BR202020024692U2 - CONSTRUCTION PROVISION INTRODUCED IN PASSIVE SENSOR TO MEASURE LEAKAGE CURRENT IN CAPACITIVE BUSHINGS - Google Patents

Abstract

The present utility model is described as a constructive arrangement introduced in a passive sensor to measure leakage current in capacitive bushings which, according to its characteristics, favors the formation of a passive sensor (1) having an innovative constructive arrangement in its own specific electromechanical structure based on the coupling of a body (2), an outer ring (6) and a coupling (3) with insulator (4) and pin (5) in place of multicomponent structures, in order to enable a complete optimization in the structuring/assembly procedures of the passive sensor components and fixation of the passive sensor in the capacitive bushings by means of adapters and, based on a passive sensor (1) with great resistance, safety and versatility.

Description

CONSTRUCTION PROVISION INTRODUCED IN PASSIVE SENSOR TO MEASURE LEAKAGE CURRENT IN CAPACITIVE BUSHINGS

[001] The present utility model refers to sensors in general, more specifically to a constructive arrangement introduced in a passive sensor to measure leakage current in capacitive bushings which, according to its general characteristics, has as a basic principle to provide to the formation of a passive sensor having an innovative constructive arrangement in its own and specific structure of the electromechanical type based on the coupling of a body, an external ring and a coupling with insulator and pin in place of the multicomponent structures, in order to make it possible in an extremely practical, safe and economical a complete optimization in the structuring/assembly procedures of the passive sensor components and fixation of the passive sensor in the capacitive bushings through adapters and, based on a passive sensor with great resistance, safety and versatility.

[002] With a specific design and format and easy access for better adaptation and safety of users, features of practicality in handling and functionality, very affordable costs and, due to its general characteristics and dimensions, easily adaptable to a wide range of bushings capacitors, adapters, transformers and electrical substations in general, regardless of the characteristics they may present.

[003] Currently, passive sensors for measuring leakage current in capacitive bushings widely known by the current state of the art, despite being functional and widely used by electric utilities, present several types of inconveniences in assembly, installation, operation procedures. and maintenance along the capacitive bushings and power transformers which, in turn, do not allow a full and safe operation of electrical substations.

[004] Among these different types of inconveniences reported by electric power utilities, one can describe: low resistance to vibrations generated by the transformers, difficulties in couplings/connections with capacitive bushings and adapters; low resistance to weather factors; large number of mobile elements in its structuring; poor ergonomics in assembly and integration with capacitive bushings; low robustness; and low resistance in aggressive environments.

[005] In this way, it has become essential for the various electric energy concessionaires in their wide range of electric energy distribution networks, the structuring of a passive sensor that, through its totally innovative structural design, adding high resistance and robustness , be able to check all the essential characteristics required and pointed out by the technicians of the electric energy concessionaires.

[006] The direct use of technology through the optimization of its structures makes it possible to add several benefits to passive sensors for measuring leakage current in capacitive bushings, in order to guarantee high safety and operability, especially in capacitive bushings and in electrical substations , inhibiting their misuse and acting as an important tool in the safety of electrical substations, including saving lives directly through technicians and indirectly by eliminating the lack of electrical energy.

[007] In this line, the utility model in question is characterized by bringing together components and processes in a differentiated design, which will meet the various requirements that the nature of use demands, that is, a passive sensor for high efficiency capacitive bushings , functionality, resistance, durability, safety, ergonomics and precision due to the excellent technical qualities added, providing advantages and improvements in the operation and safety procedures over the passive sensors of the patent of invention PI 0304816-0 "Passive Sensor for Current Measurement Leakage in Capacitive Bushings", filed on 09/24/2003 and granted on 08/25/2015; and utility model MU 8400171-2 "Constructive Arrangement Introduced in Sensors for Measuring Leakage Current in Capacitive Bushings", filed on 01/13/2004 and granted on 12/09/2014.

[008] It should be noted that these previous models of passive current sensors were built based on the fitting format of the capacitive TAP of the WTFX condenser bushing from ASEA, which have these drawbacks, primarily those of coupling to the capacitive bushings, so that, the present Innovative structuring of the passive sensor started with the premise of generating a new way of fitting the passive sensor together with the adapters.

