ES2381954A1 - Voltmeter using capacitive coupling in medium-voltage bushings and busbars - Google Patents

Abstract

The invention relates to bushings and busbars that include a conductor (1, 1a, b) covered with an insulator (2, 2a, 2b) that dielectrically supports the difference in voltage created between the conductor and the structure (6) where it is located and the inside of which includes an element configuring the electric field and a connection with the outside of the insulating covering (2, 2a, 2b) to achieve a capacitive coupling, the capacitive current of which flows to an electronic circuit that determines whether or not there is voltage in the conductor. It is characterized in that the element configuring the electric field includes a body of insulating material having dielectric properties that are not affected by temperature variations (8), preferably a ceramic material, to obtain a measurement of the module and phase of the conductor voltage, which is stable with respect to temperature.

Description

Voltage measuring device by capacitive coupling in medium voltage busbars and busbars

OBJECT OF THE INVENTION

The present invention, as expressed in the statement of this specification, is encompassed in the field of the devices provided for the measurement of capacitive coupling voltage in medium voltage busbars and busbar conductors, which is intended to provide a new capacitive coupling with unalterable dielectric properties with temperature variations, so that a measurement of the stable voltage module and phase is obtained against the possible variations that the temperature of the capacitive coupling can suffer.

BACKGROUND OF THE INVENTION

In the field of medium voltage switchgear (MT) it is usually necessary to have an element capable of transporting the current both from the outside to the inside of the MV switchgear, and inside it between compartments, or even between two units functional or cells.

In this sense, the bushing and busbars are known, which comprise a conductor that is covered with an insulator that has to have electrical insulation properties to withstand the potential difference that is created between the conductor and the structure in which it is located.

In addition, the bushing and busbars are designed so that they have adequate mechanical resistance to withstand the stresses derived from their connection to the network (installation, cables, tightening torques, etc.) and against the electrodynamic stresses derived from the operation and operation of switchgear (short circuit resistance, etc.).

Additionally and due to exploitation needs, it has also been common in the design of the bushing and busbars, the inclusion of both external and internal elements that allow the capacitive coupling of the medium voltage conductor with the structure in which it is located and which is located Connects to a low voltage electronic circuit capable of indicating and / or detecting the absence or presence of voltage in the conductor.

This capacitive coupling is effected by the use of an electric field configuration element determined by a mesh arranged around the conductor and provided inside the conductor insulating coating, so that said insulating coating is provided with a connection with the outside for By means of the low voltage electronic circuit, it is possible to detect and indicate when there is voltage in the conductor. Therefore, the capacitive coupling is constituted by the metal mesh and the insulating coating itself that is arranged between the mesh and the conductor, which dielectrically supports the potential difference that is created between the conductor and the structure in which it is located, such and As already commented. Therefore, the dielectric commonly used is constituted by the materials used to make the insulating coating of the conductor, such as (epoxy resins, polyurethanes, silicones, etc.).

These types of materials have the disadvantage that they have significant coefficients of thermal variation, relative permittivity and delta tangent of the capacitive coupling, and as a consequence, the signal that is derived from low voltage electronics, both in module and phase , to determine if there is voltage in the conductor, it is strongly dependent on temperature. Therefore they do not serve to accurately measure the voltage module and phase.

In this regard, it can be noted that both the normal operating, environmental and load margins, to which the switchgear is subjected, as well as the limits set by international standards for the correct operation of the indication (presence) non-indication signals ( absence of tension have not made it necessary to take into consideration as a design parameter the variations with the temperature of the materials used so far for capacitive couplings in bushing and busbars.

It can also be mentioned that the new challenges imposed by the generation of energy in places closer to consumption (distributed generation), the fact that energy flows can occur in opposite directions, as well as the need to provide the network of greater intelligence (smart grid) in the localization and automatic resolution of faults, make necessary the availability of a more precise voltage monitoring, both in module and in phase, which is available so far, which only allows the presence or absence of tension.

Accuracy in terms of voltage levels is necessary both at the module level and at the phase level, since both factors are involved in the calculation of active / reactive powers.

Likewise, in some of the fault location systems certain levels of phase accuracy are required for the discrimination / location of said faults.

Obviously and for these new needs, the levels of precision must be kept under acceptable levels whatever the conditions of use of the switchgear, such as different levels of load, ambient temperature, etc.

