BR102018016439B1 - METHOD AND APPARATUS FOR CONTROLING A VOLTAGE VALUE IN A CONDUCTOR AND TRANSFORMER SYSTEM - Google Patents

Abstract

The present invention relates to a method for controlling a value of a voltage in a conductor (3) to which at least one secondary winding (5A) of a first scalable transformer (7A) and a secondary winding (5B) of a second scalable transformer (7B) are connected which is provided, wherein the method comprises: if a voltage deviation (DV) of the voltage in the conductor (3) from a value of the voltage set point is within a first range ([- BCC_DV, BCC_DV]) around the voltage setpoint value and if an overall deviation (DA, DB) of a sum of the voltage deviation (DV) and a reactive current deviation (DCCA, DCCB) from the point value voltage adjustment time, respectively, for the first and second transformers is outside a second range ([-BC, B]), which is greater than the first, around the voltage setpoint value: define a voltage adjustment time delay (T1) to scale the first transformer (7A) and/or the second transformer (7B) in such a way that the scaling of the first or second transformer that neutralizes the voltage deviation is prioritized.

Description

[001] The present invention relates to a method and an apparatus for regulating a value of a voltage in a conductor to which at least one secondary winding of a first scalable transformer and a secondary winding of a second scalable transformer are connected. The present invention further relates to a transformer system, comprising the apparatus and two scalable transformers.

[002] It is known from the prior art that two or more transformers are connected in parallel on a bus so as to distribute the energy to be distributed between the transformers so that the individual transformer is not overloaded. However, if two or more transformers are feeding into the same bus and the voltage regulators are regulating independently of each other at the voltage set point value, balancing currents may arise due to the different open circuit voltages of the transformers. Since the impedance of transformers is mainly inductive, circulating reactive currents can essentially form.

[003] Circulating reactive currents of this type are undesirable, as they can lead to greater energy loss from transformers. In addition to a voltage deviation from the value of the voltage set point value, the circulating reactive current has also been conventionally used as an additional regulation criterion of voltage regulation to minimize the circulating reactive current.

[004] In a conventional voltage regulator, a voltage band or range B is defined around the voltage set point value. If the measured voltage is outside this range, a scaling command is sent to a switch after a scalable time delay, where the voltage returns to the voltage band due to the change in the transformer's open circuit voltage. The range adjustment value is stipulated to be at least so large that the range is not passed through the setpoint value during scaling up or scaling down. Otherwise, it would result in endless scaling back and forth. With voltage regulation for parallel transformers according to the circulating reactive current method, in addition to the voltage deviation in each parallel transformer, the circulating reactive current is checked and a regulation deviation based on the circulating reactive current is added to the regulation deviation due the tension.

[005] The DCC regulation deviation resulting from the circulating reactive current can generally be calculated according to the following formula: k - configurable circulating reactive current regulation factor ICC - circulating reactive current

[006] The general deviation D is determined from the sum of the voltage deviation and the circulating reactive current deviation and is compared with the range:

[007] In the case of two parallel transformers, exactly the opposite circulating reactive current and therefore exactly the opposite circulating reactive current deviation, DCC results in the case of a difference in open circuit voltages. If the voltage measured at both transformers corresponds to the setpoint voltage, exactly the opposite overall deviation D will therefore result in both voltage regulators.

[008] For example, a first transformer A has a higher stepped level and therefore a higher open circuit voltage than a second transformer B. The DCC circulating reactive current voltage deviation is therefore positive. In this example, according to a conventional regulation method, both regulators would perform scaling to control the transformers, since in one of the transformers the reactive current deviation is greater than the range limit value and in the other transformer the reactive current deviation is less than the negative of the range limit value.

[009] After opposite scaling of both regulators, the identical case would emerge with interchangeable roles. Regulators according to the prior art subsequently escalated endlessly. The regulation thus conventionally operates in an unstable manner and unnecessary wear on the commutator may be associated therewith. Regulators would subsequently escalate endlessly. In this case, additional measures would be necessary to avoid unnecessary escalation.

[0010] Voltage regulators with two different timing characteristics have also been used conventionally. In the case of the linear time characteristic, regulation takes place using a constant regulation offset, regardless of the regulation offset. In the case of the inverse time characteristic, the delay time is inversely proportional to the regulation deviation D. The setting of the delay time for voltage deviations is prescribed by the network operator, so that superordinate coordination in radial networks is possible. Different, fixed parameterization is therefore not desired. Furthermore, in the event of a voltage drop due to the load connection, both regulators must step up after the same delay time.