[009] In this way, the general design of the present constructive arrangement introduced in a passive sensor to measure leakage current in capacitive bushings, object of this utility model, is based entirely on its simple and robust structuring with a necessary minimum of components and extremely simplified, safe and optimized operation, combined with very practical manufacturing and maintenance procedures, in order to generate a practical and efficient passive sensor capable of connecting in a totally protected way from the factors of weather, vibrations and connection failures to the capacitive bushings by adapters next to electrical substations.

[0010] More specifically, the present utility model consists of the use of a modern, efficient, safe and functional constructive arrangement introduced in a passive sensor to measure leakage current in capacitive bushings formed by a set of electrical and mechanical solutions correctly incorporated, composing a complete and differentiated passive sensor with exclusive design and its own characteristics, which incorporates its own and specific structure of the electromechanical type, of high durability and resistance, cylindrical shape and containing perfectly integrated and symmetrically arranged with each other by a body as an element of structuring of the passive sensors, an outer ring with the fastening element of the passive sensors in the adapters, a coupling as a packing element for the insulating assembly with pin, locking the outer ring on the passive sensor and fixing to the body, an insulator as an electrical insulating element of the passive sensor and a pin as element electrical connection of the passive sensor, in order to enable the formation of a single, complete and safe set, whose internal and external shapes and arrangements allow perfect adaptation to a wide range of capacitive bushings and adapters in substations in general, being especially designed for these purposes.

[0011] The present passive sensor is based on the application of components and processes in a differentiated design, without, however, reaching a high degree of sophistication and complexity, making it possible to solve some of the main drawbacks of the other forms and models known by the current state. of the technique and employed in the leakage current measurement procedures and safety in the use of capacitive bushings in electrical substations, which are located in a working range in which the shapes and/or models present difficulties in use and application, frequent accidents, great deterioration and fragility, low versatility, low precision, high insecurity, low yield, high losses, labor intensive application, no ergonomics, high cost, high overall volume and weight, complex handling, high maintenance, high waste of time and complex manufacturing.

[0012] The objectives, advantages and other important characteristics of the utility model in question can be more easily understood when read together with the attached figures, in which:

[0013] Figure 1A represents a perspective view of the passive sensor for measuring leakage current in capacitive bushings.

[0014] Figure 1B represents a front view of the passive sensor for measuring leakage current in capacitive bushings.

[0015] Figure 1C represents a rear view of the passive sensor for measuring leakage current in capacitive bushings.

[0016] Figure 1D represents a right side view of the passive sensor for measuring leakage current in capacitive bushings.

[0017] Figure 1E represents a left side view of the passive sensor for measuring leakage current in capacitive bushings.

[0018] Figure 1F represents a top view of the passive sensor for measuring leakage current in capacitive bushings.

[0019] Figure 1G represents a bottom view of the passive sensor for measuring leakage current in capacitive bushings.

[0020] Figure 1H represents a perspective view in longitudinal section of the passive sensor for measuring leakage current in capacitive bushings.

[0021] Figure 1I represents an exploded perspective view of the passive sensor for measuring leakage current in capacitive bushings.

[0022] Figure 2A represents a perspective view of the passive sensor body for measuring leakage current in capacitive bushings.

[0023] Figure 2B represents a longitudinal sectional view of the passive sensor body for measuring leakage current in capacitive bushings.

[0024] Figure 3A represents a perspective view of the coupling of the passive sensor for measuring leakage current in capacitive bushings.

[0025] Figure 3B represents a longitudinal sectional view of the passive sensor coupling for measuring leakage current in capacitive bushings.

[0026] Figure 4A represents a perspective view of the outer ring of the passive sensor for measuring leakage current in capacitive bushings.

[0027] Figure 4B represents a longitudinal view of the external ring of the passive sensor for measuring leakage current in capacitive bushings.

[0028] Figure 5A represents a perspective view of the passive sensor insulator for measuring leakage current in capacitive bushings.

[0029] Figure 5B represents a longitudinal sectional view of the passive sensor insulator for measuring leakage current in capacitive bushings.

[0030] Figure 6A represents a perspective view of the passive sensor pin for measuring leakage current in capacitive bushings.

[0031] Figure 6B represents a longitudinal sectional view of the passive sensor pin for measuring leakage current in capacitive bushings.