Traditionally, a solution to this problem to measure voltage in a precise and thermally stable way, both in module and in phase, includes the use of induction voltage transformers that are subject to international IEC standards and classified according to levels or classes of precision.

Another traditional solution to carry out this measurement, includes the use of voltage dividers of different types (resistive, capacitive, combined, etc.) specially manufactured for this purpose and with comparisons comparable to those obtained by the transformers, although without the support of a regulation international.

The incorporation of transformers or adaptation of the dividers to the switchgear is not a simple and economical solution in all cases.

For example, in gas-insulated cells the inclusion of transformers requires the use of additional modules or cells, designed for this purpose, and electrically connected to the switchgear by means of insulated cable.

Also, in the case where voltage dividers are used for gas insulation cells, their use depends largely on the type of connection cable used, which on the other hand is not normally part of the supply of the cell manufacturer or Well, it implies its installation in the tank, which affects both dielectric and mechanical implications in the design of the cell itself.

Therefore, the traditional solutions of using voltage transformers or splitters are not suitable to allow measurement of the module and phase of the voltage present in a conductor of the medium voltage busbars and busbars.

DESCRIPTION OF THE INVENTION

To achieve the objectives and solve the aforementioned drawbacks, the invention provides a new voltage measuring device by capacitive coupling in medium voltage busbars and busbars, in which said bushing and busbars comprise a conductor covered with an insulator that dielectrically withstands the difference. of potential that is created between the conductor and the structure in which it is located, so that the interior of the insulating coating is provided with an element of configuration of the electric field generated in the dielectric by the difference in voltage between the structure and the conductor , the electric field configuration element being provided with a connection to the outside to obtain a capacitive coupling which, from the measurement of its capacitive current, allows to determine if there is voltage in the conductor. The main novelty of the invention is characterized in that the electric field configuration element comprises a body of insulating material of unalterable dielectric properties against temperature variations, which allows, by means of a conventional low-voltage electronic circuit, to obtain a module measurement and voltage phase stable with temperature.

This configuration has the great advantage of allowing a stable signal to be available in the range of use of the bushing and busbars at different ambient temperatures, which in turn and by means of conventional low voltage electronics, allows the conductor voltage to be measured in module and phase with sufficient precision to meet the needs that the new challenges of distributed generation and intelligent networks demand at the level of medium voltage switchgear.

All this with the simplicity, robustness and savings that the integration of said coupling inside the bushing and busbar entails.

In the preferred embodiment of the invention, the insulating material body of unalterable dielectric properties against temperature variations is a ceramic material that allows to obtain the mentioned functionality.

In addition, the insulating material body of unalterable dielectric properties against temperature variations is arranged around the conductor to which it is electrically joined by means of a joint, such as a contact, welding, a semiconductor interface, or any conventional method that allows it to be located or similar potential of the conductor to one of the poles of the capacitive coupling.

In one embodiment of the invention, the insulating material body of unalterable dielectric properties against temperature variations is separated a certain distance from the conductor, by a second body of semiconductor material, different from the material of the coating itself, so that it establishes a semiconductor interface of connection with the driver.

Therefore, the insulating material body of unalterable dielectric properties against temperature variations, as described above, can be in contact with the conductor or separated from it a certain distance by establishing in the latter case the semiconductor interface for connection with the conductor.

The invention also provides for the possibility of using a metal mesh that is disposed around the body of insulating material of unalterable dielectric properties against temperature variations, so that the set of both constitutes the electric field configuration element.

The invention provides that the conductor comprises a narrowing in which the insulating material body of unalterable dielectric properties is coupled against temperature variations to accommodate the insulating material body of unalterable dielectric properties against temperature variations in the area of the narrowing, and at the same time adjust the relationship between the supported voltages between the conductor and the structure in which it is located.

Furthermore, in one embodiment of the invention, the insulating material body of unalterable dielectric properties against temperature variations has a thickness greater than the insulating coating section, so that it is provided with a complementary thickening covering the insulating material body. unalterable dielectric properties against temperature variations.

The structures described allow measuring the module and phase of the voltage difference between the conductor and the structure in which it is located.

In order to facilitate a better understanding of this descriptive report and forming an integral part thereof, a series of figures are attached in which the object of the invention has been shown as an illustrative and non-limiting nature.

BRIEF STATEMENT OF THE FIGURES

 Figure 1.- Shows a sectional view of a conventional bushing.

Figure 2.- Shows a sectional view of a possible embodiment of a bushing of the invention in which the electric field configuration element is constituted by a metal mesh arranged around an insulating body of unalterable dielectric properties against variations Of temperature.