[0011] In the prior art, a voltage regulator has also been proposed, in which one regulator is adjusted to be more sensitive to the circulating reactive current than the other. However, this has the disadvantage that no regulation deviation is produced in the sensitive regulator in the case of a voltage deviation within the voltage range, since DV and DCC cancel each other out and in the insensitive regulator D does not exceed the range B. Poor regulation quality can therefore be produced and the circulating reactive current is not satisfactorily corrected.

[0012] It is, therefore, an object of the present invention to provide a method and apparatus for controlling a voltage value in a conductor to which at least one secondary winding of a first scalable transformer and a secondary winding of a second scalable transformer are connected. , in which reliable control is achieved, in which wear on components, in particular wear on transformer switches, is reduced.

[0013] The objective is achieved by the subjects of independent claims. The dependent claims specify particular embodiments of the present invention.

[0014] Embodiments of the present invention utilize temporal scaling prioritization to stabilize voltage regulation. Regulator stabilization is used in the sense of temporal scaling prioritization if the voltage deviation is located within a specific band of the range. Said range-specific band is also referred to in the following text as the prioritization range, wherein the prioritization range is smaller than the conventionally used range.

[0015] According to an embodiment of the present invention, there is provided a method for controlling a value of a voltage in a conductor to which at least one secondary winding of a first scalable transformer and a secondary winding of a second scalable transformer are connected, wherein the method comprises: if a voltage deviation of the voltage in the conductor from a voltage setpoint value is within a first range around the voltage setpoint value and if a general deviation from a sum of the voltage deviation and a reactive current deviation from the voltage setpoint value respectively for the first and second transformers is outside a second range, which is larger than the first, around the voltage setpoint value: defining a delay time for scaling the first transformer and/or the second transformer such that the scaling of the first or second transformer that neutralizes the voltage deviation is prioritized.

[0016] The method can be implemented in part in hardware and/or software, in particular, it can be implemented by a computer method. The conductor to which the secondary windings of the first and second transformers are connected is also called the busbar.

[0017] Transformers can have switches of any known type. An open circuit voltage of the respective transformer can be adjusted by operating the switches. In this case, the scaling can be carried out on a primary winding or also on the secondary winding. The scaling that is performed in the primary stage can be advantageous as the current (in particular during charging operation) can be lower than the current flowing through the secondary coil due to the higher voltage in the primary winding.

[0018] To regulate the value of the voltage set point on the bus (which is electrically connected to the corresponding secondary windings of the transformers), scalable transformers are used, in which it is possible to tap at various points of the primary winding and/or the secondary winding . To scale transformers, what are known as tap switches can be used, which tap switches serve to set the transformation rate. For this purpose, the transformer winding or coil may have on the primary side and/or on the secondary side a root winding and a regulating or stepping winding having a plurality of taps, which are guided to the tap changer. Known tap switches include so-called on-load tap changers (OLTC) and diverters (no-load tap changers (NLTC), off-load tap changers (DETC) or off-circuit tap changers (OCTC)). On-load switches can be used for free switching of on-load arrangements and can be divided into on-load selectors and on-load switches. In this case, a tap-changer column can switch one or more phases, for example three phases.

[0019] To measure voltage deviation and reactive current, a measuring device can be provided, which measures the current in the secondary windings and also, in each case, the current flowing from the secondary windings to the conductor. Both the voltage deviation and the reactive current deviation can in this case be specified or defined, for example, as a proportion or a percentage of the difference between the voltage reference value or a reactive current setpoint value of zero.

[0020] An embodiment of the present invention uses an optimized calculation of the regulation deviation resulting from the circulating reactive current: k - configurable circulating reactive current control factor ICC - circulating reactive current

[0021] With the addition of the term to the reactance of the transformer, the regulation sensitivity is precisely amplified, so that the regulation deviation caused by the DCC circulating reactive current is exceeded in the case of a minimum scaling difference. Due to this optimization, the set value of the regulation sensitivity can be kept at the preset value of 1 in most cases and therefore very good regulation sensitivity and regulation stability are provided without expensive initialization. In conventional regulators, the ideal factor has to be checked during initialization.

