on-load tap-changer to switch taps on a transformer winding

专利摘要:
DERIVATOR SWITCH WITH AN IMPROVING DRIVE SYSTEM. The present invention relates to an on-load tap-changer that is provided having a plurality of modules, each of which is operable to change taps in a transformer winding. A transmission shaft is connected to the modules and is operable with rotation to effect tap-changing in the windings. A servo motor rotates the drive shaft. The servo motor includes an operable feedback device to generate a feedback signal containing information regarding the position of the motor shaft. A servo unit is connected to the servo motor to receive the feedback signal. The servo unit uses the feedback signal to determine and store a total angular displacement of the motor axis. The servo unit uses the feedback signal and the total angular displacement of the motor shaft to control the operation of the servo motor.
公开号:BR112013024908B1
申请号:R112013024908-0
申请日:2012-03-27
公开日:2021-02-17
发明作者:William James Teising；Robert Alan Elick；David Matthew Geibel；Joshua Tyler Elder
申请人:Abb Schweiz Ag；
IPC主号:

专利说明:

[0001] [0001] The present invention relates to a tap-changer and more particularly to on-load tap-changers.
[0002] [0002] As is well known, a transformer converts electricity from one voltage to electricity into another voltage, whether higher or lower. A transformer performs this voltage conversion using a main winding and a secondary winding, each of which is wound in a ferromagnetic core and comprises a number of turns of an electrical conductor. The main 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 voltage to input voltage can be changed, thereby controlling or regulating the output voltage of the transformer. This relationship can be changed by effectively changing the number of turns in the main winding and / or the number of turns in the secondary winding. This is accomplished by making connections between different connection points or "taps" within the winding (s). A device that can make said selective connections for the taps is referred to as a "tap switch".
[0003] [0003] In general, there are two types of tap-changer: on-load tap-changer and no-load or de-energized tap-changer. A no-load tap-changer uses a circuit breaker to isolate a transformer from the voltage source and then switches from one tap to the other. 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 can include, for each phase winding, a selector switch set, a bypass switch set and a vacuum switch set. The selector switch set makes connections to the transformer taps, while the bypass switch set connects the taps, through two derivative circuits, to a main power circuit. During a bypass switching, the vacuum switch assembly securely isolates a bypass circuit. A drive system moves the selector switch assembly, the bypass switch assembly and the vacuum switch assembly. The present invention is directed to said drive system. Summary of the Invention
[0004] [0004] In accordance with the present invention, an on-load tap-changer is provided to carry out tap-changings in a transformer winding. The tap-changer includes a tap-changer module connected to the transformer winding. The bypass switch module includes a bypass switch assembly, a vacuum switch assembly and a selector switch assembly. A servo motor is provided and includes a motor shaft and a feedback device. The motor shaft is connected to the tap-changer module and is operable, with rotation, to make the tap-changer module perform a sequence of operations that effect a tap-changer. The feedback device is operable to generate a feedback signal containing information regarding the position of the motor shaft. A servo unit is connected to the servo motor to receive the feedback signal. The servo unit uses the feedback signal to determine and store the total angular displacement of the motor axis. The servo unit uses the feedback signal and the total angular displacement of the motor shaft to control the operation of the servo motor. Brief Description of Drawings
[0005] [0005] The characteristics, aspects, and advantages of the present invention will become better understood with respect to the following description, attached claims and attached drawings, in which:
[0006] [0006] Figure 1 shows a front elevation view of a tap-changer of the present invention;
[0007] [0007] Figure 2 shows a schematic view of the tap-changer;
[0008] [0008] Figure 3 shows circuit diagrams of the tap-changer in linear, plus-minus and thick-thin configurations;
[0009] [0009] Figure 4 shows a schematic drawing of an electrical circuit of the tap-changer;
[0010] [00010] Figure 5 shows the electrical circuit progressing through a bypass switch;
[0011] [00011] Figure 6 shows a front view of the interior of a tap-changer tank;
[0012] [00012] Figure 7 shows a rear view of a forward support structure of the tap-changer;
[0013] [00013] Figure 8 shows a schematic view of a drive system and a tap-changer monitoring system;
[0014] [00014] Figure 9 shows a front view of an oscillation panel of a housing for the drive system;
[0015] [00015] Figure 10 shows a schematic view of the power and communication connections between the components of the drive system and the monitoring system;
[0016] [00016] Figure 11 shows a schematic sectional view of a servo motor of the drive system;
[0017] [00017] Figure 12 shows the schematic view of a servo unit of the drive system;
[0018] [00018] Figure 13 shows a perspective view of the interior of the housing containing the drive system and the monitoring system;
[0019] [00019] Figure 14 shows an enlarged view of a hand crank assembly and other components of the drive system;
[0020] [00020] Figure 15 shows an enlarged view of a Geneva type cam and gear of the drive system;
[0021] [00021] Figure 16 shows a perspective view of the cam;
[0022] [00022] Figure 17 shows a schematic view of a vacuum switch monitoring system;
[0023] [00023] Figure 18 shows a graphical representation of a tap switching map stored in the monitoring system's memory;
[0024] [00024] Figure 19 shows a flow chart of an energy restoration routine performed by the monitoring system;
[0025] [00025] Figure 20 shows a flow chart of a first monitoring routine that can be performed by the monitoring system; and
[0026] [00026] Figure 21 shows a flow chart of a second monitoring routine that can be performed by the monitoring system. Detailed Description of the Illustrative Modalities
[0027] [00027] It should be noted that in the following detailed description, identical components have the same reference numbers, 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 illustrate the present invention, the drawings may not necessarily be in scale and certain features of the present invention can be shown in a relatively schematic form.
[0028] [00028] Referring now to figures 1 and 2, a load tap-changer (LTC) 10 designed according to the present invention is shown. The LTC 10 is adapted for tank mounting to a transformer. In general, LTC 10 comprises a tap-changer set 12, a drive system 14 and a monitoring system 16. The tap-changer set 12 is embedded in a tank 18, while the drive system 14 and the monitoring system 16 are embedded in a housing 20, which can be mounted below the tank 18. The tank 18 defines an internal chamber within which the tap-changer assembly 12 is mounted. The internal chamber retains a volume of dielectric fluid sufficient to immerse the tap-changer assembly 12. Access to the tap-changer assembly 12 is provided through a door 24, which is pivotable between the open and closed positions.
[0029] [00029] The tap-changer assembly 12 includes three circuits 30, each of which is operable to change taps on a regular winding 32 to a transformer phase. Each circuit 30 can be used in a linear configuration, a plus-minus configuration or a thin-thick configuration, as shown in figures 3a, 3b, 3c, respectively. In the linear configuration, the voltage across the regular winding 32 is added to the voltage through a main winding (low voltage) 34. In the plus-minus configuration, the regular winding 32 is connected to the main winding 34 by a toggle switch 36, which allows that the voltage across the regular winding 32 be added to or subtracted from the voltage across the main winding 34. In the coarse-coarse configuration, there is a regular coarse winding 38 in addition to the regular (fine) winding 32. Switch 40 connects the winding regular (fine) 32 to the main winding 34, either directly, or in series, with the thick regular winding 38.
[0030] [00030] Referring now to figure 4, a schematic drawing of one of the electrical circuits 30 of the tap-changer assembly 12 connected to the regular winding 32 in a plus-minus configuration is shown. The electrical circuit 30 is arranged in first and second derivative circuits 44, 46 and in general includes a selector switch assembly 48, a bypass switch assembly 50 and a vacuum interrupter assembly 52 comprising a vacuum interrupter 54.
[0031] [00031] The selector switch assembly 48 comprises first and second movable contact arms 58, 60 and a plurality of stationary contacts 56 which are connected to the winding taps 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 is connecting two taps. The first contact arm 58 is located on the first branch circuit 44 and a second contact arm 60 is located on a second branch circuit 46. The bypass switch assembly 50 comprises first and second branch switches 66, 68, with the first switch bypass 66 being located on the first bypass circuit 44 and a second bypass switch 68 being located on a second bypass circuit 46. Each of the first and second bypass switches 66, 68 is connected between its associated reactor and the power circuit main. The vacuum switch 54 is connected between the first and second derivative circuits 44, 46 and comprises a fixed contact and a movable contact embedded in a flask or housing having a vacuum therein.
[0032] [00032] The first and second contact arms 58, 60 of the selector switch assembly 48 can be positioned in a non-connection position or a connection position. In the non-bonding position, the first and second contact arms 58, 60 are connected to a single one of a plurality of taps on winding 32 of the transformer. In the connection position, the first contact arm 58 is connected to one of the leads and a second contact 60 is connected to another, adjacent to the leads.
[0033] [00033] In figure 4, the first and second contact arms 58, 60 are both connected to a derivation 4 of the winding 32, that is, the first and second contact arms 58, 60 are in the non-connection position. In a steady state condition, the contacts 164, 166 of the vacuum switch 54 are closed and the contacts on each of the first and second tap-changers 66, 68 are closed. The charging current flows through the first and second contact arms 58, 60 and the first and second tap-changers 66, 68. Substantially no current flows through the vacuum switch 54 and there is no current circulating in the reactor circuit.
