through the vacuum interrupter (52), and if current is not flowing through the vacuum interrupter (52), the monitoring system (134) determines that an error has occurred.
[0010]
10. On-load tap-changer (10), according to claim 7, characterized in that in the tap-change monitoring method, the time measurement step comprises measuring the times required to perform the operations ( a.), (b.) and (e.), respectively; and in which an error is determined to have occurred if the time required to perform operation (a.) is greater than a first predetermined amount of time, or if the time required to perform operation (b.) is greater than a second predetermined amount of time, or if the time required to perform operation (c.) is greater than a third predetermined amount of time.
[0011]
11. On-load tap-changer (10) according to claim 1, characterized in that the selector switch assembly (48) comprises a pair of movable contacts (58, 60) and a plurality of contacts fixed (56) electrically connected to transformer winding taps, respectively; and wherein the movable contacts (58, 60) are movable between a plurality of different tap positions, wherein at each tap position the movable contacts (58, 60) are connected to the same fixed contact (56 ) or are connected to adjacent fixed contacts (56), respectively; and wherein the monitoring system (134) is operable to determine the tap position of the movable contacts (56, 58) from the position of the at least one rod (174, 122, 232).
[0012]
12. On-load tap-changer (10) according to claim 11, characterized in that the motor (124) is a servo motor and comprises a motor rod and a feedback device operable to generate a feedback signal from which the position of the motor rod can be determined; and wherein the on-load tap-changer further comprises a servo drive (126) connected to the servo motor for receiving the feedback signal, the servo drive (126) determining a position of the motor rod from the feedback signal and storing the position, where the servo drive (126) uses the feedback signal and the position of the motor rod to control the operation of the servo motor.
[0013]
13. On-load tap-changer (10) according to claim 12, characterized in that the at least one rod (174, 122, 232) comprises the motor rod (174), a transmission rod (122) connected between the motor rod (174) and the tap-switch module, and a first side rod (232) connected by means of at least one gear to the transmission rod (122) so as to rotate with the same; and wherein the multi-turn encoder (264) is connected to the first side rod (232) and is operable to determine the position of the first side rod (232).
[0014]
14. On-load tap-changer (10), according to claim 13, characterized in that if there is a loss of power to the servo drive (126) and/or to the monitoring system (134) , the monitoring system (134), after power restoration, performs a restoration routine comprising: determining the position of the motor rod (174) from the position of the first side rod (232) received from the encoder (264); transmitting the determined position of the motor rod (174) to the servo drive (126), which then stores the determined position of the motor rod (174); determining whether a tap change between an initial position of the tap positions and an end position of the tap positions that was initiated before the power loss was completed; and if tap switching has not been completed, control the motor (124), depending on where the tap switching module is in the sequence of operations, to terminate tap switching by moving one of the moving contacts (58, 60) so that the movable contacts (58, 60) are in the final position of the tap positions, or cancel tap switching by moving one of the movable contacts (58, 60) so that the movable contacts (58, 60) are back to the home position of the lead positions.
[0015]
On-load tap changer (10) according to claim 1, characterized in that the monitoring system (134) is operable to control the motor (124) to perform a tap change within a predetermined period of time selectable by the user.

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US9697962B2|2017-07-04|

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MX2013011088A|2014-05-01|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

US3404247A|1966-03-08|1968-10-01|Gen Electric|Pressure responsive protective means for vacuum type circuit interrupters|

---

US3524033A|1968-04-03|1970-08-11|Gen Electric|Bypass switch and vacuum interrupter|

---

US3602807A|1970-04-16|1971-08-31|Westinghouse Electric Corp|Load tap changer apparatus with magnetic transducer protective circuitry|

---

US3622867A|1970-04-16|1971-11-23|Westinghouse Electric Corp|Load tap changer system including protective apparatus for monitoring the operation thereof|

---

US3720867A|1972-02-04|1973-03-13|Gen Electric|Fail safe vacuum type circuit interrupter and associated load current tap changer for electric induction apparatus|

---

US3735243A|1972-04-03|1973-05-22|Gen Electric|Control system for tap changer with vacuum interrupter|

---

US3819892A|1972-11-30|1974-06-25|Gen Electric|Fail safe vacuum type circuit interrupter and associated load current tap changer for electric induction apparatus|