[0022] Embodiments of the present invention utilize two intervals, in particular a first interval and a second interval. Conventional methods only use a single interval, in particular the second interval. Embodiments of the present invention address regulation instability in the case where the voltage deviation is relatively low and the reactive current deviations are opposite and of the same magnitude. For this case, conventional methods and devices were staggered to continuously ascend and descend, which led to damage and wear to the components.

[0023] According to embodiments of the invention, however, a delay time is established in case the voltage deviation is within a first interval around the value of the voltage set point value. The delay time (of either the first or second transformer) can define how long a given deviation must be at least present to perform scaling of the corresponding transformer. In order to prioritize the scaling of a specific transformer, the delay time of the other respective transformer can be increased. If the delay time of a given transformer is increased, this corresponds to a more stringent criterion to trigger scaling of the respective transformer. When, for example, the voltage deviation is negative, priority may be given to scaling up the transformer that exhibits an overall negative deviation (increasing the corresponding delay time of the other transformer). A simple method for stabilizing regulation is thus provided.

[0024] According to an embodiment of the present invention, a transformer delay time for which the overall deviation has a different sign than the voltage deviation is defined as being greater than another delay time for the other transformer.

[0025] Priority in the case of scaling is therefore given to the transformer that has a general deviation that has a sign identical to the voltage deviation. In this case, the scaling or voltage scaling during the rising scaling and the falling scaling and the second interval can be selected depending on each other, so that the rising scaling and during the falling scaling of the open circuit voltage At the output of the secondary winding, do not leave the second gap. Continuous switching back and forth can therefore be avoided.

[0026] The method can be designed such that, if the overall deviation and/or reactive current deviation is outside the second range for at least the delay time that is set to be greater, the corresponding transformer is stepped up if the overall deviation is negative and is scaled down if the overall deviation is negative, where scaling is left if the overall deviation is outside the second interval for a time less than the delay time that is defined as being greater.

[0027] A given transformer is then only increased or decreased when the corresponding or respective global deviation is outside the second range for a period, which period is at least as large for the presently adjusted delay time. By changing the delay time, a criterion can thus be changed, according to which the step occurs.

[0028] According to an embodiment of the present invention, the method is designed such that, when scaling up one of the transformers, a higher voltage and, when scaling down one of the transformers, a lower voltage is present at the output of the secondary winding of the respective transformer, in which the step-up and/or step-down occurs (m) by appropriate derivation in a respective primary winding (and/or secondary winding), the input of which is connected to an additional conductor , wherein, in particular, a high voltage between 70 kV and 400 kV is present, wherein the value of the nominal voltage value is, in particular, between 5 kV and 20 kV.

[0029] Stepping down and scaling up can be achieved by changing the tap in the primary winding and/or in the secondary winding.

[0030] According to an embodiment of the present invention, the delay time that is defined as being greater is between 1.5 and 2.5 times, particularly twice, the other delay time. Effective stabilization of regulation can thus be achieved.

[0031] According to an embodiment of the present invention, the overall deviation for the other transformer (the delay time is not increased) has a sign identical to the voltage deviation. Said other transformer is prioritized in terms of scaling to neutralize voltage deviation.

[0032] In accordance with an embodiment of the present invention, the method is designed such that, when the voltage deviation is negative, the delay time for the voltage regulator or regulators, which exceeds the range, i.e., staggers for descent, it is defined to be greater. This applies in the case of: where the first range is given by the band [-BCC_DV, BCC_DV], the second range is given by the band [-B, B], DV is the voltage deviation, DCC is the reactive current deviation, D is the general deviation ; for example, the delay time set as the largest may be between 1.5 and 2.5 times, particularly 2 times, the other delay time.

[0033] According to an embodiment of the present invention, the method is designed in such a way that, when the voltage deviation is positive, the delay time for the voltage regulators, which do not reach the range, that is, increases, is adjusted to be larger.

[0034] This applies in the case of:

[0035] According to an embodiment of the present invention, the first range is between 0.3 and 0.7 times, particularly 0.5 times, the second range. Other values are possible.

[0036] It is to be understood that the characteristics, which are described, explained or provided individually or in any combination in connection with a method for controlling a voltage value in a conductor, can equally be used individually or in any combination for an apparatus for controlling a voltage value in a conductor, according to an embodiment of the present invention, or vice versa.

