Disclosure of Invention
The utility model aims to solve the technical problem that a simple structure is provided to above-mentioned prior art current situation, occupation space is little, and the cost of manufacture is low, can provide a take zero sequence voltage output function's of zero sequence voltage signal combination voltage transformer.
The utility model provides a technical scheme that above-mentioned technical problem adopted does: the combined voltage transformer with the zero sequence voltage output function comprises a double-voltage transformer combination formed by connecting two voltage transformers in a V-V wiring mode, and is characterized in that: the double-voltage transformer combination is characterized in that each phase high-voltage input end of the double-voltage transformer combination is connected with a capacitive voltage divider, the capacitive voltage dividers are respectively connected with one end of an output capacitor through a line, the other end of the output capacitor is a zero potential end, the output capacitor is connected with the input end of an adjusting module capable of adjusting and compensating the output capacitor voltage in parallel, and the output end of the adjusting module is a zero sequence voltage signal output end.
As an improvement, the dual voltage transformer combination may be preferably cast with the capacitive voltage divider as an integral structure through epoxy resin, and the output capacitor and the adjusting module are connected to the integral structure.
In a further improvement, any capacitive voltage divider comprises two voltage dividing capacitors which are arranged together in series.
In a further improvement, the capacitive voltage divider preferably further comprises an upper shielding plate and a lower shielding plate which can reduce interference of a combined magnetic field of the double voltage transformers, wherein an upper capacitor of the two voltage dividing capacitors is connected with the upper shielding plate through a line, the upper shielding plate is connected with a corresponding high-voltage input end through a line, a lower end of a lower capacitor of the two voltage dividing capacitors is connected with the lower shielding plate, and the lower shielding plate is connected with an output capacitor through a line.
In a further improvement, the voltage-dividing capacitor is preferably a ceramic capacitor made of high-voltage-resistant ceramic, a silicone rubber layer with elasticity and buffering performance is coated on the surface of the ceramic capacitor, and the ceramic capacitor is connected with epoxy resin forming an integral structure through the silicone rubber layer.
In a further improvement, the distance between any capacitive divider and the coil of the closest dual voltage transformer combination may preferably be greater than or equal to 50 mm.
As an improvement, the specific structure of the dual-voltage transformer combination may preferably be that the first coil set and the second coil set are sleeved on the first iron core in a mutually inductive manner, one end of the first coil set is connected with the a-phase high-voltage input end through a line, the other end of the first coil set is connected with the B-phase high-voltage input end through a line, the second coil group is connected with the first low-voltage signal output end, the third coil group and the fourth coil group are sleeved on the second iron core in a mutual induction manner, one end of the third coil group is connected with the B-phase high-voltage input end through a circuit, the other end of the third coil group is connected with the C-phase high-voltage input end through a circuit, the fourth coil group is connected with the second low-voltage signal output end, and the A-phase high-voltage input end, the B-phase high-voltage input end and the C-phase high-voltage input end are respectively connected with a capacitive voltage divider, and the three capacitive voltage dividers are respectively connected with an output capacitor through lines.
The high-voltage cable is characterized in that the high-voltage input end of the phase A, the high-voltage input end of the phase B and the high-voltage input end of the phase C are arranged on the upper portion of the integral structure at intervals preferably, a corresponding fuse is detachably arranged on the integral structure corresponding to the high-voltage input end of any phase, and the high-voltage input end of any phase is communicated with the high-voltage cable through the corresponding fuse.
The fuse is preferably a rod fuse, the rod fuse is inserted into a fuse mounting hole in the upper part of the overall structure, an electric conduction embedded piece is arranged on the bottom surface of the fuse mounting hole, the embedded piece is connected with a corresponding capacitive voltage divider through a circuit, an ejection spring capable of ejecting the rod fuse is arranged on the embedded piece, when the rod fuse is inserted into the fuse mounting hole, one end of the rod fuse is abutted against the ejection spring to enable the ejection spring to contract and compress, a quick-mounting and dismounting mechanism is detachably arranged in an opening of the fuse mounting hole, the other end of the rod fuse is abutted against the quick-mounting and dismounting mechanism, and a silicon rubber sealing cover is detachably covered on the opening of the fuse mounting hole.
In a further development, the end of the rod fuse can preferably be connected via a high-voltage lead to a mounting spring arranged at the end of an elbow socket, which can be connected to an elbow plug, the end of the elbow plug being provided with an elbow plug connection, which presses the mounting spring into connection with the high-voltage lead when the elbow plug is plugged onto the elbow socket.
