KR102664034B1 - converter valve - Google Patents

Abstract

This application relates to a converter valve, comprising at least two converter valve valve layers and at least one electrical connection component, wherein the at least two converter valve valve layers are stacked on each other; Adjacent converter valve layers of the at least two converter valve layers are electrically connected in series in a diagonal manner through one of the at least one electrical connection component.

Description

converter valve

This application relates to the field of power electronics and power system technology, and in particular to converter valves.

The converter valve is an important component of high-voltage direct current transmission, and typically several tens to nearly a hundred level power electronic devices must be connected in series to implement high-voltage on/off control. The series-connected power electronic devices are each included in a plurality of series-connected valve modules, and each valve module includes a plurality of series-connected power electronic devices. A plurality of valve modules are divided into several layers and distributed in space, and each layer is a converter valve layer. A plurality of converter valve valve layers constitute a converter valve.

The inventor of the present application found that the volume of the conventional converter valve is relatively large, and the support installation and suspension installation are incompatible.

In one embodiment of the present application, a converter valve is provided, comprising an electrical connection part and at least two converter valve layers, wherein the at least two converter valve layers are stacked on top of each other, and the at least two converter valve layers are stacked on top of each other, and the converter valve layer is connected to the converter valve through the electrical connection part. connected in series; Both ends of the electrical connection component are electrically connected to diagonal positions of two adjacent converter valve layers of the at least two converter valve layers.

When a converter valve configured according to the above connection method is used, the voltage difference between the valve modules included therein is relatively small, so the safety distance can be relatively small, and the volume of the overall converter valve can be relatively small. .

Optionally, the converter valve also includes a shielded contact terminal adjacent a last level converter valve valve layer of the at least two converter valve valve layers, the shield contact terminal providing electromagnetic shielding, wherein the shield contact terminal is adjacent to the last level converter valve valve layer of the at least two converter valve valve layers. It is electrically connected to one of the at least two contact terminals of the valve layer, wherein the contact end is not electrically connected to the electrical connection part.

Shielded contact terminals provide electromagnetic shielding and can also serve as lead-out terminals. One component can be saved for the converter by using shielded contact terminals. Therefore, it is possible to reduce the volume and save costs at the same time.

Optionally, the converter valve may also include a pressure-resistant insulator insulatingly supported between the two adjacent converter valve valve layers.

Alternatively, the converter valve may also include a tensioned insulator that is insulatingly pulled between the two adjacent converter valve valve layers.

The pressure-resistant and tension-type insulators allow the converter valve to switch relatively easily between a supported converter valve and a suspended converter valve.

1 is a connection diagram between the converter valve valve layers of the converter valve in the prior art.
Figure 2 shows a connection diagram between valve layers of the converter valve in the converter valve according to an embodiment of the present application.
Figure 3 shows a connection diagram between valve layers of the converter valve in the converter valve according to another embodiment of the present application.
Figure 4 is a structural diagram of a converter valve according to another embodiment of the present application.
Figure 5 is a connection diagram of a converter valve according to another embodiment of the present application.
Figure 6 is a local structural diagram of a converter valve according to another embodiment of the present application.
Figure 7 is a local structural diagram of a converter valve according to another embodiment of the present application.
Figure 8 is a structural diagram of a converter valve according to another embodiment of the present application.
Figure 9 is a structural diagram of a converter valve according to another embodiment of the present application.

A clear and complete description of the technical solutions in the embodiments of this application will be provided with reference to the drawings in the embodiments of this application below, and the described embodiments are only some embodiments of the present application and are not all embodiments. It is self-evident. All other embodiments that can be obtained by those skilled in the art based on the embodiments of the present application without requiring creative efforts should all fall within the scope of the present application.

The terms “first,” “second,” “third,” and “fourth” in the claims, specification, and drawings of this application are intended to distinguish different objects and are not intended to explain a specific order. You will understand. As used in the specification and claims of this application, the terms “including” and “included” indicate the presence of a described feature, whole, step, operating element, and/or module, but one or more other features, whole, etc. , does not exclude the presence or addition of steps, operations, elements, modules and/or other sets.

