COMPACT OUTDOOR OPEN-CLOSE TYPE CURRENT TRANSFORMER

Abstract

The invention discloses a compact outdoor open-close type current transformer which comprises a transformer shell formed by butt joint of an upper half housing and a lower half housing, wherein an upper half hollow framework and a lower half hollow framework are arranged in the transformer shell, an upper half iron core is arranged in the upper half hollow framework, a lower half iron core is arranged in the lower half hollow framework, and a spring jacking piece is arranged between the upper half hollow framework and the upper half iron core; a winding wire is arranged on the lower half hollow framework, a framework baffle and a sealing gasket connected to the framework baffle are arranged at the butt joint of the upper half hollow framework and the lower half hollow framework, and the framework baffle and the sealing gasket after being connected are respectively and correspondingly embedded in a guide positioning groove arranged in the upper half housing and the lower half housing; and inner spaces of the upper half housing and the lower half housing are filled with epoxy resin, a pair of lug hole plates, and a pressing plate and bolts for connecting the lug hole plates are arranged on the transformer shell. According to the invention, the fixing reliability between a cable and the transformer is improved, and screws can be prevented from falling off during high-altitude operation.

Claims

1. A compact outdoor open-close type current transformer, characterized by comprising a transformer shell formed by connecting an upper half housing and a lower half housing which are semi-annular in a butt-joint mode, wherein an upper half hollow framework and a lower half hollow framework which are semi-annular are respectively arranged in the upper half housing and the lower half housing, a semi-annular upper half iron core is arranged in the upper half hollow framework, and a semi-annular lower half iron core is arranged in the lower half hollow framework; a winding wire is arranged on an outer contour of the lower half hollow framework, and a butt joint mouth part is respectively formed at a butt joint of the upper half housing and the lower half housing, a butt joint of the upper half hollow framework and the lower half hollow framework and a butt joint of the upper half iron core and the lower half iron core; and a compact winding structure for increasing a winding space is formed by arranging the mouth part of each butt-joint connection with the depth dimension of the mouth part larger than the width dimension of the mouth part.

2. The compact outdoor open-close type current transformer according to claim 1, characterized in that the compact winding structure for increasing the winding space is formed by the following modes: an annular oval shape is respectively formed after the butt-joint connection of the upper half housing and the lower half housing, after the butt-joint connection of the upper half hollow framework and the lower half hollow framework, and after the butt-joint connection of the upper half iron core and the lower half iron core; and a long axis of the annular oval is positioned in a parallel direction of a butt-joint connection surface, and a short axis of the annular oval is positioned in a perpendicular direction of the butt-joint connection surface.

3. The compact outdoor open-close type current transformer according to claim 1, characterized in that the compact winding structure for increasing the winding space is formed by the following modes: the upper half housing and the lower half housing are in butt joint to form a circular housing, the upper half hollow framework and the lower half hollow framework are in butt joint to form a circular hollow framework, the butt joint surface of the upper half housing and the lower half housing is eccentrically arranged towards a direction of the upper half housing, and the butt joint surface of the upper half hollow framework and the lower half hollow framework are eccentrically arranged towards a direction of the upper half hollow framework.

4. The compact outdoor open-close type current transformer according to claim 1, characterized in that a spring jacking piece is arranged between an inner side wall of the upper half hollow framework and the upper half iron core, a framework baffle and a sealing gasket connected with the framework baffle are respectively arranged at the butt joint of the upper half hollow framework and the lower half hollow framework, and the framework baffle and the sealing gasket after being connected are respectively and correspondingly embedded in the guide positioning groove arranged in the upper and lower half housings; and inner spaces of the upper half housing and the lower half housing are respectively filled with epoxy resin, the transformer shell is provided with a pair of lug hole plates used for fixing a primary side cable, and the primary side cable is fixed by the lug hole plates, and a pressing plate and bolts for connecting the lug hole plates.

5. The compact outdoor open-close type current transformer according to claim 1, characterized in that the upper half housing and the lower half housing are respectively and correspondingly provided with an upper fixing block and a lower fixing block which are butt-joint connected, and the upper fixing block and the lower fixing block are connected by special screws and anti-falling combined screw holes.