Compared with the prior art, the utility model has the advantages of: the capacitive voltage divider is connected to each phase high-voltage input end of the double-voltage transformer combination, and the three-phase capacitive voltage divider is introduced into the voltage transformer combination connected in a V-V wiring mode, so that a zero-sequence voltage signal can be provided on the premise that the shape and the size of the double-voltage transformer combination are not changed, the structure is simple, the occupied space is small, and the manufacturing cost is low; the capacitive voltage divider adopts a double-ceramic capacitor structure, the bearing voltage on the single capacitor is reduced by half, the insulation margin is greatly increased, and the possibility of breakdown fault is greatly reduced; meanwhile, even if the breakdown of a single capacitor occurs, the breakdown of the whole device cannot be caused, and the non-stop accident cannot be caused; after a single capacitor is broken down, an early warning signal similar to zero sequence voltage of a line can be generated and sent to a power distribution terminal due to the fact that the three-phase balance is broken, and enough time is won for timely arrangement of a power failure plan of a power system to complete preventive maintenance; the output capacitor is independently placed, can be maintained and replaced, and solves the problem that the service life of an electronic product affects the overall use of the device; the quick disassembling and assembling mechanism with the built-in protective fuse is designed, the time for disassembling and assembling the fuse on site is shortened to 1 minute from the original 2-3 hours, the design is very ingenious, and the maintenance and replacement efficiency is very high.
Detailed Description
The present invention will be described in further detail with reference to the following embodiments.
As shown in fig. 1 to fig. 3, the combined voltage transformer with zero sequence voltage output function includes a dual voltage transformer combination formed by two voltage transformers connected in a V-V connection manner, a capacitive voltage divider is connected to each phase high voltage input end of the dual voltage transformer combination, the capacitive voltage dividers are respectively connected to one end of an output capacitor 18 through a line, the other end of the output capacitor 18 is a zero potential end, the output capacitor 18 is connected in parallel with an input end of an adjusting module 19 capable of adjusting and compensating the voltage of the output capacitor 18, and an output end of the adjusting module 19 is a zero sequence voltage signal output end. The double-voltage transformer combination and the capacitive voltage divider are poured into an integral structure 1 through epoxy resin, and the output capacitor and the adjusting module are connected to the integral structure 1. Any capacitive voltage divider comprises two voltage dividing capacitors 6 arranged together in series. The capacitive voltage divider further comprises an upper shielding plate 7 and a lower shielding plate 5 which can reduce the interference of the combined magnetic field of the double voltage transformers, wherein the upper capacitors in the two voltage division capacitors 6 are connected with the upper shielding plate 7 through lines, the upper shielding plate 7 is connected with the corresponding high-voltage input end through lines, the lower ends of the lower capacitors in the two voltage division capacitors 6 are connected with the lower shielding plate 5, and the lower shielding plate 5 is connected with the output capacitor 18 through lines. The voltage division capacitor 6 is a ceramic capacitor made of high-voltage-resistant ceramic, a silicone rubber layer which is elastic and can buffer is coated on the surface of the ceramic capacitor, and the ceramic capacitor is connected with epoxy resin which forms the integral structure 1 through the silicone rubber layer. The distance between any capacitive voltage divider and the coil of the two-voltage transformer combination closest to the capacitive voltage divider is greater than or equal to 50 mm.