[0034] [00034] A bypass switch in which the first and second contact arms 58, 60 are moved to the connection position will now be described with reference to figures 5a – 5e. The first tap-changer 66 is first opened (as shown in figure 5a), which causes current to flow through vacuum switch 54 from first contact arm 58 and reactor 62. Vacuum switch 54 is then open to isolate the first branch circuit 44 (as shown in figure 5b). This allows the first contact arm 58 to be subsequently moved to lead 5 without sparking (as shown in figure 5c). After this movement, the vacuum switch 54 is first closed (as shown in figure 5d) and then the first tap-changer 66 is closed (as shown in figure 5e). This completes the branch switching. At that point, the first contact arm 58 is connected to lead 5 and the second contact arm 60 is connected to lead 4, i.e., the first and second contact arms 58, 60 are in the connecting position. In the steady state condition, the contacts of the vacuum switch 54 are closed and the contacts on each of the first and second tap-changers 66, 68 are closed. Reactors 62, 64 are now connected in series and the voltage at its central point is half the voltage by tap selection. The circulating current now flows in the reactor circuit.
[0035] [00035] Another bypass switching can be done to move the second contact arm 60 to lead 5 so that the first and second contact arms 58, 60 are on the same lead (lead 5), that is, to be on no connection position. To do this, the routine described above is performed for a second branch circuit 46, that is, a second branch switch 68 is first opened, then the vacuum switch 54 is opened, a second contact arm 60 is moved to the branch. 5, the vacuum switch 54 is first closed and then a second tap-changer 68 is closed.
[0036] [00036] In the bypass switching described above, the current flows continuously during the bypass switching, while the first and second contact arms 58, 60 are moved in the absence of current.
[0037] [00037] As best shown in figure 4, the selector switch assembly 48 can have eight stationary contacts 56 connected to eight leads in winding 32 and a stationary contact 56 connected to a neutral lead (middle range) of winding 32. Thus, with toggle switch 36 at terminal B (as shown), the selector switch assembly 48 is movable between a neutral position and sixteen distinct elevated positions (plus) (i.e., eight non-connecting positions and eight connecting positions). With the switch switch 36 at terminal A, the selector switch set 48 is movable between the neutral position and sixteen distinct lower (minus) positions (i.e., eight non-connecting positions and eight connecting positions). In this way, the selector switch set 48 is movable between a total of 33 positions (one neutral position, 16 upper (R) positions and 16 lower (L) positions).
[0038] [00038] With reference now to figure 6, three support structures 80 are mounted inside the tank 18, one for each electrical circuit 30. The 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 portion) of a support structure 80, while the selector switch assembly 48 is mounted behind the control structure. support 80.
[0039] [00039] With reference now to figure 7, a second side of one of the support structures 80 is shown. A bypass gear 82 and a vacuum switch gear (VI) 92 are mounted on a second side. An isolated shaft 83 is shown connected to the bypass 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. A bypass gear 82 is attached to a bypass axis that extends through the support structure 80 and within the first side of the support structure 80. The bypass gear 82 is connected by a chain 90 to the VI 92 gear, which it is fixed to a VI 94 axis. The VI 94 axis also extends through the support structure 80 and within the first side of the support structure 80. When the drive system 14 is activated to effect a bypass switch, the drive system 120 and shaft 83 carry the rotation of the main drive shaft 122 to the bypass gear 82, thereby causing the bypass gear 82 and the bypass shaft to rotate. The rotation of the bypass gear 82, in turn, is conveyed by a chain 90 to the VI 92 gear, which causes the VI 92 gear and the VI 94 shaft to rotate.
[0040] [00040] Details of transmission system 120 are described in provisional US patent application No .: 61 / 467,455 filed on March 25, 2011, entitled "Selector Switch Assembly for Load Tap Changer" and in provisional US patent application No. : 61 / 467,822 filed on March 25, 2011, entitled "An Improved Tap Changer", both of which are incorporated herein by reference.
[0041] [00041] On the first side of the support structure 80, the deviation axis is fixed to a deviation cam, while the VI 94 axis is fixed to an VI cam. The bypass cam rotates with the rotation of the bypass axis and the VI cam rotates with the rotation of the VI axis 94. The rotation of the bypass cam drives the first and second bypass switches 66, 68, while the rotation of the cam VI opens and closes the vacuum switch contacts 54. The VI 82, 92 bypass and gears are dimensioned and arranged to rotate the bypass cam through 180 degrees for each tap changeover and to rotate the VI cam by 360 ° for each tap changeover.
[0042] [00042] Referring now to figure 8, the transmission system 120 also connects each set of selector switch 48 to the main transmission shaft 122 of the drive system 14. More specifically, the transmission system 120 translates the rotation of the transmission shaft main 122 in rotational movement of the first and second contact arms 58, 60. Said rotational movement is indexed and is around a common axis in the center of a circular configuration of the stationary contacts 56. The first and second contact arms 58, 60 are aligned, with a second contact arm 60 disposed on the first contact arm 58 when they are connected to the same stationary contact 56 (in a non-connected position). The stationary contacts 56 are arranged in a circle, with the neutral stationary contact N being located at the top and a maximum reduction contact 16L and a maximum elevation contact 16R being located towards the bottom. Stationary contact 56 adjacent to neutral contact N in a counterclockwise direction (CCW) is hereinafter referred to as contact 1L. The rotation of the first contact arm 58 between neutral contact N and contact 1L activates switch switch 36. More specifically, the CCW rotation of the first contact arm 58 from neutral contact N to contact 1L moves the switch switch 36 for terminal A, while in the clockwise rotation (CW) of the first contact arm 58 from contact 1L to neutral contact N moves the switch switch 36 to terminal B. In the mode described above where there are positions 16R , positions 16L and the neutral position (the neutral stationary contact N), since the first and second contact arms 58, 60 have been moved counterclockwise and are in position 16L (both in contact 16L), the first and second second contact arms 58, 60 must be moved back clockwise to the neutral position before the first and second contact arms 58, 60 can be moved to any of positions 1-16R. Similarly, since the first and second contact arms 58, 60 have been moved clockwise and are in position 16R (both in contact 16R), the first and second contact arms 58, 60 must be moved back to counterclockwise to the neutral position before the first and second contact arms 58, 60 can be moved to any of the 1-16L positions. Move the first and second contact arms 58, 60 of each circuit 30 between positions, neutral, positions 1L-16L and positions 1R-16R (and the associated operation of each bypass switch set 50 and each vacuum switch set 52) can be referred to as moving tap switch assembly 12 between taps.
[0043] [00043] With reference now also to figures 9 and 10, the drive system 14 in general includes a servo motor 124, a servo unit 126, the gear head 128 and a hand crank assembly 130. The drive system 14 interfaces com and is controlled by the monitoring system 134. As determined above, the drive system 14 and the monitoring system 134 are mounted inside the housing 20, which has a front opening through which the drive system 14 and the monitoring system 134 can be accessed. As shown in figure 1, an external door 136 is pivotally mounted to housing 20 and is operable to close the front opening. With particular reference now to figure 9, an oscillation plate 138 is pivotally mounted to housing 20, internally to external door 136. Oscillation plate 138 has a plurality of openings through which interface devices within housing 20 are accessible when the oscillation plate 138 is in a closed position. For example, a mode switch 140, a socket 142, a mechanical bypass position indicator 144 and a human machine interface (HMI) 146 all extend through and / or are accessible through openings in the oscillation plate 138 when the oscillation plate 138 is closed. In addition to providing access to the previous interface devices, the oscillation plate 138 has a number of interface devices directly mounted to it. For example, a return to neutral switch 150 and a lower / lift switch 152 are mounted directly on the oscillation plate 138. The oscillation plate 138 acts as the second door that protects the equipment inside the housing 20, while providing access to the interface device.
[0044] [00044] 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 inside the housing 20. Said devices are electrically connected to and controlled by the monitoring system 134 in order to maintain a suitable environment for the servo unit 126, the monitoring system 134 and the other devices within the housing 20.
[0045] [00045] Still mounted inside housing 20 are the 24 VDC power supply 160, a 5 VDC power supply 162 and a second redundant 5 VDC power supply 164. Servo unit 126, heater 158, fan 159, the 24 VDC power supply 160 and the first 5 VDC power supply 162 are provided with 120 VAC to 240 VAC power from a main power supply 165. A second 5 VDC power supply 164 can be connected to a backup power supply 166. Monitoring system 134 is supplied with power from the first 5 VDC power supply 162 or, in the event of a failure of the main power supply 165, the second power supply of 5 VDC 164.