[0032] Figure 7 represents a perspective view of the passive sensor for measuring leakage current in capacitive bushings with the cable gland.

[0033] As can be seen from the attached figures that illustrate and integrate the present utility model of "Constructive Arrangement Introduced in Passive Sensor to Measure Leakage Current in Capacitive Bushings", in figure 1A it is presented in general, comprised of a passive sensor (1) complete and with its own characteristics, which incorporates a specific and specific structure of the electromechanical type, of high durability and resistance, cylindrical shape, internal and external shapes and arrangements that adapt to a wide range of capacitive bushings and adapters in substations and containing perfectly integrated and symmetrically arranged between them a body (2) of cylindrical shape at the bottom, truncated at the middle part and cylindrical at the top and arranged symmetrically along the entire length of the upper part of the passive sensor ( 1); a hook (3) of hollow cylindrical shape and arranged symmetrically aligned and threaded at the lower end of the body (2); an insulator (4) of cylindrical shape hollowed out in a section similar to a "T" and arranged perpendicularly and symmetrically fitted inside the upper end of the coupling (3); a pin (5) of cylindrical shape and arranged perpendicularly and symmetrically fitted along the entire length of the hollow of the insulator (4); and an outer ring (6) arranged symmetrically around the hook (3).

[0034] The body (2) consists of a hollow (2A) symmetrically around the entire internal extension of the body (2), an upper thread (2B) arranged symmetrically around the entire internal extension of the upper end of the body (2) that threads into the cable gland, a lower thread (2C) arranged symmetrically around the entire inner length of the lower end of the body (2), and a lower tab (2D) arranged perpendicularly and symmetrically around the entire length of the lower end of the body (2).

[0035] The coupling (3) consists of an upper recess (3A) of annular shape and arranged parallel and symmetrically around the entire external extension of the upper end of the coupling (3), an upper thread (3B) arranged parallel and symmetrically around the entire external extension of the upper recess (3A) that threads into the lower thread (2C), an upper hole (3C) arranged perpendicular and symmetrically passing through the upper face of the coupling (3), a sealing ring ( 3D) arranged symmetrically around the entire length of the lower end of the upper recess (3A), and a lower flap (3E) arranged perpendicularly and symmetrically around the entire length of the lower end of the hitch (3).

[0036] The pin (5) consists of a lower opening (5A) arranged symmetrically entered along the bottom of the pin (5), and an upper hole (5B) arranged perpendicularly and symmetrically centered on the top of the pin (5) ) external to the insulator (4).

[0037] The outer ring (6) consists of an upper tab (6A) arranged perpendicularly and symmetrically around the inner part of the upper end of the outer ring (6), and a lower thread (6B) arranged symmetrically around the inner bottom of the outer ring (6) which threads onto the free end of the adapter.

[0038] The constructive arrangement introduced in passive sensor to measure leakage current in capacitive bushings has its application based on its correct fixation to the adapter by means of threading the outer ring (6) to the free end of this and, consequently, the capacitive bushing , as well as fixing a cable gland by means of its thread on the upper end of the body (2) so that the electrical conductor is fixed with high mechanical resistance and is not pulled - it does not escape the passive sensor (1).

[0039] The structuring of the passive sensor (1) itself begins with the assembly of the pin (5) in the insulator (4). Once the pin (5) is mounted on the insulator (4), this part of the passive sensor (1) is mounted directly on the coupling (3), which is also called the base, as this component connects directly to an adapter. Once the pin (5) and insulator (4) assembly is mounted on the coupling (3), the outer ring (6) is inserted around it by its upper face. Then the body (2), which is also called the cover, is threaded into the upper end of the coupling (3), inserting and securing the outer ring (6) in the assembly, in order to allow the entire passive sensor assembly (1 ) is fixed to the adapter by its screw into the adapter.

[0040] The constructive arrangement introduced in passive sensor to measure leakage current in capacitive bushings, for having its components fully integrated with each other, nothing comes off and nothing has to break or bend, reaching a high performance index and efficiency, combined with high durability and absolute safety. After being fully integrated with each other and with the capacitive bushings through adapters, the components are cohesive, thus preventing them from coming loose by themselves when in use, leaving the set fully available for the leakage current measurement procedures and safety in the use of the capacitive bushings. In this way, the passive sensor (1) can be used without any concerns, especially regarding the durability and safety of its components, in addition to the safety of the technicians of the electric energy concessionaires.