The double-voltage transformer combination has the specific structure that a first coil group 4 and a second coil group 3 can be mutually inductively sleeved on a first iron core 2, one end of the first coil group 4 is connected with an A-phase high-voltage input end through a circuit, the other end of the first coil group 4 is connected with a B-phase high-voltage input end through a circuit, the second coil group 3 is connected with a first low-voltage signal output end 17, a third coil group and a fourth coil group are mutually inductively sleeved on the second iron core, one end of the third coil group is connected with a B-phase high-voltage input end through a circuit, the other end of the third coil group is connected with a C-phase high-voltage input end through a circuit, the fourth coil group is connected with a second low-voltage signal output end, and the A-phase high-voltage input end, the B-phase high-voltage input end and the C-phase high-voltage input end are respectively connected with a capacitive voltage divider, and the three capacitive voltage dividers are respectively connected with the output capacitor 18 through lines. The phase A high-voltage input end, the phase B high-voltage input end and the phase C high-voltage input end are arranged on the upper portion of the integral structure 1 at intervals in parallel, a corresponding fuse 10 is detachably arranged on the integral structure 1 corresponding to any phase high-voltage input end, and any phase high-voltage input end is communicated with a high-voltage cable through the corresponding fuse 10. The fuse 10 is a rod fuse, the rod fuse is inserted in a fuse mounting hole on the upper part of the integral structure 1, a conductive embedded piece 8 is arranged on the bottom surface of the fuse mounting hole, the embedded piece 8 is connected with a corresponding capacitive voltage divider through a circuit, an ejection spring 9 capable of ejecting the rod fuse is arranged on the embedded piece 8, when the rod fuse is inserted in the fuse mounting hole, one end of the rod fuse is abutted against the ejection spring 9 to enable the ejection spring 9 to contract and compress, a quick-mounting and dismounting mechanism 11 is detachably arranged in an opening of the fuse mounting hole, the other end of the rod fuse is abutted against the quick-mounting and dismounting mechanism 11, and a silicon rubber sealing cover 12 is detachably covered on the opening of the fuse mounting hole. The end of the rod fuse is connected via a high voltage lead 13 to a mounting spring 14 provided at the end of an elbow socket which can be connected to an elbow plug 16, and an elbow plug connector 15 is provided at the end of the elbow plug 16, and when the elbow plug 16 is inserted into the elbow socket, the elbow plug connector 15 presses the mounting spring 14 to connect to the high voltage lead 13.
As shown in FIG. 1, ZA,ZB,ZCThree capacitive voltage dividers are connected in series with two voltage division capacitors 6, wherein points A, B and C in the figure 1 are respectively connected with a phase-A power supply, a phase-B power supply and a phase-C power supply, and point Z in the figure 10Namely the output capacitor 18, the adjusting module 19 can adjust and compensate the voltage of the output capacitor 18, and the specific circuit structure of the adjusting module 19 belongs to the prior art, so that the detailed description is not needed. Points da and dn in fig. 1 represent the zero sequence voltage signal output end, points a and b constitute the first low voltage signal output end 17, and points b and c constitute the second low voltage signal output end. As shown in fig. 2, the overall structure 1 is formed after epoxy resin is poured, each of the second coil group 3 and the fourth coil group includes two independent coil groups, one coil group of the second coil group 3 corresponds to the points 1a and 1b, the other coil group of the second coil group 3 corresponds to the points 2a and 2b, similarly, one coil of the fourth coil group corresponds to the points 1b and 1c, and the other coil of the fourth coil group corresponds to the points 2b and 2c, and the specific connection is the connection structure shown in fig. 1, so detailed description is omitted.
As shown in fig. 3, the specific structure of the quick assembly and disassembly mechanism 11 belongs to the known technology, in the figure, a cover plate is adopted, the cover plate is connected in a fuse mounting hole through a screw, an iron core 2, a second coil group 3, a first coil group 4 form a voltage transformer, another iron core, a third coil group and a fourth coil group form another voltage transformer, the two voltage transformers are arranged side by side as shown in fig. 2 and are connected according to an electrical schematic diagram shown in fig. 5, three phases of high voltage A, B, C are respectively led out through conducting wires, a connection schematic of a phase is given in fig. 3 and is connected with a fuse 10 through an embedded piece 8 and an ejecting spring 9, the quick assembly and disassembly mechanism 11 seals the fuse 10 in the fuse mounting hole, and simultaneously, the electrical connection is formed and is connected with a high-voltage cable in an elbow plug 16 through a high-voltage lead 13, a mounting spring 14 and an elbow plug, forming a complete high-voltage connecting passage. The embedded part 8 is connected with a lead to lead high-voltage signals to the upper pole plate of a voltage-dividing capacitor 6 made of high-voltage resistant ceramic, the upper part of the ceramic capacitor is provided with an upper shielding plate 7 and is connected with a high-voltage wire, the lower part of the ceramic capacitor is provided with a lower shielding plate 5 which is directly grounded, the three groups of high-voltage ceramic capacitors are arranged in parallel, and the lower pole plate of the three groups of high-voltage ceramic capacitors is led to an output capacitor 18 and an adjusting module 19 along the iron core 2 through the lead to form. And then the iron core 2, the coil group, the capacitive voltage divider, the embedded part 8, the high-voltage lead 13, the low-voltage signal output end and the output capacitor 18 are integrally vacuum-cast and cured into the integral structure 1 through epoxy resin insulating materials.