It will also be understood that the terms used herein in the specification of the present application are only for describing specific embodiments and are not intended to limit the present application. For example, as used in the specification and claims of this application, unless the context clearly specifies that other situations exist, the meaning of “one”, “one”, and “corresponding” in the singular form shall be used in the plural form. Includes. Furthermore, it is to be understood that the term “and/or” used in the specification and claims of the present application refers to any and all possible combinations of one or more of the items neatly listed and includes such combinations. will be.

Figure 1 is a connection diagram between converter valve valve layers in the prior art. As shown in Figure 1, the converter valve 1000 includes two converter valve valve layers 11 and 12 and an electrical connection component 13. 111 and 112 are both ends of the converter valve valve layer 11, and 121 and 122 are both ends of the converter valve valve layer 12. The electrical connection part 13 is electrically connected between opposite ends 112 and 122 of the converter valve layers 11 and 12 in the same direction. The current direction is as indicated by the arrow.

Assuming that the electrical characteristics and operating mode of the converter valve layer 11 and the converter valve layer 12 are the same, the voltage across the converter valve layer 11 and the voltage across the converter valve layer 12 are both U am. Then, it is clear that the voltage between the stage 111 of the converter valve valve layer 11 and the stage 121 of the converter valve valve layer 12 is 2U. Assuming that the safety distance corresponding to the voltage U is d, the distance between the converter valve layer 11 and the converter valve layer 12 is at least 2d.

The inventor of the present application found that the voltage difference between the valve layers of the converter valve in the U-type connection is relatively large. Since the safety distance and the voltage value are directly proportional, the relatively large voltage difference between the valve layers of the converter valve in the U-type connection makes the safety distance between the valve layers of the converter valve relatively large, and further makes the volume of the converter valve relatively large.

In addition, the inventor of the present application has already built nearly 100 direct current transmission projects within the current global scope, and except for the Chinese domestic projects mainly concentrated since 2000, the remaining projects have nearly 40 projects with an operating time of over 20 years. It was discovered that the converter valve equipment was aging severely and the demand for modification was rapidly increasing. Conventional converter valve equipment is mainly provided by companies such as ABB, Siemens, and Alstom. Modifying DC construction generally involves installing a newly manufactured converter valve valve tower into the valve hole, and since the valve hole length, width and height are already fixed, the newly manufactured converter valve must be sufficiently tight to avoid many construction tasks. It can be applied in the field. Conventional converter valves are mainly studied based on the characteristics of ultra-high voltage direct current construction, such as high voltage level and large transport capacity. It has poor compatibility and lacks advantages. A tight converter valve that is smaller in size, more rational in structure, and more versatile is needed.

Currently, converter valve towers have two structures: suspended type and supported type. Suspension type valve tower uses a flexible connection between floors, usually a suspension insulator and a rotating link, which can move relatively between valve layers when the valve tower is subjected to external forces such as earthquakes, and the rotating link is a suspension insulator between floors. Prevents damage from excessively large shear forces and has good anti-seismic performance; The supported valve tower is fixedly connected between floors using a supporting insulator, and the valve tower is again fixed to the ground installation base through the supporting insulator. In actual construction, when the DC transmission voltage level exceeds ±500kV, the suspension type is generally used, and when the DC transmission voltage is below ±500kV, the suspension type or the support type can be used depending on construction demands. However, in Korea, there are almost no general-purpose converter valve design methods that are compatible with suspension type and support type.

Therefore, this application proposes a technical solution for a converter, which includes at least two converter valve layers and at least one electrical connection part. The at least two converter valve layers are stacked on top of each other; Adjacent converter valve layers of the at least two converter valve layers are electrically connected in series in a diagonal manner through one of the at least one electrical connection component.