6. The compact outdoor open-close type current transformer according to claim 5, characterized in that the special screws comprise a bolt head, a polished rod section and a threaded section which are sequentially connected, and an outer diameter of the polished rod section is less than a thread bottom diameter of the threaded section; the anti-falling combined screw hole comprises a section of internal thread hole formed on the upper fixing block, a section of bolt hole connected to a lower end of the internal thread hole, and an internal thread hole formed on the lower fixing block, wherein the size of the section of internal thread hole formed on the upper fixing block and the size of the internal thread hole formed on the lower fixing block are respectively matched with the size of the external thread of the thread section of the special screw; and the threaded section of the special screw rotates into a section of internal threaded hole formed on the upper fixing block and sequentially penetrates through the section of internal threaded hole and the bolt hole to be connected with the internal threaded hole formed on the lower fixing block.

7. The compact outdoor open-close type current transformer according to claim 5, characterized in that the lower fixing block is provided with an inlay nut, and the inner threaded hole of the lower fixing block is provided on the inlay nut.

8. The compact outdoor open-close type current transformer according to claim 1, characterized in that a waterproof terminal is inserted into the lower half housing, and a lead connected with a winding wire on the lower half hollow framework passes through the waterproof terminal.

9. The compact outdoor open-close type current transformer according to claim 1, characterized in that the upper half housing and the lower half housing are respectively formed by connecting a shell seat and a shell cover; epoxy pouring holes are respectively formed in the upper half housing and the lower half housing, and the epoxy pouring holes are connected by buckles and are plugged with small sealing covers.

10. The compact outdoor open-close type current transformer according to claim 1, characterized in that an arc-shaped positioning plate is provided on the transformer shell at a position between a pair of the lug hole plates.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0024] FIG. 1 is a schematic structural view of a compact outdoor open-close type current transformer of the present invention;

[0025] FIG. 2 is a schematic structural view of the compact outdoor open-close type current transformer of FIG. 1 with a shell cover disassembled;

[0026] FIG. 3 is a schematic structural view in which an upper half iron core and a lower half iron core are provided in an upper half hollow framework and the lower half hollow framework of FIG. 2;

[0027] FIG. 4 is a top view of FIG. 3;

[0028] FIG. 5 is a schematic structural view after a sealing gasket is installed on the basis of FIG. 3;

[0029] FIG. 6 is a schematic structural view in which an upper half housing and a lower half housing are connected by special screws;

[0030] FIG. 7 is a schematic view illustrating an embodiment of a compact winding structure for forming an increased winding space in a compact outdoor open-close type current transformer; in the figure, the left part is one of the preferred modes of the compact winding structure (forming an annular oval shape after the butt joint connection), and the right part is another one of the preferred modes of the compact winding structure (forming an eccentric arrangement after the butt joint connection);

[0031] FIG. 8 is a schematic view of an embodiment of the upper and lower half housing of FIG. 7 corresponding to two compact winding configurations;

[0032] FIG. 9 is a schematic view of an embodiment of the upper and lower half hollow frameworks of FIG. 7 corresponding to two compact winding configurations;

[0033] FIG. 10 is a schematic view of an embodiment after the upper and lower half hollow frameworks corresponding to the two compact winding structure modes are internally provided with the corresponding upper and lower half iron cores; and

[0034] FIG. 11 is a schematic view for calculating the CAD area of the winding space (black body portion) corresponding to the two compact winding configurations in FIG. 10.

[0035] In the drawings: 1, an upper half housing; 2, a lower half housing; 3, a transformer shell; 4, an upper half hollow framework; 5, a lower half hollow framework; 6, an upper half iron core; 7, a lower half iron core; 8, a spring jacking piece; 9, a winding wire; 10, a framework baffle; 11, a sealing gasket; 12, a guide positioning groove; 13, a primary side cable; 14, a lug hole plate; 15, a pressing plate; 16, a bolt; 17, an upper fixing block; 18, a lower fixing block; 19, a special screw; 20, a bolt head; 21, a polished rod section; 22, a threaded section; 23, an inlay nut; 24, a waterproof terminal; 25, a lead; 26, a shell seat; 27, a shell cover; 28, an epoxy pouring hole; 29, a small sealing cover; and 30, an arc-shaped positioning plate.

DETAILED DESCRIPTION OF THE INVENTION

[0036] The detailed description of the present invention are further described below in combination with the attached drawings and embodiments. The following embodiments are only intended to more clearly illustrate the technical solution of the present invention, and are not intended to limit the scope of the present invention.