[0046] [00046] Referring now to figure 11, a sectional view of a modality of servo motor 124 is shown. In said modality, servo motor 124 is a brushless AC induction motor having a fixed stator 170 and a rotating rotor 172 fixed to an axis 174. When voltage is applied to stator 170, current flows in stator 170 and induces current to flow in rotor 172 through magnetic induction. The interaction of the magnetic fields in the stator 170 and the rotor 172 causes the rotor 172 and thus the axis 174 to rotate. Stator 170 is located radially outward from rotor 172 and can be comprised of blades and turns of an electrical conductor. The rotor 172 may have a "squirrel cage" construction comprised of stacks of steel sheets separated by slits filled with conductive material, such as copper or aluminum.
[0047] [00047] Servo motor 124 may include a brake 176 that maintains the position of axle 174 when power to servo unit 126 and thus servo motor 124 is cut off. Brake 176 may be a spring-type brake or a permanent magnet-type brake.
[0048] [00048] Servo motor 124 is provided with a feedback device 180, which can be a solver or an absolute encoder of multiple rotations. Resolvers are described in the following paragraphs, while an absolute multi-spin encoder is described further below.
[0049] [00049] In one embodiment, the feedback device 180 is a single speed resolving transmitter, as shown in figure 11. The resolving transmitter is essentially a rotary transformer having a rotor winding 182 rotatably disposed within a stationary pair of windings. of stator SIN and COS 184, 186, which are positioned 90 degrees apart. The rotor winding 182 is connected in some way to the motor shaft 174 in order to rotate with it. Rotor winding 182 is driven by an AC voltage called the reference voltage (Vr). The voltages induced in the SIN and COS stator windings 184, 186 are equal to the value of the reference voltage multiplied by the SIN or COS of the motor shaft angle 174 from a fixed zero point. Thus, the resolving transmitter provides two voltages whose relationship represents the absolute position of the axis. (SIN θ / COS θ = TAN θ, where θ = axis angle). The voltages induced in the SIN and COS stator windings 184, 186 are provided to a solver microcontroller, which analyzes the signals and generates a feedback signal that contains information about the speed and the angular position of the motor axis 174. The microcontroller then outputs the feedback signal to a servo unit 126. In one embodiment of the present invention, the feedback signal comprises a series of pulses or counts, in which, for example, 16,384 counts are generated for each 360 ° rotation of the motor axis 174. Thus, a count is generated for about every 0.02 degree of movement of the motor shaft 174. The counts are positive when the servo motor 124 is operating in a first direction, such as to make a tap-changeover from from 1R to 2R and are negative when the servo motor 124 is operating in a second direction, such as to make a tap change from 1L to 2L. When viewed from a top front perspective, as in figure 13, the first direction is clockwise and the second direction is counterclockwise.
[0050] [00050] The resolving transmitter described above is considered a single speed resolving transmitter in that the signals emitted go through only one sine wave (and one cosine wave) as the motor axis 174 rotates through 360 °.
[0051] [00051] It should be noted that instead of being a single speed resolving transmitter, the feedback device 180 can be a multiple speed resolving transmitter, such as a four speed resolving transmitter in which the emitted signals go through four waves of sine as the motor axis 174 rotates through 360 °. Additionally, the feedback device 180 can be a resolver control transformer, which has two stator windings and two rotor windings. The two rotor windings are provided with excitation signals and the position information is derived from the signals from the stator windings. In addition, the feedback device 180 may be a synchro, which is similar to a resolving transmitter, except that there are three stator windings, separated by 120 °. A resolver transmitter (single or multiple speed) and a resolver control transformer are generically referred to as a "resolver".
[0052] [00052] Referring now to figure 12, servo unit 126 controls the operation of servo motor 124 by controlling the power provided to servo motor 124. Servo unit 126 generally includes a low voltage section 187 and a high voltage section 194. Low voltage section 187 includes a controller 188 and a plurality of associated records, including a speed record 189, a stop record plus 190, a stop record minus 191 and a feedback record 192. Controller 188 is based on microprocessor and receives command signals from monitoring system 134 or local devices, such as the lower / raise switch 152. In addition, controller 188 receives the feedback signal from feedback device 180 and derives information feedback from it (for example, angular position, speed). Controller 188 compares a command and feedback information to generate an error that controller 188 then acts to eliminate. Controller 188 acts on the error using an algorithm, such as a proportional and integral (PI) algorithm, or a proportional, integral and derivative algorithm (PID). The output of the algorithm is a low energy level control signal, which is provided for the high voltage section 194. Using power from the main power supply 165, the high voltage section 194 amplifies the level control signal low energy to a higher energy level which is then provided to the servo motor 124. The high voltage section 194 can convert AC energy into DC energy in a rectifier 196 and generates an output to servo motor 124 using a modulation inverter pulse width 198. It is generally observed that higher voltage levels are required to rotate servo motor 124 at appropriate higher speeds and higher current levels are required to provide torque for moving heavier loads.
[0053] [00053] As determined above, there are a plurality of records associated with controller 188. Said records store information that is used by controller 188 to control the operation of servo motor 124. Speed record 189 stores the speed at which the servo motor 124 must operate when a tap-changer is made. The stop record plus 190 stores the number of positive feedback units (for example, counts) from the feedback device 180 which corresponds to a stop location in the first rotation direction of the motor shaft 174. Similarly, the stop record minus 191 stores the total number of negative feedback units (for example, counts) from feedback device 180 which corresponds to a stop location in the second rotation direction of the motor shaft 174. The feedback record 192 stores the position information of the motor axis 174 obtained from the feedback signal. In the mode described above where the feedback signal comprises a series of counts, the feedback record 192 stores a worked total of the counts received. Since the motor axis 174 rotates twenty times for each tap changeover and 16,384 counts are generated for each rotation, the record will store 327,680 counts for each tap changeover. If the power to the servo unit 126 is cut off, all the information stored in the speed record 189, the stop record plus 190, the stop record minus 191 and the feedback record 192 is lost and, with the restoration of power, the values in the records are set to zero.
[0054] [00054] The number of feedback units stored in the stop register plus 190 is used by controller 188 to automatically stop the rotation of axis 174 of servo motor 124 in the first direction after it has moved tap-changer assembly 12 to position bypass 16R or relatively beyond. In the mode described above where the feedback signal comprises a series of counts, the number of counts stored in the stop record plus 190 can be +5,242,880 counts or slightly more. The number of feedback units stored in the stop record minus 191 is used by controller 188 to automatically stop the rotation of axis 174 of servo motor 124 in the second direction after it has moved tap-changer assembly 12 to bypass position 16L or relatively beyond. In the mode described above where the feedback signal comprises a series of counts, the number of counts stored in the stop record minus 190 can be - 5,242,880 counts or relatively more (negative counts). From the above, it should be noted that controller 188, using the feedback units (for example, counts) stored in the stop record plus 190 and the stop record minus 191, performs a "rigid electronic stop" that prevents tap switch assembly 12 goes from position 16R through the neutral position and then to position 1R, and prevents tap switch assembly 12 from starting position 16L through the neutral position and then to position 1L.
[0055] [00055] The operation of the servo unit 126 is controlled by signals received by the controller 188 from the monitoring system 134. Two of the said signals are: enable hardware (H / W) and allow normal software mode (NMS). When the H / W permission signal is received, controller 188 only allows control algorithms in monitoring system 134 to control tap switch assembly 12. When the NMS permission signal is received, controller 188 additionally allows the servo unit 126 is controlled by command signals from local devices (for example, the lower / raise switch 152), the HMI 146 and remote devices. If neither the H / W permission signal nor the NMS permission signal is received, the servo unit 126 is "locked". The servo unit 126 can only be moved out of the locked state by the press of a release button on the HMI 146 by an operator after the problem causing the locked state has been corrected. There is bidirectional communication between the servo unit 126 and the monitoring system 134 over a CAN 200 bus. In addition, the monitoring system 134 sends digital command signals to the servo unit 126 over the drive interface 202 (shown in figure 8). Digital signals can also be sent from the servo unit 126 to the monitoring system 134 on the drive interface 202.
[0056] [00056] A regenerative braking resistor 206 can be provided to quickly stop the rotation of the motor shaft 174. When turned on, the regenerative braking resistor 206 bleeds the voltage from servo motor 124. The regenerative braking resistor 206 can be internal or external to the servo unit 126 and can be connected by a transistor. The regenerative braking resistor 206 is operable to stop the rotation of the motor shaft 174 with less than half a revolution (<180 °) of additional rotation of the motor shaft 174. In this regard, it should be noted that the controller 188 of servo unit 126 uses acceleration and deceleration values stored in a non-volatile memory (e.g., EEPROM) of servo unit 126 to control the coefficient at which motor axis 174 is started and stopped, respectively. These values can be changed by authorized maintenance personnel when tap-changer 10 is closed for maintenance.
[0057] [00057] With reference again to figure 8, the servo motor 124 is connected to the gear head 128, which is operable to multiply the torque of the servo motor 124 and increases its torsional rigidity. This allows the 124 servo motor to be reduced in size and to operate over its optimum range. Additionally, gear head 128 minimizes reflected inertia for maximum acceleration. The gear head 128 includes an output shaft and planetary gears and is attached to the axis of the servo motor 124 by self-locating input pin clamps. In one embodiment, the gear head 128 is operable to produce one rotation of its output shaft for every 10 revolutions of the motor shaft 174.