[0041] The constructive arrangement introduced in a passive sensor to measure leakage current in capacitive bushings has the following specific advantages: high resistance to weather factors; simplicity in structuring due to the low number of components, mainly mobile components; high operational robustness; high resistance to vibrations near the transformers by means of larger components; practicality and ergonomics in couplings/connections with capacitive bushings and adapters in electrical substations; high resistance when placed in aggressive environments; high quality connections/fittings between components and with capacitive bushings and adapters; and high voltage connectors/couples.

[0042] From all that has been exposed, it is a measurement and safety device that will be well received by electric energy concessionaires in general, since the constructive arrangement introduced in a passive sensor to measure leakage current in capacitive bushings presents numerous advantages , such as: great security, reliability and agility in the application; great yield and performance in its application due to its general design; high comfort, convenience and safety for technicians; very high strength and general durability, combined with low or no wear on the set as a whole; totally accessible costs, which allows an excellent cost/benefit ratio; practical and safe use by a wide range of technicians; large range; very low and practical general maintenance; perfect and direct adaptation to the most diverse types of capacitive bushings and electrical substations; high operational precision; high operational ergonomics; and the certainty of having a passive sensor (1) that fully complies with current legislation and standards and the basic conditions necessary for its application as a whole.

[0043] All these attributes allow classifying the constructive arrangement introduced in passive sensor to measure leakage current in capacitive bushings, as a totally versatile, efficient, practical and safe way for the structuring procedures of a wide range of passive sensors applied in the more diverse types of capacitive bushings and power transformers in electrical substations, regardless of the general characteristics that they may present, being still of great ease of application and handling, allied to great performance and excellent general characteristics; however, dimensions and components may vary according to needs without departing from the scope of this utility model.

Claims (1)

"CONSTRUCTIVE ARRANGEMENT INTRODUCED IN A PASSIVE SENSOR FOR MEASUREMENT OF LEAKAGE CURRENT IN CAPACITIVE BUSHINGS", characterized by being comprised of a passive sensor (1) that incorporates a cylindrical shaped structure and containing integrated and symmetrically arranged between them a cylindrical body (2) in the lower part, frustoconical in the middle part and cylindrical in the upper part and arranged symmetrically along the entire length of the upper part of the passive sensor (1); a hollow and symmetrically arranged cylindrical coupling (3) aligned and threaded at the lower end of the body (2); a cylindrical insulator (4) hollow in section similar to a "T" and arranged perpendicularly and symmetrically fitted inside the upper end of the coupling (3); a cylindrical pin (5) arranged perpendicularly and symmetrically fitted along the entire length of the insulating hole (4); and an outer ring (6) arranged symmetrically around the hook (3); being that, the body (2) consists of a hollow (2A) symmetrically around the entire internal extension of the body (2), an upper thread (2B) arranged symmetrically around the entire internal extension of the upper end of the body (2) that threads into the cable gland, a lower thread (2C) arranged symmetrically around the entire inner length of the lower end of the body (2), and a lower tab (2D) arranged perpendicularly and symmetrically around the entire length of the lower end of the body (2); the coupling (3) consists of an upper recess (3A) of annular shape and arranged parallel and symmetrically around the entire external extension of the upper end of the coupling (3), an upper thread (3B) arranged parallel and symmetrically around of the entire external extension of the upper recess (3A) that threads into the lower thread (2C), an upper hole (3C) arranged perpendicular and symmetrically passing through the upper face of the coupling (3), a sealing ring (3D) arranged symmetrically around the entire length of the lower end of the upper recess (3A), and a lower flap (3E) arranged perpendicularly and symmetrically around the entire length of the lower end of the hook (3); the pin (5) consists of a lower opening (5A) arranged symmetrically entered along the lower part of the pin (5), and an upper hole (5B) arranged perpendicular and symmetrically centered in the upper part of the pin (5) external to the insulator (4); and the outer ring (6) consists of an upper tab (6A) arranged perpendicularly and symmetrically around the inner part of the upper end of the outer ring (6), and a lower thread (6B) arranged symmetrically around the inner lower part. of the outer ring (6) which threads onto the free end of an adapter.

Images