---

US4061963A|1976-04-27|1977-12-06|Westinghouse Electric Corporation|Load tap changer system|

---

US4090225A|1977-01-21|1978-05-16|Mcgraw-Edison Company|Fail-safe circuit for tap-changing transformer regulating system|

---

JPH0439764B2|1984-02-23|1992-06-30|

---

JPH0452603B2|1984-02-24|1992-08-24|Tokyo Shibaura Electric Co|

---

DE4009038C2|1990-03-21|1992-01-16|Maschinenfabrik Reinhausen Gmbh, 8400 Regensburg, De|

---

DE4214431C3|1992-04-30|1996-08-14|Reinhausen Maschf Scheubeck|Step switch with motor drive|

---

US5428551A|1992-09-23|1995-06-27|Siemens Energy & Automation, Inc.|Tap changer monitor apparatus and method|

---

JP3189541B2|1993-11-29|2001-07-16|三菱電機株式会社|Abnormality monitoring device for load tap changer|

---

DE19528827C1|1995-08-05|1996-12-12|Reinhausen Maschf Scheubeck|Control of transformer tap or stepping switches e.g. for power supply installation|

---

DE19743864C1|1997-10-04|1999-04-15|Reinhausen Maschf Scheubeck|Tap changer|

---

DE19744465C1|1997-10-08|1999-03-11|Reinhausen Maschf Scheubeck|Means for regulation of a multi-contact switch for tapped transformer|

---

DE19746574C1|1997-10-22|1999-02-04|Reinhausen Maschf Scheubeck|Method of functional monitoring of step switches|

---

DE19907834C1|1999-02-24|2000-05-18|Reinhausen Maschf Scheubeck|Monitoring method for step switches involves selecting characteristic motor torque values for identical times in two switching processes, and comparing corresponding switch torques with limits|

---

SE519492C2|2000-05-26|2003-03-04|Abb Ab|Actuator and winding coupler including one|

---

US7145760B2|2000-12-15|2006-12-05|Abb Technology Ltd.|Tap changer monitoring|

---

EP1404000A1|2002-09-27|2004-03-31|Phase Motion Control S.r.l.|A compact servo motor|

---

DE10315206A1|2003-04-03|2004-10-21|Maschinenfabrik Reinhausen Gmbh|Multipoint switch for step-down transformer, has torque motor used as operating drive for fine selector, preselector and load switching device|

---

UA84417C2|2003-04-03|2008-10-27|Машиненфабрик Райнхаузен Гмбх|Multipoint switch |

---

AT341826T|2003-04-03|2006-10-15|Reinhausen Maschf Scheubeck|ARRANGEMENT FOR A MONITORING SYSTEM FOR STAGE SWITCHES|

---

DE10333010B4|2003-07-18|2008-07-24|Karl Mayer Textilmaschinenfabrik Gmbh|Method for operating a high-speed knitting machine|

---

US7417411B2|2005-09-14|2008-08-26|Advanced Power Technologies, Llc|Apparatus and method for monitoring tap positions of load tap changer|

---

US7444266B2|2006-03-21|2008-10-28|Abb Technology Ltd.|Control system for a transformer or reactor|

---

UA95970C2|2006-08-25|2011-09-26|Абб Текнолоджи Лтд|On-load tap-changer comprising electric motor drive unit|

---

EP2244272B1|2009-04-20|2012-06-06|ABB Technology Ltd|Measuring contact sequence in a tap changer|

---

US8203319B2|2009-07-09|2012-06-19|General Electric Company|Transformer on-load tap changer using MEMS technology|

---

US8643221B2|2010-06-08|2014-02-04|Siemens Energy, Inc.|Retrofit kit, circuitry and method for reconfiguring a tap changer to avoid electrical arcing|

---

EP2689444B8|2011-03-25|2017-10-11|ABB Schweiz AG|Tap changer having an improved vacuum interrupter actuating assembly|

---

WO2012135213A1|2011-03-27|2012-10-04|Abb Technology Ag|Tap changer with an improved monitoring system|

---

BR112013024908B1|2011-03-27|2021-02-17|Abb Schweiz Ag|on-load tap-changer to switch taps on a transformer winding|WO2012135213A1|2011-03-27|2012-10-04|Abb Technology Ag|Tap changer with an improved monitoring system|