[0058] [00058] With reference now also to figure 13, the output shaft of the gear head 128 is connected to the main drive shaft 122, which extends upwards through an opening in a shelf 208 fixed between two walls on the inside . Above the shelf 208, the main drive shaft 122 extends upwardly through an opening in housing 20 and into the tank 18. The main drive shaft 122 enters the tank 18 through a feed assembly 210 fixed within an opening on a back wall of tank 18. Supply set 210 includes a gasket to seal the opening in tank 18. Inside tank 18, main drive shaft 122 is connected to selector switch sets 48, to bypass 50 and vacuum switch assemblies 52 via the transmission system 120. Rotating the main drive shaft 122 performs a bypass switching, as described above. More specifically, the 720 ° rotation of the main drive shaft 122 results in a complete tap-off switch. Since ten revolutions of the motor shaft 174 produce a rotation of the main drive shaft 122, the servo motor 124 rotates 20 times for each tap-changeover. The strict control provided by the drive system 14 allows the rotation of the main drive shaft 122 to be stopped at the end of a tap-changer with less than 15 ° of additional rotation of the main drive shaft 122.
[0059] [00059] With reference now also to figures 14 and 15, the hand crank assembly 130 includes an extended hand crank gear 214 and a crank device 216. Hand crank gear 214 is attached to the main drive shaft 122 above from shelf 208. A block 218 is attached to the underside of hand crank gear 214. Crank device 216 is mounted on rack 208, next to hand crank gear 214. Crank device 216 includes a gear that engages the hand crank gear 214 and an internal mechanism that translates the rotation of a rod 220 (shown in figure 13) into rotation of the gear and thus the hand crank gear 214 and the main drive shaft 122. The rod 220 is typically set aside and is only used when manual movement of the main drive shaft 122 is required. The rod 220 has an end with a cavity adapted to firmly receive a contoured shaft 222 of the internal mechanism. The shaft 222 is disposed within socket 142 in the housing of the crank device 216. The shaft 222 may have a hexagonal cross section, as shown. When the end of the stem 220 is disposed within socket 142 and engaged with shaft 222, stem 220 can be manually rotated to rotate main drive shaft 122, such as to perform a full or partial manual bypass switching.
[0060] [00060] The mode switch 140 is mounted adjacent to the crank device 216. (It should be noted that although the mode switch 140 is not shown in figure 13, it must be considered present). The mode switch 140 is connected to the servo unit 126 and the monitoring system 134 and includes four positions: crank, outside, local and remote. In local mode, mode switch 140 interacts signals from location control devices (such as the lower / raise switch 152) to control servo unit 126 and thus servo motor 124. In remote mode, mode switch 140 interacts signals from remote locations to control servo unit 126 and thus servo motor 124. In crank mode, mode switch 140 disconnects power to servo unit 126 and signals the control system monitoring 134 to deny the H / W permission signal to servo unit 126, thereby rendering servo motor 124 inoperable. The mode switch 140 has a rotating rod 223 for moving between the four positions. An irregularly shaped plate 224 with an enlarged opening is connected to stem 223 in order to rotate with it. Plate 224 is rotatable between an unblocked position, where the opening is aligned with socket 142 in the housing, and a locked position, where plate 224 blocks socket 142 in the housing. The plate 224 is in the unblocked position only when the rod 223 is in the position that places the mode switch 140 in crank mode. Thus, rod 220 can only be disposed within socket 142 and engaged with shaft 222 when mode switch 140 is in crank mode. Thus, the crank device 216 can only be used to manually move the main drive shaft 122 when power is cut to the servo motor 124.
[0061] [00061] Below the hand crank gear 214, a first gear 226 (shown schematically in figure 8) is attached to the main drive shaft 122. The first gear 226 is engaged in engagement with a second enlarged gear 230 which is attached to a first side of the shaft 232. The first and second gears 226, 230 are dimensioned so that two rotations of the main drive shaft 122 cause the first side shaft 232 to rotate, that is, there is a reduction of two for one. In this way, the first side of axis 232 will rotate 360 ° for each tap changeover. Position markings are provided on the top surface of second gear 230. Said markings, in relation to reference point 234, provide a visual indication of where in a tap-changer the tap-changer assembly 12 is located. The markings and reference point 234 are visible to an operator who is manually moving the main drive shaft 122 using the crank device 216, thereby assisting the operator to properly move tap-changer assembly 12 to a desired position .
[0062] [00062] A pin 236 (shown schematically in figure 8) is attached to the second gear 230 and extends upwards from it. The pin 236 is located towards the center of the second gear 230 and directly engages the teeth of the Geneva 238 type gear, which is dimensioned and built to rotate 10 degrees for each complete rotation of the second gear 230, that is, for each bypass switching. The Geneva 238 type gear is attached to the second side shaft 240 which is directly connectable to the mechanical bypass position indicator 242, which shows the positions of the bypass switch N, 1-16L and 1-16R arranged in a configuration circular, similar to the front of a clock. A second side shaft 240 is also connected to an extension shaft that extends through a plurality of circuit boards 244. Eccentric conductive arms are attached to the extension shaft and engage the contacts mounted to the circuit boards 244 during rotation of the extension axis, thereby generating signals representative of the position of the main transmission axis 122 (and the current derivation position of the tap-changer assembly 12). Said signals are provided to the external devices.
[0063] [00063] With reference now also to figure 16, a cam 248 is attached to the Geneva type 238 gear in order to rotate with it. The lateral surface of a central region of the cam 248 helps to define an endless groove 250. The central region is substantially circular except for a dent 252. Thus, the groove 250 has a radially external portion (outside the dent 252) and a portion radially internal (within the indentation). A cam follower 254 (shown in figure 13) is arranged in the groove 250 and is attached to an arm 256 which is pivotally mounted to a first end of the shelf 208. A structure with a block 260 projecting from it is fixed to the second end of the arm 256. The block 260 is movable between an engaged position and an uncoupled position. In the engaged position, the block 260 extends below the manual crank gear 214, where it can be contacted by the block 218. In the disengaged position, the block 260 does not extend below the manual crank gear 214 and thus cannot be contacted by block 218. Block 260 is moved between the engaged and disengaged positions by the movement of the arm 256, which is controlled by the movement of the groove 250 with respect to the cam follower 254. When the cam follower 254 is in the radially outer portion of the slot 250, the arm 256 is stationary and keeps the block 260 in the disengaged position. When cam follower 254 moves into the radially inner portion of groove 250 (speaking relatively), cam follower 254 moves radially inward, which causes arm 256 to pivot inward and move the block 260 to the engaged position. When block 260 moves to the engaged position, it will be contacted by block 218 on hand crank gear 214 if hand crank gear 214 completes its current revolution in its current direction and attempts to continue moving in the same direction. The contact between the blocks 218, 260 prevents further movement of the hand crank gear 214 in its current direction and is considered a "rigid mechanical stop".
[0064] [00064] The rigid mechanical stop is implemented to prevent the tap-changer 12 from going from position 16R through neutral and then to position 1R, and to prevent the tap-changer 12 from going to position 16L through neutral and then to the 1L position. In other words, the rigid mechanical stop prevents a 360 ° or greater rotation of the first and second contact arms 58, 60 in one direction. Due to the contact point of blocks 218, 260, the mechanical rigid stop does not have to be implemented immediately in 16L and 16R. Instead, the main drive shaft 122 may be allowed to rotate by about another 90 ° ahead of 16L and ahead of 16R. The electronic rigid stop and the mechanical hard stop can be configured to be implemented in about the same time. Alternatively, the electronic rigid stop and the mechanical hard stop can be configured so that one is implemented before the other. For example, the electronic hard stop and the mechanical hard stop can be configured so that the electronic hard stop is implemented first.
[0065] [00065] Since the cam 248 rotates 10 degrees for each tap changeover, the movement from neutral to 16L and from neutral to 16R corresponds to the rotation of cam 248 by 160 °. Thus, the cam 248 is constructed and positioned so that the cam follower 254 will be in the radially outer portion of the groove 250 by 160 ° of rotation of the cam 248 either clockwise or counterclockwise from the neutral position and after it will enter the radially internal portion (speaking relatively) to move block 260 to the engaged position. Thus, the radially internal portion of the groove comprises about 40 ° of the groove 250 and when the tap-changer assembly 12 is in the neutral position, the indentation center 252 is arranged in opposition to the cam follower 254.
[0066] [00066] With particular reference to figure 8, disk 262 of an absolute multiturn encoder ("MTAE") 264 is connected to the first side axis 232 in order to rotate with it. Disk 262 is composed of glass or plastic and has a pattern formed on it, such as by photographic deposition. The pattern comprises a series of runways that extend radially. Each track is comprised of areas of different optical properties, such as areas of transparency and opacity. A detection unit 266 of the MTAE 264 reads said tracks as the disk 262 rotates and emits a position signal representative of the angular position of the first side axis 232. The detection unit 266 includes infrared emitters and receivers. The infrared emitters are mounted on one side of the disk 262 and the infrared receivers are mounted on the other side of the disk 262. When the disk 262 rotates, the light pattern of each track received by the infrared receivers produces a unique code that represents an absolute position of the first side axis 232 on 360 °.