[0037] According to an embodiment of the present invention, there is provided an apparatus for controlling a value of a voltage in a conductor to which at least one secondary winding of a first scalable transformer and a secondary winding of a second scalable transformer are connected, wherein the apparatus comprises: a logic unit, which is configured, if a voltage deviation of the voltage in the conductor from a voltage setpoint value is within a first range around the voltage setpoint value and if a general deviation of a sum of the voltage deviation and reactive current deviation from the voltage setpoint value, respectively for the first and second transformers is outside a second range, which is larger than the first, around the value of the voltage set point, to define a delay time for scaling the first transformer and/or second transformer such that scaling of the first or second transformer that counteracts the voltage deviation is prioritized.

[0038] The apparatus may further comprise a measuring device for measuring the voltage value and the values of a reactive current of the first transformer and the second transformer.

[0039] According to an embodiment of the present invention, a transformer system is provided, having: a first scalable transformer and a second scalable transformer connected in parallel thereto; and an apparatus for controlling a voltage value according to one of the embodiments described above.

[0040] In the transformer system, at least one of the first and second transformers may have an on-load tap-changer.

[0041] Embodiments of the present invention are now explained with reference to the two drawings. The present invention is not restricted to the described or illustrated embodiments.

[0042] Figure 1 schematically illustrates a transformer system having an apparatus for controlling a value of a voltage in a conductor in accordance with an embodiment of the present invention; It is

[0043] Figures 2 and 3 illustrate bar graphs, having deviations that are observed in embodiments of the present invention.

[0044] Figure 1 schematically illustrates a transformer system 1 for controlling a voltage value on a conductor 3 to which at least one secondary winding 5A of a first scalable transformer 7A and a secondary winding 5B of a second scalable transformer 7B are connected. , according to an embodiment of the present invention. The transformer system 1 illustrated schematically in Figure 1 has a first scalable transformer 7A and a second scalable transformer 7B, connected in parallel therewith, and an apparatus 13 for controlling a value of a voltage in a conductor 3.

[0045] The apparatus 13 has a logic unit 15, which is formed in the exemplary embodiment illustrated by a first voltage regulator 17A and a second voltage regulator 17B, whose voltage regulators are connected to each other by a communication line 21. The logic unit 15 is designed if a voltage deviation DV of the voltage on the conductor from a voltage set point value is within a first range around the voltage setpoint value, and if an overall deviation D of a sum of the voltage deviation DV and a reactive current deviation DCC from the voltage setpoint value, respectively for the first and second transformers, are outside a second range [-B, B], which is greater than the first, around the voltage setpoint value, to define a delay time T1 for scaling the first 7A transformer and/or the second 7B transformer in such a way that the scaling of the first or second transformer that neutralizes the voltage deviation is prioritized.

[0046] In particular, the logic unit 15 is configured to perform a method for controlling a value of a voltage on a conductor 3 to which at least one secondary winding 5A of a first scalable transformer 7A and a secondary winding 5B of a second transformer scalable 7B are connected, in accordance with an embodiment of the present invention.

[0047] The first transformer 7A has a first primary winding 9A and the second transformer 7B has a second primary winding 9B. Furthermore, switches 37 are provided between the high-voltage rail 27 and the bus 3 to selectively isolate the first and/or second transformer 7A, 7B from the high-voltage rail 27 and/or the bus 43.

[0048] In the illustrated embodiment, the apparatus 13 also comprises a measuring apparatus 23, which is formed by partial measuring apparatus 23A and 23B, in which the measuring apparatus 23A is communicatively available with the first voltage regulator 17A in order to measure a first (reactive) current IA and a first open circuit voltage or load voltage UA at the outputs of the secondary winding 5 of the first 7A transformer. The partial measuring apparatus 23B is communicatively connected to the second voltage regulator 17B and is designed to measure the reactive current IB or generally the current IB and the output voltage UB at the output connection of the second secondary winding 5B of the second transformer 7B and to feed said measurements to the second voltage regulator 17B.