Embodiment 1

[0037] As shown in FIGS. 1 to 11, the embodiment of the compact outdoor open-close type current transformer comprises a transformer shell 3 formed by connecting an upper half housing 1 and a lower half housing 2 which are semi-annular in a butt-joint mode, wherein the upper half hollow framework 4 and the lower half hollow framework 5 which are semi-annular are respectively arranged in the upper half housing 1 and the lower half housing 2, a semi-annular upper half iron core 6 is arranged in the upper half hollow framework 4, and a semi-annular lower part is arranged in the lower half hollow framework 5; a winding wire 9 is arranged on the outer contour of the lower half hollow framework 5, and a butt joint mouth part is respectively formed at a butt joint of the upper half housing 1 and the lower half housing 2, a butt joint of the upper half hollow framework 5 and the lower half hollow framework 5 and a butt joint of the upper half iron core 6 and the lower half iron core 7; and a compact winding structure for increasing the winding space is formed by arranging the mouth part of each butt-joint connection with the depth dimension of the mouth part larger than the width dimension of the mouth part.

[0038] According to one of the preferred ways of forming the compact winding structure for increasing the winding space, an annular oval shape is respectively formed after the butt-joint connection of the upper half housing 1 and the lower half housing 2, after the butt-joint connection of the upper half hollow framework 4 and the lower half hollow framework 5, and after the butt-joint connection of the upper half iron core 6 and the lower half iron core 7; and a long axis of the annular oval is positioned in the parallel direction of the butt-joint connection surface, and a short axis of the annular oval is positioned in the perpendicular direction of the butt-joint connection surface.

[0039] According to another preferred way of forming the compact winding structure for increasing the winding space, the upper half housing 1 and the lower half housing 2 are in butt joint to form a circular housing, the upper half hollow framework 4 and the lower half hollow framework 5 are in butt joint to form a circular hollow framework, the butt joint surface of the upper half housing 1 and the lower half housing 2 is eccentrically arranged towards the direction of the upper half housing 1, and the butt joint surface of the upper half hollow framework 4 and the lower half hollow framework 5 are eccentrically arranged towards the direction of the upper half hollow framework 4.

[0040] Preferably, a spring jacking piece 8 is arranged between the inner side wall of the upper half hollow framework 4 and the upper half iron core 6, a framework baffle 10 and a sealing gasket 11 connected with the framework baffle 10 are respectively arranged at the butt joint of the upper half hollow framework 4 and the lower half hollow framework 5, and the framework baffle 10 and the sealing gasket 11 after being connected are respectively and correspondingly embedded in the guide positioning groove 12 arranged on the upper and lower half housings 1 and 2; inner spaces of the upper half housing 1 and the lower half housing 2 are respectively filled with epoxy resin, the transformer shell 3 is provided with a pair of lug hole plates 14 used for fixing a primary side cable 13, and the primary side cable 13 is fixed by the lug hole plates 14, and a pressing plate 15 and bolts 16 for connecting the lug hole plates 14.

[0041] Preferably, the upper half housing 1 and the lower half housing 2 are respectively and correspondingly provided with an upper fixing block 17 and a lower fixing block 18 which are butt-joint connected, and the upper fixing block 17 and the lower fixing block 18 are connected by special screws 19 and anti-falling combined screw holes.

[0042] According to the embodiment, the special screws 19 comprise a bolt head 20, a polished rod section 21 and a threaded section 22 which are sequentially connected, and the outer diameter of the polished rod section 21 is less than the thread bottom diameter of the threaded section 22; the anti-falling combined screw hole comprises a section of internal thread hole formed on the upper fixing block 17, a section of bolt hole connected to the lower end of the internal thread hole, and an internal thread hole formed on the lower fixing block 18, wherein the size of the section of internal thread hole formed on the upper fixing block 17 and the size of the internal thread hole formed on the lower fixing block 18 are respectively matched with the size of the external thread of the thread section of the special screw 19; and the threaded section of the special screw 19 rotates into a section of internal threaded hole formed on the upper fixing block 17 and sequentially penetrates through the section of internal threaded hole and the bolt hole to be connected with the internal threaded hole formed on the lower fixing block 18.

[0043] According to the embodiment, the lower fixing block 18 is provided with an inlay nut 23, and the inner threaded hole of the lower fixing block 18 is provided on the inlay nut 23.

[0044] According to the embodiment, a waterproof terminal 24 is inserted into the lower half housing 2, and a lead 25 connected with a winding wire 9 on the lower half hollow framework 5 passes through the waterproof terminal 25.

[0045] According to the embodiment, the upper half housing 1 and the lower half housing 2 are respectively formed by connecting a shell seat 26 and a shell cover 27.