Figures 3 to 5.- They show different examples of embodiment of the bushing of the invention in which the electric field configuration element does not incorporate the metal mesh, and is only constituted by an insulating material of unalterable dielectric properties against temperature variations.

Figures 6 and 7.- They show two possible embodiments of the invention for application in busbars that connect different switchgear cells.

Figures 8 and 9.- They show two possible embodiments of the invention for busbars of the type that make the connection between two bushing.

Figure 10. - It shows a last example of embodiment of the invention equivalent to that represented in Figure 4, but with the difference that in this case a narrowing has been incorporated in the conductor in which the body of properties insulating material is coupled Unalterable dielectrics against temperature variations.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

OF THE INVENTION

Below is a description of the invention based on the figures mentioned above.

In the first place and with the aid of Figure 1, a conventional configuration of a bushing is described, which is provided with a conductor 1 covered with an insulator 2 inside which houses a metal mesh 3 defining an electric field configuration element, which through a connection 4 allows the metal mesh 3 to be connected to the outside to allow it to be connected with a BT electronic device of measurement, as will be explained later.

In addition, the bushing comprises a ground flange 5 that is inserted inside the insulating cover 2 and emerges outside it to make electrical contact with the structure 6 in which the bushing is mounted. The earth flange 5 is protected by an insulating coating 7 inside the insulating coating 2 to prevent it from contacting the metal mesh 3.

Based on the description made, it is easily understood that when the conductor 1 is placed at a different voltage from the structure 6, an electric field is generated, so that a potential difference is created between the conductor 1 and the structure 6, the insulating coating 2 constitutes a dielectric which together with the metal mesh 3 defines a capacitive coupling whose capacitive current can be derived through the connection 4, so that from this current it is determined whether there is presence or absence of voltage.

This capacitive coupling, as already mentioned in previous sections, has the disadvantage that the insulating coating 2 has properties that vary with temperature, which does not allow measurement of the module and phase of the voltage present in the conductor 1 With some precision.

To solve these drawbacks, the invention provides a new electric field configuration element, which in the exemplary embodiment of Figure 2, in addition to including the metal mesh 3, incorporates a body of insulating material of unalterable dielectric properties against variations of temperature 8, which is constituted by a high purity ceramic material, so that its properties are unalterable against temperature changes, which determines that a stable tension measurement is obtained regardless of the temperature variations that may suffer the body of insulating material 8, which allows a measurement of the module and phase of the stable voltage with the temperature.

In Figures 3 to 5, examples are shown in which the metal mesh 3 is not used, since it is sufficient to use the body of insulating material of unalterable dielectric properties against the temperature variations 8 described.

In figure 3 the body of insulating material 8 has a greater thickness than in the case of figure 4, depending on the capacity to be stored.

In the example of Figure 5, the body of insulating material 8 is separated from the conductor 1 by means of a second body of semiconductor material 10, which is of a different material than the coating 2 itself, to establish a semiconductor interface connecting with the driver 1.

In figures 6 and 7 two examples of busbar embodiment are shown, in which the conductor 1a is provided to make the connection between different busbar compartments, for which it comprises a conductor 1a provided with a coating of an insulator 2a, in which includes the body of insulating material of unalterable dielectric properties against temperature variations 8, in an equivalent manner as described for figures 4 and 5 of the bushing respectively.

Examples of carrying out busbars are shown in Figures 8 and 9, which are constituted by a conductor 1b provided for connecting two conductors 1 of a bushing. In this case, the conductor 1b is provided with a coating of an insulator 2b in one of whose zones incorporates the insulating material body of unalterable dielectric properties against temperature variations 8 in an equivalent manner as described in the previous figures.

In the case of Figure 9, the body of insulating material 8 has a thickness greater than that of the coating of an insulator, for which it is provided with a thickening 2c covering the body of insulating material 8 to allow the functionality already mentioned .

Figure 10 shows a bushing in which the conductor 1 has a narrowing 9 that allows the body of insulating material to be accommodated in correspondence with said narrowing, and thus differently adjusting the relationship between the stresses supported between the conductor 1 and the structure 6.