---

BR112013024908B1|2011-03-27|2021-02-17|Abb Schweiz Ag|on-load tap-changer to switch taps on a transformer winding|

---

ES2656366T3|2011-05-12|2018-02-26|Moog Unna Gmbh|Emergency power supply device and method to supply emergency power|

---

DE102012103736A1|2012-04-27|2013-10-31|Maschinenfabrik Reinhausen Gmbh|Method for monitoring the operation of a tap changer|

---

DE102014100949B4|2014-01-28|2016-12-29|Maschinenfabrik Reinhausen Gmbh|On-load tap-changer according to the reactor switching principle|

---

DE102014106997A1|2014-05-19|2015-11-19|Maschinenfabrik Reinhausen Gmbh|Switching arrangement for a tapped transformer and method for operating such a switching arrangement|

---

DE102014110731A1|2014-07-29|2016-02-04|Maschinenfabrik Reinhausen Gmbh|motor drive|

---

CN104517742B|2014-12-29|2018-04-24|刁俊起|A kind of permanent magnetic drive on-load voltage regulating switch|

---

CN104517744B|2014-12-29|2018-01-12|山东洁盟节能环保技术有限公司|A kind of permanent magnetic drive on-load voltage regulating switch|

---

EP3051689A1|2015-01-30|2016-08-03|ABB Technology Ltd|A motor drive unit for operating a tap changer, a method of braking a motor drive unit, and an electromagnetic induction device|

---

DE102015106178A1|2015-04-22|2016-10-27|Maschinenfabrik Reinhausen Gmbh|OLTC|

---

WO2017134542A1|2016-02-07|2017-08-10|Rotal Innovative Technologies Ltd.|System and methods for a multi-function pressure device using piezoelectric sensors|

---

US9679710B1|2016-05-04|2017-06-13|Cooper Technologies Company|Switching module controller for a voltage regulator|

---

IT201600074502A1|2016-07-15|2018-01-15|Maurizio Damiani|VOLTAGE UNDERLOAD FOR DRY TRANSFORMER.|

---

DE102019112715B3|2019-05-15|2020-10-01|Maschinenfabrik Reinhausen Gmbh|Method for performing a switchover of an on-load tap-changer by means of a drive system and a drive system for an on-load tap-changer|

---

DE102019112718A1|2019-05-15|2020-11-19|Maschinenfabrik Reinhausen Gmbh|Method for performing a switchover of at least one switching means of an operating means and drive system for at least one switching means of an operating means|

---

DE102019112720A1|2019-05-15|2020-11-19|Maschinenfabrik Reinhausen Gmbh|Method for carrying out a changeover of a switch and drive system for a switch|

---

DE102019130457B3|2019-11-12|2021-02-04|Maschinenfabrik Reinhausen Gmbh|On-load tap-changer|

---

DE102019130460A1|2019-11-12|2021-05-12|Maschinenfabrik Reinhausen Gmbh|On-load tap-changer|

法律状态:
2017-12-19| B25A| Requested transfer of rights approved|Owner name: ABB SCHWEIZ AG (CH) |

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2018-01-30| B25L| Entry of change of name and/or headquarter and transfer of application, patent and certificate of addition of invention: publication cancelled|Owner name: ABB TECHNOLOGY AG (CH) |

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2018-02-06| B25C| Requirement related to requested transfer of rights|Owner name: ABB TECHNOLOGY AG (CH) |

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2018-05-22| B25L| Entry of change of name and/or headquarter and transfer of application, patent and certificate of addition of invention: publication cancelled|Owner name: ABB SCHWEIZ AG (CH) |

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2018-05-29| B25A| Requested transfer of rights approved|Owner name: ABB SCHWEIZ AG (CH) |

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2018-12-18| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2019-08-20| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2021-04-13| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-05-25| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 27/03/2012, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

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申请号 | 申请日 | 专利标题

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US201161468060P| true| 2011-03-27|2011-03-27|

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US61/468,060|2011-03-27|

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PCT/US2012/030734|WO2012135213A1|2011-03-27|2012-03-27|Tap changer with an improved monitoring system|

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