[0049] To scale the first transformer 7A, a tap changer 25A is provided, which receives control signals 26A from the first voltage regulator 17A, according to which the corresponding scaling (shunt on the primary winding 9A or on the secondary winding 5A of the first transformer 7A) is carried out. To scale the second transformer 7B, another tap-changer 25B is provided, which receives control signals 26B from the second voltage regulator 17B, whereby it performs the desired scaling on the second transformer 7B.

[0050] The two transformers 7A and 7B are electrically connected in parallel to each other between a high-voltage rail 27 and conductor 3 (also referred to as busbar). If the two transformers 7A and 7B have different open circuit voltages (or else voltages under load), this can lead to a circulating reactive current 29 (IKBS), which is unwanted and is eliminated according to an embodiment of the present invention.

[0051] Embodiments of the present invention achieve stabilization of regulation for a voltage set point value on bus 3, in particular, in the case where the output voltages of the two transformers 7A and 7B are slightly different but are close to the voltage set point value.

[0052] In the following text, a BCC_DV prioritization interval is established as BCC_DV = factor * B, where the factor can be, for example, 0.5 and B is a conventionally used interval. In the two transformers 7A and 7B having approximately the same transformer reactance and DV = 0, a scaling difference produces exactly the opposite circulating reactive current voltage deviation DCC and therefore an overall deviation D. The voltage deviation DV is then in A close to 0 and therefore within the prioritization interval (also referred to as the first interval). In the case of DV< 0, the ascent scheduling is temporally prioritized. This means that in the regulator on transformer A (transformer 7A), where a positive circulating reactive current is measured, doubled delay time is applied (criterion D > B). In case of DV > 0, descent scheduling is consequently prioritized.

[0053] Figure 2 schematically illustrates a bar graph, in which the voltage deviation DV, the global deviation DA for the first transformer 7A, the reactive current deviation DCCA for the first transformer 7A, the global deviation DB for the second transformer 7B and the DCCB reactive current deviation for the second transformer 7B are plotted. The deviations are in this case plotted against the set point voltage 31 plotted as a proportion. As can be seen from Figure 2, the voltage deviation DV is within the first range 33 and is negative. Furthermore, DA and also DCCA are outside the second range 35 and in particular are greater than B. Furthermore, DB and DCCB are outside the second range 35 and are in particular > -B.

[0054] In this case, the first delay time (the regulation delay time for the first transformer 7A) is increased, in particular it is adjusted to double the value of the delay time value that is used for the second transformer 7B. The step-up scaling of the second transformer 7B is thus prioritized. VACT illustrates the voltage actually measured on the bus, where the difference DV exists from the voltage set point value.

[0055] Figure 3 illustrates, in a bar graph similar to Figure 2, a situation during a regulation method, in which other values of the different deviations are present. In particular, the voltage deviation DV is within the first range 33 and at the same time is greater than 0 (> 0). Furthermore, the overall deviation and reactive current deviation of the first transformer and the second transformer are also outside the second range 35. In this case, the delay time for controlling the second transformer 7B is increased, in particular it is set to double the value compared with the T1 value of the delay time that is used for the first 7A transformer. The step-down scaling of the first 7A transformer is thus prioritized.

[0056] Embodiments of the present invention can ensure regulation stability for the user, in the case of reliable sizing of the circulating reactive current or the elimination of the circulating reactive current. The established value introduced from the prior art is therefore insufficient and can be poorly managed by the user. Due to the low quality of conventional regulation and the circulating reactive current associated with it, the energy loss of transformers is increased and, consequently, efficiency is reduced.

[0057] The stability achieved through the embodiments of the invention simultaneously prevents unnecessary scaling and, consequently, the useful life of the on-load tap changers (OLTC) is increased. Costs for the network operator can thus be reduced.

[0058] The delay time T1 may be prescribed by the network operator and may be related to the elimination of voltage fluctuations in the network. The doubling of said delay time refers to the elimination of the circulating reactive current and, therefore, has no effect on the coordination of voltage regulation processes in radial networks.