[0067] [00067] A plurality of MTAE 264 code carriers 267 is also connected to the first side axis 232 in order to rotate with it, but in a sequentially reduced mode. Each of the code holders 267 is a magnetic body comprised of alternating north and south poles. The magnetic fields generated by the rotation of the code carriers 267 are detected by the detection unit 266 to provide a measure of the number of rotations of the first side axis 264.
[0068] [00068] Since the positions of disk 262 and code carriers 267 are not changed with a power failure, the MTAE 264 does have a built-in 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 4096 rotations of the first side axis 232. Also in the said mode, the MTAE 264 has 33,554,432 positions per revolution of the first side axis 232. The absolute position of the axis of first side 232 over 360 ° and measuring the number of rotations of the first side axis 232 provides a "multi-turn position" (or simply "position") of the first side axis 232. Through the relationships described here, the position of the first side axis 232 is used to determine the position of the main drive shaft 122, the location of the tap-changer 12 within a tap-changer and the location of the tap-changer 12 between the taps, i.e., the position of derivation.
[0069] [00069] The MTAE 264 is connected to the monitoring system 134 by a communication line, such as an EnDat 2.2 interface cable, which is a digital, bidirectional interface that is capable of transmitting the position of the first side axis 232 from of the MTAE 264 as well as transmitting or updating the information stored in the MTAE 264 (such as diagnostic data). In addition to being connected to MTAE 264, monitoring system 134 is connected to a servo unit 126, a vacuum switch monitoring system (VI) 265 and several other inputs, such as environmental monitoring / control devices inside the housing 20. The monitoring system 134 is embedded in a housing unit 268 (shown in figure 13) mounted inside the housing 20. The monitoring system 134 comprises the human machine interface HMI 146, at least one microprocessor 270 and a non-volatile memory 272, such as EEPROM. HMI 146 includes a display and input devices, such as pressing keys on a membrane keyboard.
[0070] [00070] Referring now to figure 17, a schematic drawing of the VI 265 monitoring system is shown, which in general 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 a differential signal transceiver 282. On each circuit 30, the current detector module 276 is connected in series with the vacuum switch 54. When current above 6 amperes passes through the vacuum switch 54, the current detector module 276 rectifies the sinusoidal current to generate electrical pulses having a frequency that corresponds to the frequency of the current, which is in a range of 50 Hz to 60 Hz. The rectification of the sinusoidal current it can be a full wave or half wave rectification. In one embodiment of the present invention, the rectification of the sine current is half wave in order to produce a pulse per sine wave. The infrared emitter 278 converts the electrical pulses into pulses of light and transmits them to the infrared receiver 280 over a 284 fiber optic link. The infrared receiver 280 detects the light pulses and generates a pulsed electrical signal in response to the same. Said signal, which is a single-ended signal, is then transmitted to the differential signal transceiver 282. As is known, a single-ended signal is transmitted over two wires, one of which carries a varying voltage that represents the signal , while the other of which is connected to the reference voltage, in general earth. The differential signal transceiver 282 converts the signal from one end only to a digital differential signal, that is, two complementary signals that are transmitted on two separate wires. The differential signal transceiver 282 can be built according to the RS-422, RS-485 or Ethernet protocols. In one embodiment, the 282 differential signal transceiver is built according to the RS-485 protocol, which defines the electrical characteristics of actuators and receivers for use in balanced digital multi-point systems. The conversion of the signal from one end only to a differential signal helps to isolate the signal from the environmental noise sent in and around the tap-changer 10.
[0071] [00071] The differential signals generated by the differential signal transceiver 282 are transmitted to the monitoring system 134 over wires. Within the monitoring system 134, the differential signal receivers convert the differential signals back into single-sided signals, which are then provided to the microprocessor 270. The microprocessor 270 analyzes the time of the signals and the phase relationship between the three signals to monitor and control a bypass switch. More specifically, during certain stages of a bypass switching, the current must not be flowing through any of the vacuum switches 54 and at other stages of the bypass switching, the current must be flowing through the vacuum switches 54 and must be separated by 120 ° between the phases. The presence of pulses in a signal for a vacuum switch 54 provides an indication to the microprocessor 270 that current is flowing through the vacuum switch 54. Conversely, the absence of pulses in a signal for a vacuum switch 54 provides an indication to the microprocessor 270 that the current is not flowing 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 the current is flowing) must correspond to a 120 ° difference between the phases.
[0072] [00072] Referring now to figure 18, a simplified graphical representation of a bypass switching map 288 is shown which is stored in the memory 272 of the monitoring system 134 and which is used by the monitoring system 134 to control and / or monitor the operation of the tap-changer assembly 12 during a tap-switching procedure. Map 288 includes stages or A-H operations delimited by dotted lines. AH operations correspond to "on position", "bypass switch open", "vacuum switch (VI) open", "selector switch open", "selector switch closed", "VI closed", "bypass switch closed" and "on position", respectively. The shaded blocks on the dotted lines indicate ± margins in degrees of rotation. The location of tap-changer set 12 within map 288 is based on the position of the first side axis 232, which is obtained from a position signal from MTAE 264. The position just before operation D ("selector 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 disconnected from an initial tap (initial stationary contact 56) as it is being moved to a terminating tap ( terminating stationary contact 56) during a bypass switch. If monitoring system 134 receives or generates an alarm on or after PONR, monitoring system 134 will cause tap-changer assembly 12 to complete tap-switching and then lock servo unit 126. If, however, the monitoring system 134 receives or generates an alarm before PONR, monitoring system 134 will cause tap-changer assembly 12 to stop tap-switching, back to the previous tap-off position and then lock servo unit 126.
[0073] [00073] The tap switching map 288 stored in memory 272 of monitoring system 134 is more detailed than is graphically shown in figure 18. Map 288 includes AH operations for tap tap switching from tap tap to tap tap. other. In addition, for tap-off switching from 1L to N and N to 1L, map 288 additionally includes data for a switch switch 36, i.e., open and closed switch. For each operation, the map 288 includes the degrees of rotation of the first side axis 232 in which the operation starts the elapsed time (from the beginning of the tap changeover) in which the operation must be started, the change in the elapsed time (delta time) that should occur from the start of the previous operation and the number of pulses that should / should be received from the VI 265 monitoring system during the delta time to indicate whether current is flowing through the vacuum switch relevant 54. Thus, the delta time is the time window within which the monitoring system 134 decides whether the tap-changer is proceeding properly (with respect to the current through the vacuum switch 54). The elapsed time values stored on map 288 are in milliseconds. In this regard, it is observed that the monitoring system 134 is programmed to control the servo motor 124 to perform a tap-changeover in one of the two periods of time, i.e., 1 second and 2 seconds. Thus, map 288 includes the data for the operations described above either for a second tap changeover 1 or the second tap changeover 2. However, the values for map 288 can be changed from those for the second tap changeover 1 for those for the second tap-changer 2 and vice versa at the factory where tap-changer 10 is manufactured or by authorized maintenance staff in the field when tap-changer 10 is closed for maintenance. In another embodiment of the present invention, map 288 includes data for the operations described above not only for the second tap changeover 1, but also for the second tap changeover 2 and a user can select the second tap changeover 1 or the second tap changeover 2 via HMI 146 or from a remote location.
[0074] [00074] It should be noted that in addition to the map 288, the rotation speed of the motor axis 174 for the second tap changeover 1 and / or the second tap changeover 2 is / are stored in memory 272. Additionally, the plus and minus feedback units that are used to implement the electronic hard stop are stored in memory 272. The stored speed for the programmed / selected tap-off switching (1 or 2 seconds) is provided to the servo unit 126 (ie, the speed record 189) in case the power is cut to the servo unit 126, as described in more detail below. Similarly, the plus and minus feedback units to implement the electronic rigid stop are provided to the servo unit 126 (that is, the stop record plus 190 and the stop record minus 191, respectively) in case the power is cut to the servo unit 126, also as described in more detail below.
[0075] [00075] The monitoring system 134 performs routines implemented by software to monitor and control the operation of the tap-changer assembly 12. The software code for said routines is stored in the memory 272 of the monitoring system 134 and is executed by the microprocessor 270 One of the routines is the power restore routine 290 (shown in figure 19) that is implemented when the power to the monitoring system 134 and / or the servo unit 126 is cut and then re-stored. As determined above, when power to servo unit 126 is lost, all data stored in speed record 189, stop record plus 190, stop record minus 191 and feedback record 192 are lost and with restoration of energy, the values in the registers are set to zero. When the power to the monitoring system 134 is restored after the power failure, a boot program is automatically started at step 292 of the power restore routine 290. The boot program performs a boot procedure that includes: (i.) read parameters from memory 272, (ii.) establish communication with servo unit 126 (iii.) establish communication with MTAE 264, (iv.) determine the current of the tap position of tap switch assembly 12 based on information from MTAE 264, (v.) adjust an event log and (vi.) emit 4-20 mA signals representative of the current tap position for the automatic voltage regulator for the transformer. Although communication is established with the servo unit 126, the monitoring system 134 does not provide the H / W permission signal or the NMS permission signal for the servo unit 126.