The working principle is that a voltage transformer is one of key devices in an electric power system. The high-voltage signal in the primary system of the power grid can be converted into a standard low-voltage signal in a high-accuracy manner according to a specified proportion, and the standard low-voltage signal is used for a subsequent secondary metering, measuring and protecting system. Currently, there are two general types of voltage transformers used in power distribution systems, and the connection method is shown in fig. 4 and 5, where "Y" connection or "V-V" connection (double V for short). For the first Y-connection, 3 voltage transformers are needed, and zero sequence voltage signals can be obtained by the secondary winding "open delta" connection. However, the combined product has a large overall volume, and in the application of a power distribution network, especially in a neutral point insulation or non-effective grounding system, when a single-phase fault occurs, a non-fault phase voltage can rise to a line voltage, and at the moment, a ferromagnetic resonance fault of the voltage transformer is very easily caused, so that an anti-ferromagnetic resonance type 4PT connection voltage transformer shown in fig. 6 is designed. The 4PT connection voltage transformer is a 4PT formed by adding an ON winding at a Y-type neutral point, after a single-phase ground fault occurs in a system, the ON winding is responsible for bearing a part of zero-sequence voltage drop so as to complete the task of zero-sequence voltage measurement, and the voltage lifting degree ON a non-fault phase winding is limited, so that the probability of resonance occurrence is greatly reduced. However, the 4PT structure is additionally provided with a voltage transformer compared with the Y-shaped connection method, so that the size is further increased, higher requirements are placed on the installation space of equipment such as a ring main unit or a switch cabinet in practical application, and no method is available for realizing 'generalization'; and because this kind of product secondary connector lug is more, connects wrong line and leads to the probability of secondary short circuit trouble higher during site operation, also promotes installer's requirement. Therefore, a second type of "V-V" connection is usually adopted in medium voltage switchgear such as ring main units. The connection method only needs two voltage transformers, has small volume and relatively low cost, but cannot provide zero-sequence voltage signals. At present, with the development of the project of 'one-time and two-time integration' of the national grid company, the technical scheme of 'single-phase earth fault judgment and addressing' of distribution network automation is continuously popularized, and transient small signal processing logic based on zero sequence voltage and zero sequence current waveform acquisition and processing is widely applied, so that the product with the double-V structure cannot meet the requirement of the current distribution network automation. Moreover, the requirement of miniaturization of the switch cabinet requires that the high-voltage fusing protection is built in the transformer body and is connected by an elbow type cable plug, but the structure is difficult to replace a fusion tube on site, so that the development of the double-V structure combined voltage transformer which is convenient to install and maintain, is miniaturized and can provide a zero-sequence voltage signal is a product urgently needed by the current power distribution network.
The utility model discloses to the shortcoming that above-mentioned exists, provide an elbow type cable plug connection, take the quick installation mechanism of fuse, can provide zero sequence voltage signal's combination voltage transformer, satisfied electric wire netting company "the second and amalgamation" reform transform, upgrade to zero sequence voltage signal's needs, moreover, small, with low costs, installation and maintenance convenient and fast, anti ferromagnetic resonance can the strong novel two V structure combination voltage transformer.
Principle analysis: by adopting a capacitance voltage division principle, a zero-sequence voltage signal is generated through three-phase combination, as shown in fig. 7, and the specific analysis is as follows:
assume the impedance of the A-phase high-voltage arm is Z
AAt a voltage of
AThe impedance of the B-phase high-voltage arm is Z
BAt a voltage of
BC-phase high-voltage arm impedance of Z
CAt a voltage of
C, Z
A=Z
B=Z
C=Z
1Then for the voltage at the input of the regulating unit
Comprises the following steps:
namely, it is
As can be seen from the formula (2),
the zero sequence voltage is output according to a certain proportion, and the output signal is adjusted and compensated through an adjusting circuit to obtain a zero sequence voltage signal meeting the accuracy requirement.
The design scheme is combined with the traditional double-voltage transformer combination to form a product, the principle of which is shown in figure 1, and the structure of which is shown in figures 2 and 3.