Claims (12)

1. Method for controlling a value of a voltage on a conductor (3) to which at least one secondary winding (5A) of a first scalable transformer (7A) and a secondary winding (5B) of a second scalable transformer (7B) are connected, wherein the method is characterized by the fact that it comprises: if a voltage deviation (DV) of the voltage in the conductor (3) from a voltage setpoint value value is within a first interval ([-BCC_DV , BCC_DV]) around the voltage setpoint value, and if an overall deviation (D) of a sum of the voltage deviation (DV) and a reactive current deviation (DCCA, DCCB) from the setpoint value voltage, respectively, for the first and second transformers is outside a second range ([-B, B]), which is greater than the first, around the voltage setpoint value: set a delay time ( T1) to scale the first transformer (7A) and/or the second transformer (7B) in such a way that the scaling of the first or second transformer that neutralizes the voltage deviation is prioritized. 2. Method according to claim 1, characterized in that the delay time (T1) of the transformer for which the global deviation has a different sign for the voltage deviation is defined as being greater than another delay time delay for the other transformer. 3. Method according to claim 1 or 2, characterized by the fact that if the global deviation D and/or the reactive current deviation (DCC) for at least the delay time that is adjusted to be greater is outside the second interval ([-B, B]), the transformer is stepped up if the overall deviation is negative and is stepped down if the overall deviation is negative, where scaling is left if the overall deviation is outside the second interval for a time shorter than a delay time that is defined as being longer. 4. Method, according to claim 3, characterized by the fact that when scaling up one of the transformers, a higher voltage is present and, when scaling down one of the transformers, a voltage lower than the output of the transformer is present. secondary winding (5A, 5B) of the respective transformer, in which the step-up and/or step-down occurs are placed by appropriate derivation in a respective primary winding, the input of which is connected to another conductor (27), in which , in particular, a high voltage between 70 kV and 300 kV is present, wherein the value of the voltage set point value is, in particular, between 5 kV and 20 kV. 5. Method according to any one of the preceding claims, characterized in that a delay time (2 * T1) which is defined to be greater is between 1.5 and 2.5 times, particularly 2 times, the other delay time (T1). 6. Method according to any one of the preceding claims, characterized by the fact that, when the voltage deviation is negative, the delay time for one or a plurality of voltage regulators, which exceed the range, that is, step for descent, it is set to be greater if the following is true: where the first range is given by the band [-BCC_DV, BCC_DV], the second range is given by the band [-B, B], DV is the voltage deviation, DCC is the reactive current deviation, D is the general deviation , wherein a delay time that is defined as being greater is particularly between 1.5 and 2.5 times, more particularly twice, the other delay time. 7. Method according to claim 6, characterized by the fact that, when the voltage deviation is positive, the delay time for one or a plurality of voltage regulators, which does not reach the range, that is, to increase , is defined to be greater if the following is true: 8. Method according to any of the preceding claims, characterized in that the first interval ([- BCC_DV, BCC_DV]) is between 0.3 and 0.7 times, particularly 0.5 times, the second interval -BC, B. 9. Method, according to any of the previous claims, characterized by the fact that it further comprises: optimizing the calculation of a DCC regulation deviation resulting from the circulating reactive current according to: , on what k is an adjustable circulating reactive current control factor, ICC is the circulating reactive current, parallel, UN is the nominal voltage of the transformer. 10. Apparatus (13) for controlling a voltage value on a conductor (3) to which at least one secondary winding (5A) of a first scalable transformer (7A) and a secondary winding (5B) of a second scalable transformer (7B) ) are connected, the apparatus characterized by the fact that it comprises: a logic unit (15, 17A, 17B), which is configured, if a voltage deviation (DV) of the voltage on the conductor from a set point value of voltage is within a first band ([-BCC_DV, BCC_DV]) around the voltage setpoint value, and if an overall deviation (DA, DB) of a sum of the voltage deviation (DV) and a reactive current (DCCA, DCCB) of the voltage setpoint value, respectively, for the first and second transformers is outside a second range ([-BC, B]), which is greater than the first, around the value of the voltage set point, to define a delay time (T1) to scale the first transformer (7A) and/or the second transformer (7B) such that the scaling of the first or second transformer that neutralizes the voltage deviation voltage is prioritized. 11. Apparatus, according to the previous claim, characterized by the fact that it further comprises: measuring devices (23A, 23B) for measuring the voltage value and the values of a reactive current of the first transformer respectively of the second transformer. 12. Transformer system (1), characterized by the fact that it comprises: a conductor (3), to which at least one secondary winding (5a) of a first scalable transformer (7A) and a secondary winding (5B) of a second scalable transformer (7B) are connected; and an apparatus (13) for controlling a value of a voltage, as defined in claim 10 or 11.