[0076] [00076] Once the boot program has finished running, the energized state is started at step 294. The energized state has four sub-states or modes that are determined by the switch, namely: local, crank, remote and off. The three inputs (local, crank and remote) from the switch are mutually exclusive. If none of the three entries are declared, the "off" sub-state is initiated.
[0077] [00077] After the monitoring system 134 initiates the energized state, a determination is made in step 296 of whether the monitoring system 134 is in the local mode or in the remote mode. If monitoring system 134 is either in local or remote mode, routine 290 proceeds to step 298, where the H / W enable signal is transmitted to servo unit 126 via digital inputs on the drive interface 202. After step 298, the monitoring system 134 proceeds to step 300, where the position (0-360 ° and number of revolutions) of the first side axis 232 measured by MTAE 264 is converted to the position units ( for example, counts) of the motor shaft 174 measured by the feedback device 180, that is, the motor shaft position units 174 are calculated from the position output by MTAE 264. The calculated position units are then transmitted to the servo unit 126 on the CAN bus 200 in step 302 and are stored in the feedback register 192 therein. Also in step 302, the values for the rotation speed of the motor shaft 174 and the feedback units plus and minus to implement the electronic rigid stop are transmitted to the servo unit 126 on the CAN 200 bus and are stored in the speed record 189, the stop record plus 190 and the stop record minus 191, respectively. Then, the monitoring system 134 proceeds to step 306 in which routine 290 determines whether tap switch set 12 is tapped off, that is, they are tap taps, using information from MTAE 264. If the tap switch set branch 12 is not branch off, the routine proceeds directly to step 308. If, however, branch switch set 12 is branch off, monitoring system 134 proceeds to step 310, where monitoring system 134 determines if tap switch assembly 12 is before PONR, or if it is at or ahead of PONR. If tap-changer set 12 is before PONR, monitoring system 134 sends an instruction in step 312 on CAN bus 200 to servo unit 126 to control servo motor 124 to move tap-changer set 12 back to the previous lead. If branch switch assembly 12 is at or after PONR, monitoring system 134 sends an instruction in step 314 over CAN bus 200 to servo unit 126 to control servo motor 124 to move branch switch assembly 12 to forward to the next lead. After step 312 or step 314, the monitoring system 134 proceeds to step 316, in which the monitoring system 134 clears the servo unit 126 to determine whether the movement of the tap-changer assembly 12 is complete. If this is the case, the monitoring system 134 proceeds to step 308 in which an NMS enable signal is transmitted to the servo unit 126 via the digital inputs on the drive interface 202. At that point, the tap-changer assembly 12 is in normal operation in remote on mode or in normal operation in local on mode, as the case may be.
[0078] [00078] If only the servo unit 126 loses power, the boot program is not started and the power restoration routine starts at step 298.
[0079] [00079] It should also be noted that when monitoring system 134 is in crank mode or in off mode and then is moved to either local or remote mode, monitoring system 134 performs steps 298 and after. This occurs regardless of whether there was a power failure or not.
[0080] [00080] In addition to performing the power restoration routine 290, the monitoring system 134 also performs the monitoring routine 320 which inspects each bypass switching operation. The monitoring system 134 uses the tap switching map 288 stored in memory 272, the position of the first side axis 232 from the MTAE 264 and information from the VI 265 monitoring system to perform the monitoring routine 320. When a command for a bypass switch is made (for example, a lift command is issued from the lower / lift switch 152), monitoring system 134, in step 322, first determines whether the bypass switch is starting from a valid derivation position. If tap switch assembly 12 is a disconnected tap, monitoring system 134 proceeds to step 323, where monitoring system 134 denies the NMS permission signal to servo unit 126 and then returns to routine 290 and performs step 310 and the steps after. Upon completion of step 308, monitoring system 134 returns to routine 320 and then allows the tap-changer to proceed to open tap-changers (66 or 68) in operation B. If the tap-changer assembly is determined to be in derivation connected in step 322, the monitoring system 134 allows the derivation switch to proceed directly to open the derivation switches (66 or 68) in operation B. The monitoring system 134, in step 324, determines whether the derivation switches tap (66 or 68) opened (as determined from the position of the first side axis 232) within a predetermined period of time from the start of the tap switch. If tap-changers have been opened at the right time, monitoring system 134 proceeds to step 326, where monitoring system 134 determines whether current is flowing through all vacuum switches 54. If current is flowing Through all vacuum switches 54, the monitoring system 134 allows the tap-changer to proceed to open the contacts of the vacuum switches 54 in operation C. The monitoring system 134, in step 328, determines whether the contacts of the switches vacuum 54 have been opened (as determined from the position of the first side axis 232) within a predetermined period of time from the tap-changers (66 or 68) being opened. If the vacuum switch 54 contacts have been opened at the right time, monitoring system 134 proceeds to step 330 to determine that no current is flowing through any of the vacuum switch 54. If the vacuum switch contacts 54 have been opened at the right time and no current is flowing through the vacuum switches 54, monitoring system 134 allows the tap switch to continue to move the first contact arm 58 or the second contact arm 60 to the next tap and to close the contacts of the vacuum switches 54. In step 332, the monitoring system 134 determines whether current is flowing through the vacuum switches 54 within a predetermined period of time from the closing of the contacts of the vacuum switches 54 (as determined from the position of the first side axis 232). If current is flowing through the vacuum switches 54 within the predetermined period of time from the closure of the vacuum switch contacts 54, the monitoring system 134 allows the tap-changer to continue to close the tap-changers (66 or 68). In step 334, the monitoring system 134 determines whether the tap-changers (66 or 68) have been closed (as determined from the position of the first side axis 232) within a predetermined period of time from the closing of the contacts of vacuum switches 54. If tap-changers (66 or 68) were closed at the right time, monitoring system 134 determines in step 336 that tap-tap switching has been completed successfully.
[0081] [00081] If, during the previous monitoring routine 320, any of the determinations is negative, the monitoring system 134 will first either stop the tap switch and return to the initial tap or complete the tap switch, depending on where the tap negative determination is, and then it will lock servo unit 126. If the determination is negative at step 332 or after, monitoring system 134 will instruct servo unit 126 to complete the tap changeover at step 338 and then lock the servo unit 126 in step 340. If the determination is negative in step 330 or earlier, the monitoring system 134 will instruct the servo unit 126 to stop the tap switching and go back to the initial tap in step 344 and then lock the unit servo 126 at step 346.
[0082] [00082] After each determination in the monitoring routine 320, the monitoring system 134 makes an entry in the log case describing the result of the determination. For some of the negative determinations, the monitoring system 134 will include the probable cause of the problem in the entry. For example, if there is a negative determination in step 324, the monitoring system 134 will include in the case in the log entry that there is a fault in the tap-changer.
[0083] [00083] After a bypass switch has been successfully performed, monitoring system 134 monitors servo unit 126 to ensure that servo unit 126 is holding servo motor 124 in place in order to maintain the current bypass position. If the monitoring system 134 sees that the output of the servo unit 126 moves within a predetermined amount of deviation, the monitoring system 134 will move the output of the servo unit 126 back. If, however, the output of the servo unit 126 moves beyond the predetermined amount of deviation, the monitoring system 134 will emit an alarm and lock the servo unit 126.
[0084] [00084] In place of monitoring routine 320, other monitoring routines can be implemented to inspect a bypass switching operation. For example, in another modality, monitoring routine 420 can be implemented, as shown in figure 21. When a command for a branch switch is made (for example, a lift command is issued from the lower / lift switch) 152), the monitoring system 134, in step 422, first determines whether the tap switching is starting from a valid tap position. If tap switch assembly 12 is a disconnected tap, monitoring system 134 proceeds to step 423, where monitoring system 134 denies the NMS permission signal to servo unit 126 and then returns to routine 290 and performs step 310 and the steps after. Upon completion of step 308, monitoring system 134 returns to routine 420 and then allows the tap-changer to proceed to open tap-changers (66 or 68). If the tap-changer assembly is determined to be tapping in step 422, monitoring system 134 allows tap tapping to proceed directly to open tap taps (66 or 68) in operation B. In step 424, the tapping system monitoring 134 determines whether the current is detected through all vacuum switches 54 for a minimum amount of time in the period between operations B and C. If the current is detected through all vacuum switches 54 for the minimum amount of time , the monitoring system 134 allows the tap-changer to proceed to open the contacts of the vacuum switches 54 in operation C. In step 426, the monitoring system 134 determines whether no current is detected through all of the vacuum switches 54 in the period between operations C and D. If no current is detected through all vacuum switches 54, monitoring system 134 allows tap-changer switching proceed to open the first contact arm 58 or the second contact arm 60 in operation D, that is, to move the first contact arm 58 or the second contact arm 60 out of the start taps (start stationary contacts 56 ) in a bypass switch. In step 428, monitoring system 134 determines whether current is detected through all vacuum switches 54 in the period between operations D and E. If no current is detected through all vacuum switches 54, the monitoring system 134 allows the tap-changer to proceed to close the first contact arm 58 or the second contact arm 60 in operation E, that is, to move the first contact arm 58 or the second contact arm 60 in engagement with the taps terminals (final stationary contacts 56) in a tap-changer. In step 430, monitoring system 134 determines whether 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 monitoring system 134 allows the tap-changer to proceed to close the contacts of vacuum switches 54 in operation F. In step 432, monitoring system 134 determines whether current is detected through all vacuum switches 54 for the minimum amount of time in the period between operations F and G. If the current is detected through all vacuum switches 54 for the minimum amount of time, the monitoring system 134 allows the tap-changer to proceed to close the tap-changers (66 or 68 ) in operation G and complete the tap changeover in operation H. In step 436, the monitoring system 134 determines whether the entire tap changeover has been carried out within the ne The required amount of time, which is slightly less than 1 second for the second tap 1 and slightly less than 2 seconds for the second tap switch 2. If the tap switch was completed in time, the monitoring system 134 determines that the tap changeover was successfully completed in step 438. If the tap changeover was not completed in time, the monitoring system 134 determines that there is a problem and locks the servo unit 126 in step 442.