Claims (9)

1.- VOLTAGE MEASUREMENT DEVICE FOR CAPACITIVE COUPLING IN PASSENGERS AND HALF VOLTAGES, the bushing and busbars comprising a conductor (1, 1a, 1b), covered with an insulator (2, 2a, 2b) that dielectrically withstands the difference of potential that is created between the conductor (1, 1a, 1b) and the structure (6) in which it is located; counting the inside of the insulating coating (2, 2a, 2b) with an electric field configuration element generated in the dielectric by the voltage difference between the structure (6) and the conductor (1, 1a, 1b); and with a connection (4) of said electric field configuration element with the outside of the insulating coating (2, 2a, 2b), to derive the capacitive current, obtaining a capacitive coupling in which from said capacitive current derivation it is determined if there is voltage in the conductor (1, 1a, 1b); characterized in that the electric field configuration element comprises a body of insulating material of unalterable dielectric properties against temperature variations (8), to obtain a measure of the module and phase of the voltage stable with the temperature. 2.- VOLTAGE MEASUREMENT DEVICE BY CAPACITIVE COUPLING IN PASSENGERS AND HALF-VOLTAGE EMBARRATES, according to claim 1, characterized in that the insulating material body of unalterable dielectric properties against temperature variations (8) is a ceramic material. 3.- VOLTAGE MEASUREMENT DEVICE BY CAPACITIVE COUPLING IN PASSENGERS AND MEDIUM VOLTAGE BARRELS, according to claim 1, characterized in that the insulating material body of unalterable dielectric properties against temperature variations (8) is arranged around the conductor (1, 1a , 1b), to which it is electrically connected by a connection selected between contact, welding and a semiconductor interface. 4.- VOLTAGE MEASUREMENT DEVICE BY CAPACITIVE COUPLING IN PASSENGERS AND HALF VOLTAGES, according to claim 3, characterized in that the insulating material body of unalterable dielectric properties against temperature variations (8) is separated a certain distance from the conductor (1) , 1a, 1b), in which a second body of a semiconductor material (10) is interposed, to establish a semiconductor interface connecting with the conductor. 5.- VOLTAGE MEASUREMENT DEVICE FOR CAPACITIVE COUPLING IN PASSENGERS AND MEDIUM VOLTAGES, according to claims 3 or 4, characterized in that the insulating material body of unalterable dielectric properties against temperature variations (8) is an annular body. 6.- VOLTAGE MEASUREMENT DEVICE FOR CAPACITIVE COUPLING IN PASSENGERS AND HALF VOLTAGES, according to claim 1, characterized in that the insulating material body of unalterable dielectric properties against temperature variations (8) comprises a metal mesh (3) arranged around of the same. 7.- VOLTAGE MEASUREMENT DEVICE FOR CAPACITIVE COUPLING IN PASSENGERS AND HALF VOLTAGES, according to claim 3, characterized in that the conductor (1, 1a, 1b) comprises a narrowing (9) in which the body of insulating material of unalterable dielectric properties against temperature variations (8). 8.- VOLTAGE MEASUREMENT DEVICE BY CAPACITIVE COUPLING IN PASSENGERS AND MEDIUM VOLTAGES, according to claim 1, characterized in that the insulating material body of unalterable dielectric properties against temperature variations (8) has a thickness greater than the section of the coating insulator (2, 2a, 2b), and this comprises a thickening (2c) that covers the body of insulating material of unalterable dielectric properties against temperature variations (8). SPANISH OFFICE OF THE PATENTS AND BRAND Application no .: 201031541 SPAIN Date of submission of the application: 20.10.2010 Priority Date: REPORT ON THE STATE OF THE TECHNIQUE 51 Int. Cl.: See Additional Sheet RELEVANT DOCUMENTS

Category

56 Documents cited Claims Affected

X

JP 59196475 A (KANSAI ELECTRIC POWER CO ET AL.) 07/11/1984, Recovered from: EPO PAJ 1-3.5-8

TO

4

X

US 3538440 A (GALLOWAY DUDLEY L.) 11/03/1970, description; figures. 1-5,7,8

Y

6

Y

ES 2204334 A1 (GRUPO ORMAZABAL S.A.) 04/16/2004, description; Figure 1. 6

TO

1-5,7,8

TO

JP 8138973 A (TOSHIBA CORP.) 05/31/1996, the entire document. 1-5.8

X

WO 0194956 A1 (NU LEC IND PTY LTD ET AL.) 12/13/2001, the whole document. 1-5

TO

6-8

Category of the documents cited X: of particular relevance Y: of particular relevance combined with other / s of the same category A: reflects the state of the art O: refers to unwritten disclosure P: published between the priority date and the date of priority submission of the application E: previous document, but published after the date of submission of the application