A, B, C three-phase voltage is led out from a high-voltage input end of the double-voltage transformer combination, each phase is provided with two high-voltage ceramic capacitors connected in series, the three phases are connected in parallel, a secondary voltage-dividing capacitor is connected at a connecting point, the voltages at two ends of the secondary voltage-dividing capacitor are taken, and a zero-sequence voltage signal is output through an adjusting module. Two high-voltage ceramic capacitor series structures are adopted for high voltage, and compared with a voltage transformer with the traditional capacitor voltage division, the high-voltage capacitor has a one-level series structure, the voltage borne by a single capacitor is halved, the insulation margin is greatly increased, and the possibility of breakdown fault is greatly reduced. Meanwhile, even if the breakdown of a single capacitor occurs, the breakdown of the whole sensor cannot be caused, and the non-stop accident cannot be caused; and after a single capacitor is broken down, due to the fact that the balance of three phases is broken, an early warning signal similar to zero sequence voltage of a line can be generated and is uploaded to a power distribution terminal (DTU/FTU), and enough time is obtained for timely arrangement of a power failure plan and completion of preventive maintenance of a power system. The surface of the high-voltage capacitor is sprayed with silicon rubber to form an elastic buffer layer, so that the surface of the high-voltage capacitor is ensured to be in insulated and reliable contact with external epoxy resin, and the occurrence of creepage breakdown accidents along the surface is prevented. And an enough insulation distance is reserved between the high-voltage capacitor and the double-voltage transformer combination, and shielding plates are arranged above and below the high-voltage capacitor, so that the electromagnetic field generated when the double-voltage transformer combination operates is ensured not to influence the capacitance. The output capacitor is led out to the side face of the low-voltage output end, and can be overhauled and replaced at any time, so that the problem that the service life of an electronic element is not matched with the service life of power equipment, and popularization and use are affected is effectively solved. The high voltage input is designed as an insulating support connected to the elbow plug and is electrically connected to the elbow plug by means of a built-in conductor. Move out the protection fuse of traditional product at elbow type plug internal assembly, have the fuse room of taking the mechanism of installing and removing fast at product top design, shorten the time of installing, tearing open the fuse to 1 minute from the 2 ~ 3 hours of traditional product.
Adopt the utility model provides a technical solution utilizes to implant capacitive voltage divider, has realized the voltage transformer of two V methods of connecing, can gather zero sequence voltage signal, satisfies smart power grids's demand, and simultaneously, the design has built-in fuse to install and remove the mechanism fast, makes things convenient for the operation and the maintenance of distribution network. More importantly, the technical scheme is completed on the premise of not changing the appearance size of the original product, and is very important to the popularization and the reconstruction of the power distribution network!
In the embodiment of the utility model provides an in, provide a technical scheme that high voltage capacitive voltage divider makes up and produces zero sequence voltage signal to implant it in the current voltage transformer of two V structures that have used in batches.
In the embodiment of the utility model provides an in, provide three group's capacitive voltage divider combination and produce zero sequence voltage's technical scheme, when satisfying the zero sequence signal that provides, stopped the risk that product ferroresonance takes place.
In the embodiment of the utility model provides an in, capacitive voltage divider high pressure adopts two ceramic capacitor structures, solves the difficult problem that punctures back high voltage and damage secondary equipment to quick warning has been realized.
In the embodiment of the utility model provides an in, capacitive voltage divider and two V body electrical part insulation distance are greater than or equal to 50mm, guarantee its electrical property and reliable operation ability.
In the embodiment of the utility model provides an in, set up the shield plate from top to bottom at high-voltage capacitor, go up the shield plate and link to each other with high-voltage lead wire, shield plate ground connection down forms regional even electromagnetic field, ensures that the electromagnetic field when two V bodies move does not exert an influence to the electric capacity.
In the embodiment of the utility model provides an in, capacitive voltage divider high pressure ceramic capacitor surface spraying silicon rubber forms the elastic buffer layer, guarantees the insulating reliable contact of high-pressure capacitor surface and outside epoxy pouring, prevents the emergence of following creepage breakdown accident.
In the embodiment of the utility model provides an in, low pressure electric capacity is placed in secondary terminal box side, can maintain at any time, change, guarantees that electronic component's life-span problem does not influence the operation of equipment itself.
In the embodiment of the utility model provides an in, shift out built-in protection fuse from elbow type plug, place at the product top, be equipped with the mechanism of installing and removing fast, will adorn, tear time of fuse shorten to 1 minute from the 2 ~ 3 hours of traditional product.
The utility model has the advantages that: the three-phase capacitive voltage divider is introduced into a voltage transformer with a double-V structure, so that a zero-sequence voltage signal can be provided on the premise that the shape and the size of the voltage transformer are not changed; the capacitive voltage divider adopts a double-ceramic capacitor structure, solves the operation risk and gives an alarm in time; the low-voltage capacitor is independently placed, can be maintained and replaced, and solves the problem that the service life of an electronic product affects the use of the body; a built-in protection fuse quick assembly and disassembly mechanism is designed, and the time for assembling and disassembling the fuse on site is shortened from 2-3 hours to 1 minute.