[0046] Preferably, epoxy pouring holes 28 are respectively formed on the upper half housing 1 and the lower half housing 2, and the epoxy pouring holes 28 are connected by buckles and are plugged with small sealing covers 29.

[0047] According to the embodiment, an arc-shaped positioning plate 30 is provided on the transformer shell 3 at a position between a pair of the lug hole plates 14.

[0048] According to the embodiment, the shell seat 26 and the shell cover 27 are connected by ultrasonic welding.

Embodiment 2

[0049] FIGS. 7 to 11 show two implementations of a compact winding structure for forming an increased winding space in a compact outdoor open-close type current transformer; in the figure, the left part is one of the preferred modes of the compact winding structure (forming an annular oval shape after the butt-joint connection), and the right part is another one of the preferred modes of the compact winding structure (forming an eccentric arrangement after the butt-joint connection).

[0050] For convenience, one of the preferred modes is simply referred to as an annular oval compact structure; and one of the preferred modes is simply referred to as a circular eccentric compact structure.

[0051] As shown in FIG. 7, the annular oval compact structure substantially conforms to the outer dimension of the circular eccentric compact structure.

[0052] The inner hole of the annular oval compact structure is an oval inner hole of φ 36 mm. The long axis direction of the oval is located in the direction perpendicular to the butt joint surface, and the requirement of compact design can be met. A certain winding space is increased compared with a conventional non-eccentric butt joint surface with a circular symmetric structure, and enameled wires with larger cross sections or more turns can be wound.

[0053] The annular oval compact structure described above can be further improved. Since the oval of the ring-shaped oval compact structure has a part of the space not fully utilized, and the diameter of the inner hole is just φ 36 mm, it is possible that the standard-sized cable of φ 36 mm will not easily penetrate through it in the later stage if slightly deformed.

[0054] According to a further improvement solution, a circular eccentric compact structure is adopted, the diameter of the inner hole of the circular eccentric compact structure is φ 36.4 mm, and the penetration of the standard-sized cable of φ 36 mm can be fully ensured.

[0055] As shown in FIGS. 8 to 9, compared with the annular oval compact structure of the same specification, the plastic wall thickness of the hollow framework of the circular eccentric compact structure is greater than that of the annular oval compact structure, the wall thickness of the housing is increased from 2 mm to 2.2 mm, and the wall thickness of the hollow framework is increased from 1.5 mm to 2 mm.

[0056] As shown in FIG. 10, the circular eccentric compact structure is better in transformer accuracy performance than the annular oval compact structure. Due to the accuracy performance of the transformer, on one hand, the internal resistance of the winding is reduced by virtue of the thicker enameled wire; on the other hand, the section of the iron core is required to be large enough, the length of a magnetic circuit of the transformer is small, and loss is reduced as much as possible so as to achieve higher performance. Here, we consider the iron core firstly, without thinking about the longitudinal dimension of the iron core, and consider the transverse dimension of both the annular oval compact structure and the circular eccentric compact structure, which are both 8.5 mm. The annular oval compact structure and the circular eccentric compact structure have the same iron core sections when the longitudinal dimension of the iron core is the same. However, the annular oval compact structure has a larger magnetic circuit length and more loss due to its annular oval core. The circular eccentric compact structure has circular oval iron core, and the magnetic path length is shorter. Therefore, with an overall consideration, the circular eccentric compact structure has better performance of the iron core, and the transformer has more excellent accuracy performance.

[0057] As shown in FIG. 11, the winding space area (the black body part is the sum of the black body areas of the upper part and the lower part) is selected in the CAD software, and the winding space areas of the annular oval compact structure and the circular eccentric compact structure are calculated by utilizing the area calculation function of the CAD software:

Winding space area of annular oval compact structure=upper black body area+upper black body area==389.1070+570.8891=959.9961 mm.sup.2

Winding space area of circular eccentric compact structure=upper black body area+upper black body area=454.0089+631.7706=1085.7795 mm.sup.2.

[0058] According to the above calculation, it can be further concluded that the winding space area of the circular eccentric compact structure is improved by about 13.1% compared with the winding space area of the annular oval compact structure. Therefore, it can be judged that the circular eccentric compact configuration is the first preferred configuration.

[0059] Of course, it is also possible to combine the above-mentioned two structures as desired.

[0060] The above mentioned are only preferred embodiments of the invention. It will be appreciated by those skilled in the art that some modifications and adaptations may be made without departing from the principle of the invention, and such modifications and alterations are intended to be included within the scope of the invention.