This report has been prepared • for all claims • for claims no:

Date of realization of the report 21.05.2012

Examiner M. d. López Sábater Page 1/4

REPORT OF THE STATE OF THE TECHNIQUE Application number: 201031541 CLASSIFICATION OBJECT OF THE APPLICATION G01R19 / 155 (2006.01) H02J13 / 00 (2006.01) H04B3 / 54 (2006.01) Minimum documentation sought (classification system followed by classification symbols) G01R, H02J, H04B Electronic databases consulted during the search (name of the database and, if possible, terms of search used) INVENTIONS, EPODOC State of the Art Report Page 2/4  WRITTEN OPINION Application number: 201031541 Date of the Written Opinion: 21.05.2012 Statement

Novelty (Art. 6.1 LP 11/1986)

Claims Claims 2,4,5,8 1,3,6,7 IF NOT

Inventive activity (Art. 8.1 LP11 / 1986)

Claims Claims 1-8 IF NOT

The application is considered to comply with the industrial application requirement. This requirement was evaluated during the formal and technical examination phase of the application (Article 31.2 Law 11/1986).  Opinion Base.- This opinion has been made on the basis of the patent application as published. State of the Art Report Page 3/4  WRITTEN OPINION Application number: 201031541  1. Documents considered.- The documents belonging to the state of the art taken into consideration for the realization of this opinion are listed below.

Document

Publication or Identification Number publication date

D01

JP 59196475 A (KANSAI ELECTRIC POWER CO et al.) 07.11.1984

D02

US 3538440 A (GALLOWAY DUDLEY L.) 03.11.1970

D03

JP 8138973 A (TOSHIBA CORP.) 05/31/1996

 2. Statement motivated according to articles 29.6 and 29.7 of the Regulations for the execution of Law 11/1986, of March 20, on Patents on novelty and inventive activity; quotes and explanations in support of this statement Claim 1: The document closest to this first claim in the prior art is D01, in which a voltage measuring device is disclosed by capacitive coupling in medium voltage busbars and busbars, the bushing and busbars comprising a conductor (1), coated with an insulator (5), which dielectrically withstands the potential difference that is created between the conductor (1) and the structure in which it is located. The apparatus has a connection of said electric field configuration element with the outside of the insulating coating to derive the capacitive current, obtaining a capacitive coupling in which, from said capacitive current derivation, it is determined if there is voltage in the driver (1). Finally, the electric field configuration element of D01 comprises a body of insulating material of unalterable dielectric properties against temperature variations (5) to obtain a stable voltage measurement with temperature. Therefore, this first claim is not new within the meaning of article 6 of Patent Law 11/86. Claims 2 and 5: In D01 it is disclosed that the dielectric used contains Barium Titanate, a known ceramic dielectric, as well as being in contact with the conductor. Its shape is cylindrical. In view of these characteristics of the D01 apparatus, a person skilled in the art would not need to exercise any inventive activity to exclusively use Barium Titantao or shorten the extension of the dielectric around the conductor until its shape was that of a ring. Therefore, these claims lack inventive activity according to article 8 of Patent Law 11/86. Claim 3: In view of D01 it follows that this claim is also not new. Claim 4: In document D01 it is not stated that the insulating material body of unalterable dielectric properties against temperature variations (5) is separated a certain distance from the conductor (1), in which a second body of a semiconductor material is interposed to establish a semiconductor interface connecting with the conductor. However, this possibility does arise in document D02 of the prior art, (figures 3 and 4. Also read the description of this document column 4, lines 41 to 45). Therefore D02 affects the inventive activity of this dependent claim. Claim 6: In D01 it is mentioned as usual practice the incorporation of a cylindrical mesh as an electrode and therefore constitutes a priority that nullifies the novelty of this claim. Claims 7 and 8: These dependent claims address features of the apparatus that have been introduced as design options, without explaining the technical effect they entail. On the other hand, devices in which a conductor has a narrowing in which a body of insulating material of unalterable dielectric properties against temperature variations, (D01), as well as devices in which The insulating material body of unalterable dielectric properties against temperature variations has a thickness greater than the section of the insulating coating and this comprises a thickening that covers the insulating material body of unalterable dielectric properties against temperature variations, (D03). Therefore, claim 7 is not new and claim 8 lacks inventive activity. State of the Art Report Page 4/4