[0085] [00085] If, during the previous monitoring routine 420, any one of the determinations is negative, the monitoring system 134 will first either stop the tap switch and go back to the initial tap or complete the tap switch, depending on where the negative determination is, and then it will lock the servo unit 126. If the determination is negative at step 428 or after, the monitoring system 134 will instruct the servo unit 126 to complete the tap changeover at step 440 and then lock the servo unit 126 in step 442. If the determination is negative in step 426 or earlier, monitoring system 134 will instruct servo unit 126 to stop tap tap change and go back to the initial tap in step 444 and then lock servo unit 126 in step 446.
[0086] [00086] Unlike monitoring routine 320, monitoring routine 420 does not check the time of operations during the performance of the tap switching. Routine 420 only checks the overall time of the tap switch at its completion in step 436. It should be noted that routine 420 can be modified to additionally include one or more time checks during tap switch performance. For example, a time determination can be made before PONR, such as if the contacts of the vacuum interrupters 54 opened in operation C within a predetermined amount of time for the start of the tap changeover in operation A. If the contacts of the vacuum switches 54 are not open within the predetermined amount of time, monitoring system 134 can proceed to step 444 and then lock servo unit 126 in step 446. Additionally, or alternatively, time determination can be made after the PONR. For example, the determination can be made if the contacts of the vacuum switches 54 are closed in operation F within a predetermined amount of time from the closure of the first contact arm 58 or the second contact arm 60 in operation E. If the contacts of the vacuum interrupters 54 are not closed within the predetermined amount of time, the monitoring system 134 can proceed to step 440 and then lock the servo unit 126 in step 442.
[0087] [00087] In previous descriptions of routines 320, 420, references to monitoring system 134 allowing the tap switching to continue after determination should not be constructed in such a way as to mean that the tap switching procedure awaits the monitoring system 134 to make your determination before the bypass switching procedure continues. The tap switching proceeds continuously and the monitoring system 134 makes its determinations within the delta times between the various operations. Bypass switching is stopped only if an error is detected.
[0088] [00088] In addition to the monitoring routine 320 or 420, the monitoring system 134 performs other monitoring activities, too. For example, the monitoring routine 134 continuously monitors the position of the first side axis 232 measured by MTAE 264 and the position of the motor axis 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 servo unit 126 (after allowing a tap-changer to continue or move back to the initial tap, as the case may be). The monitoring system 134 also monitors the three signals from the VI 265 monitoring system to ensure that the pulse displacement between the three signals (when the current is flowing) corresponds to the 120 ° difference between the phases. If they do not match, monitoring system 134 will generate an alarm. In addition to generating an alarm, the monitoring system 134 can also lock the servo unit 126, as described above.
[0089] [00089] Another operation performed by the monitoring system 134 is the return to neutral operation. The return to neutral operation can be performed when the monitoring system 134 is either in local or remote mode. When said operation is initiated, the monitoring system 134 causes the servo motor 126 to move the tap-changer assembly 12 to the neutral position, regardless of where the tap-changer assembly 12 is currently located. The return to neutral operation can be initiated by an operator who activates the return to neutral switch 150 on the oscillation plate 138, or by activating a return to neutral switch located in a remote location, such as a control room or a control cabin nearby.
[0090] [00090] An additional operation performed by the monitoring system 134 is a displacement operation, which can only be performed when the monitoring system 134 is in local mode. The shifting operation is carried out in conjunction with the lowering / raising operation, which will be described first. The lowering / raising operation can be carried out in a continuous mode (which is the default) or in a step-by-step mode. The lowering / raising operation can be performed using the lowering / raising switch 152 on the oscillation plate 138 when the monitoring system 134 is in local mode, or the lowering / raising switch in a remote location when the monitoring system 134 is in remote mode. When the lower / raise switch is operated in continuous mode, tap-changer assembly 12 continues to make tap-changers (to lower or raise the voltage through main winding 34, depending on whether the switch is operated to lower or raise ) for as long as the switch is held in the actuated position. When the lower / raise switch is operated in step-by-step mode, tap-changer assembly 12 only makes a tap-switch (to lower or raise the voltage through main winding 34, depending on whether the switch is pushed to lower or lift) regardless of how long the switch is held in the triggered position. In order to make another bypass switch, the switch must be moved to its off state and then operated again to raise or lower. The travel operation is initiated by an operator by first pressing the travel button on HMI 146 and then activating the lower / raise switch 152 on the oscillation plate 138. When the travel operation is initiated, the monitoring system 134 causes the the servo unit 126 moves the servo motor 124 at a much slower coefficient than when a normal lift / lower operation is performed. By comparison, the motor shaft speed 174 during the second tap changeover 1 is 1300 RPM and during the second tap changeover 2 is 650 RPM. During the travel operation, the speed of the motor shaft 174 is about 150 RPM. Thus, the speed of the motor shaft 174 during the travel operation is about 8.6 times slower than the second tap changeover 1.
[0091] [00091] Yet another operation performed by the monitoring system 134 is a transformer turn ratio (TTR) operation. The TTR operation can be performed when the monitoring system 134 is either in local or remote mode. When the TTR operation is initiated, the monitoring system 134 causes the servo motor 126 to move the tap-changer assembly 12 through the predetermined sequence of tap-changers for testing purposes. The predetermined sequence can be from neutral to 16R, and then back to neutral and then 1-16L, or just from neutral to 16R, or just from neutral to 16L, or some other sequence. As with the displacement operation, the TTR operation is performed in conjunction with the lower / raise operation. More specifically, a TTR key on HMI 146 or a TTR key at a remote location is first triggered. Then the lowering / raising switch 152 on the oscillation plate 138 or a remote lowering / raising switch is activated. Regardless of whether the lower / raise switch is activated to lower or raise, the monitoring system 134 causes the servo motor 126 to move the tap-changer assembly 12 through the predetermined sequence of tap-changers.
[0092] [00092] It should be understood that the description of the previous exemplary mode (s) is (are) intended to be (are) only illustrative, rather than exhaustive (s) ) of the present invention. Those skilled in the art will be able to perform certain additions, deletions, and / or modifications to the mode (s) of the objective described without departing from the spirit of the present invention or its scope, as defined in the appended claims.

权利要求:
Claims (14)
[0001]
On-load tap-changer (10) for switching taps on a transformer winding, the tap-changer (10) comprising: a tap-changer module (12) connected to the transformer winding and comprising a bypass switch assembly (50), a vacuum switch assembly (52) and a selector switch assembly (48); a servo motor (124) comprising: a motor shaft (174) connected to the tap-changer module (12) and operable, with rotation, to cause the tap-changer module (12) to perform a sequence of operations that effect a tap-changer; a feedback device (180) operable to generate a feedback signal containing information relating to the position of the motor shaft (174); and a servo unit (126) connected to the servo motor (124) to receive the feedback signal, the servo unit (126) using the feedback signal to determine and store the total angular displacement of the motor shaft (174), the servo unit (126) using the feedback signal and the total angular displacement of the motor shaft (174) to control the operation of the servo motor (124), characterized by the fact that the feedback device (180) is an absolute encoder of multiple turns.
[0002]
On-load tap-changer (10) according to claim 1, characterized in that the servo unit (126) stores a maximum angular displacement and in which the servo unit (126) automatically stops the rotation of the motor shaft ( 174) when the total angular displacement of the motor axis (174) reaches the maximum angular displacement.
[0003]
On-load tap-changer (10) according to claim 2, characterized by the fact that the maximum angular displacement is a first maximum angular displacement and is for a first direction of rotation of the motor shaft (174); wherein the servo unit (126) stores a second maximum angular displacement for a second direction of rotation of the motor shaft (174); wherein the servo unit (126) automatically stops the rotation of the motor shaft (174) when the total angular displacement of the motor shaft (174) in the first direction reaches the first maximum angular displacement; and wherein the servo unit (126) automatically stops the rotation of the motor shaft (174) when the total angular displacement of the motor shaft (174) in a second direction reaches the second maximum angular displacement.
[0004]
On-load tap-changer (10) according to claim 3, characterized by the fact that the transformer winding is a regular winding (32) connected to a main winding (34) by a toggle switch (36) that allows the voltage across the regular winding (32) is added to or subtracted from the voltage across the main winding (34) to generate a total voltage across the regular winding (32) and the main winding (34).
[0005]
On-load tap-changer (10), according to claim 4, characterized in that the rotation of the motor shaft (174) in the first direction moves the switch (36) to a lifting position that causes the subsequent rotation of the motor shaft (174) in the first direction to effect tap-off taps that raise the total voltage through the regular winding (32) and the main winding (34), while the rotation of the motor shaft (174) in the second direction moves the toggle switch (36) to a lower position which causes the subsequent rotation of the motor shaft (174) in the second direction to make tap-changer switches that reduce the total voltage through the regular winding (32) and the main winding (34) .
[0006]
On-load tap-changer (10) according to claim 5, characterized by the fact that the selector switch set (48) comprises a pair of selector switches and a plurality of fixed contacts (56) connected to the derivations of the regular winding (32), the fixed contacts (56) being arranged in a circle and including a neutral contact (N), a maximum lift contact (16R) and a maximum reduction contact (16L), the selector switches each being able to rotate around a central axis of the circle in order to move in engagement with the different fixed contacts (56); where after rotating the motor shaft (174) in the first direction moving the toggle switch (36) to the lifting position, the subsequent rotation of the motor shaft (174) in the first direction causes the selector keys to rotate in a first switching direction from engagement with the fixed neutral contact (N) to engage with the other of the fixed contacts (56), thereby making tap-off taps that raise the total voltage through the regular winding (32) and the main winding (34); and where after rotating the motor shaft (174) in the second direction moving the switch switch (36) to the lowest position, the subsequent rotation of the motor shaft (174) in the second direction causes the selector keys to rotate in a second switching direction from engagement with the fixed neutral contact (N) to engage with the other of the fixed contacts (56), thereby making tap-off switches that reduce the total voltage through the regular winding (32) and the main winding (34).
[0007]
On-load tap-changer (10), according to claim 6, characterized by the fact that when the selector switches are engaged with the maximum lift contact (16R) after turning in the first switching direction, the regular winding (32) is adding a maximum amount of tension to the tension across the main winding (34); where when the selector switches are engaged with the maximum reduction contact (16L) after turning in the second switching direction, the corresponding regular winding (32) is subtracting a maximum amount of voltage from the voltage across the main winding (34) ; where when the servo unit (126) stops the motor shaft rotation (174) when the total angular displacement of the motor shaft (174) in the first direction reaches the first maximum angular displacement, the servo unit (126) prevents the selector switches are moved substantially beyond the maximum elevation contact (16R) in the first switching direction; and where when the servo unit (126) stops the motor shaft rotation (174) when the total angular displacement of the motor shaft (174) in the second direction reaches the second maximum angular displacement, the servo unit (126) prevents the selector switches are moved substantially beyond the maximum reduction contact (16L) in the second switching direction.
[0008]
On-load tap-changer (10) according to claim 1, characterized in that it additionally comprises: a drive shaft (122) connecting the motor shaft (174) to the tap-changer module (12); a hand crank gear (214) attached to the drive shaft (122); a crank device (216) engaged with the manual crank gear (214), the crank device having a socket (142) with a connector (222) disposed therein, the connector (222) being adapted to engage an end of a crank rod; wherein the rotation of the connector (222) causes the crank device to rotate the manual crank gear (214) and thus the transmission shaft (122); a switch (140) mounted next to the crank device (216), the switch (140) being connected to the servo unit (126) and having a switch rod (223) which is movable between at least a first position, where the switch rod (223) causes the switch (140) to disconnect power to the servo unit (126), and a second position where the switch rod (223) causes the switch (140) to connect power to the unit servant (126); and a locking structure (224) connected to the switch rod (223) so as to be movable with it, the locking structure (224) blocking access to the socket (142) when the switch rod (223) is in the second position and allowing access to the socket (142) when the switch rod (223) is in the first position.
[0009]
On-load tap-changer (10) according to claim 1, characterized in that it additionally comprises: a drive shaft (122) connecting the motor shaft (174) to the tap-changer module (12); a first locking structure (218) connected to the drive shaft (122) so as to rotate with it; a first gear (238) connected to the drive shaft (122) so as to turn when the drive shaft (122) turns; a second locking structure (260) movable between an engaged position, wherein the second locking structure (260) is in a position where it can be contacted by the first locking structure (218), and the disengaged position, in which the second locking structure (260) cannot be contacted by the first locking structure (218); a rigid stop actuator (248, 256, 250, 254) connected to the first gear (238) and the second locking structure (260), the rigid stop actuator (248, 256, 250, 254) being operable to move the second locking structure (260) from the disengaged position to the engaged position after the drive shaft (122) rotates a predetermined amount; and wherein the continued rotation of the drive shaft (122) after the predetermined amount causes the first locking structure (218) to contact the second locking structure (260), thereby preventing further rotation of the drive shaft (122).
[0010]
On-load tap-changer (10) according to claim 9, characterized by the fact that the rigid stop actuator (248, 256, 250, 254) comprises: a cam (248) attached to the first gear (238) so as to rotate with it, the cam (248) defining an endless groove (250) having a radially internal portion and a radially external portion; an arm (256) having a first end portion pivotally mounted to a support and the second end portion fixed to the second locking structure (260), the arm (256) being pivotable to move the second locking structure (260) between the disengaged and engaged positions; a cam follower (254) attached to the arm and arranged in the endless groove (250) of the cam (248); and wherein the relative movement of the cam follower (254) between the radially inner and outer portions of the endless groove (250) causes the arm (256) to move the second locking structure (260) between engaged and disengaged positions.
[0011]
On-load tap-changer (10) according to claim 9, characterized by the fact that the transformer winding is a regular winding (32) connected to a main winding (34) by the switch (36) that allows the voltage across the regular winding (32) is added or subtracted from the voltage across the main winding (34) to generate the total voltage across the regular winding (32) and the main winding (34); wherein the first and second locking structures (218, 260) come into contact with each other after a predetermined number of bypass switching has been carried out to add voltage across the regular winding (32) and the main winding (34); and wherein the first and second locking structures (218, 260) come into contact with each other after a predetermined number of tap-changers have been carried out to subtract voltage through the regular winding (32) and the main winding (34).
[0012]
On-load tap-changer (10) according to claim 11, characterized in that the servo unit (126) stores a first maximum angular displacement and a second maximum angular displacement; wherein the servo unit (126) automatically stops the rotation of the motor shaft (174) when the total angular displacement of the motor shaft (174) in a first direction reaches the first maximum angular displacement; wherein the servo unit (126) automatically stops the rotation of the motor shaft (174) when the total angular displacement of the motor shaft (174) in a second direction reaches the second maximum angular displacement; wherein the total angular displacement of the motor shaft (174) in the first direction reaches the first maximum angular displacement after the predetermined number of tap-changers have been carried out to add tension through the regular winding (32) and the main winding (34) ; in which the total angular displacement of the motor axis (174) in the second direction reaches the second maximum angular displacement after the predetermined number of tap-changers have been carried out to subtract voltage through the regular winding (32) and the main winding (34) ; and wherein the total angular displacement of the motor axis (174) in the first direction reaches the first maximum angular displacement before the first and second locking structures (218, 260) come into contact with each other.
[0013]
On-load tap-changer (10) according to claim 1, characterized by the fact that the servo unit (126) stores a rotation speed of the motor shaft (174) that is necessary to carry out a tap-changer within a predetermined period of time; and wherein the predetermined period of time can be changed by a user via a human machine interface connected to the servo unit (126).
[0014]
On-load tap-changer (10) according to claim 1, characterized in that it additionally comprises a feedback system (188) operable to determine the total angular displacement of the motor shaft (174); wherein the feedback system (188) transmits the total angular displacement of the motor shaft (174) to the servo unit (126) if the value of the total angular displacement of the motor shaft (174) stored in the servo unit (126) is lost; and wherein the feedback device (180) is a resolver and where the feedback system (188) comprises an absolute multi-turn encoder.

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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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2018-06-05| B25B| Requested transfer of rights rejected|Owner name: ABB SCHWEIZ AG (CH) |

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2018-07-10| 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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2018-12-18| 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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2020-06-30| B06A| Patent application procedure suspended [chapter 6.1 patent gazette]|

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2020-12-01| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-02-17| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|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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US201161468058P| true| 2011-03-27|2011-03-27|

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US61/468,058|2011-03-27|

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PCT/US2012/030729|WO2012135209A1|2011-03-27|2012-03-27|Tap changer with an improved drive system|

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