According to the technical solution of the present application, an electrical connection is made to the diagonal end of the valve layer of an adjacent converter valve through an electrical connection part, and the voltage difference between each point of the valve layer of an adjacent converter valve can be balanced, so that the adjacent converter The voltage arch between the two points where the voltage difference between the valve layers is highest can be lowered. Furthermore, the requirements for the safety distance of the converter valve can be met by using a smaller inter-layer spacing, and the volume of the converter valve can be made relatively small.

A detailed description of the technical solution proposed in this application will be given with reference to the drawings below.

Figure 2 shows a connection diagram between valve layers of the converter valve in the converter valve according to an embodiment of the present application.

As shown in Figure 2, the converter valve 2000 may include two converter valve valve layers 21 and 22 and an electrical connection component 23 that are stacked. 211 and 212 are both ends of the converter valve valve layer 21, and 221 and 222 are both ends of the converter valve valve layer 22. The electrical connection part 23 is electrically connected between diagonal ends 212 and 221 of the converter valve valve layers 21 and 22. The current direction may be as indicated by the arrow.

Assuming that the electrical characteristics and operating modes of the converter valve layer 21 and the converter valve layer 22 are the same, the voltage across the converter valve layer 21 and the voltage across the converter valve layer 22 are both U am. Then, since the diagonal ends (212 and 221) of the converter valve valve layers (21 and 22) are at equal potential, between the end (211) of the converter valve valve layer (21) and the end (212) of the converter valve valve layer (22). The voltage of is U, and the voltage between the end 212 of the converter valve valve layer 21 and the end 222 of the converter valve valve layer 22 is U, and are all less than 2U. The safety distance between the converter valve layer 21 and the converter valve layer 22 may be less than 2d.

Optionally, both ends of the electrical connection part 23 may also be electrically connected to the end 211 of the converter valve valve layer 21 and the end 222 of the converter valve valve layer 22, respectively.

As shown in Figure 2, optionally, stage 211 may include point A of the converter valve layer 21, and may also include point B of the converter valve layer 21, and It can include any point between line segments AB. Furthermore, stage 211 may also include a point proximate to line segment AB on the converter valve valve layer 21 .

As shown in Figure 2, correspondingly, the electrical connection part 23 may be electrically connected to point A of the converter valve valve layer 21, and may also be electrically connected to point B of the converter valve valve layer 21. It can also be electrically connected to any point between line segments AB. In a further step, the electrical connection part 23 can be electrically connected to a point close to the line segment AB on the converter valve valve layer 21 .

As shown in Figure 2, similarly optionally, stage 221 may include point C of the converter valve layer 22, and may also include point D of the converter valve layer 22; , may also include any point between the line segments CD on the converter valve valve layer 22. As a further step, stage 221 may also include a point proximate to the line segment CD of the converter valve valve layer 22 .

As shown in Figure 2, correspondingly, the electrical connection part 23 may be electrically connected to point C of the converter valve valve layer 22, and may also be electrically connected to point D of the converter valve valve layer 22. You can. It can also be electrically connected to any point between the CDs on the converter valve valve layer 22. As a further step, the electrical connection part 23 can be electrically connected to a point close to the line segment CD of the converter valve valve layer 22 .

Optionally, the converter valve layer 21 and the converter valve layer 22 are provided in parallel.

Optionally, at least one of the converter valve valve layer 21 and the converter valve valve layer 22 may include at least two tangential ends, which are a high pressure end and a low pressure end, respectively.

Furthermore, stages 211 and 221 may have high-pressure stages, and stages 212 and 222 may have low-pressure stages; Optionally, stages 211 and 221 may also have low pressure stages, and stages 212 and 222 may also have high pressure stages. Correspondingly, both ends of the electrical connection part 23 are electrically connected to the tangential ends of the ends 221 and 212, respectively.

Optionally, converter valve 2000 may include three or more converter valve layers. Furthermore, at least one pair of adjacent converter valve layers among the three or more than three converter valve layers is electrically connected in series by electrical connection parts in a diagonal manner.

Using the converter valve, an electrical connection can be made to the diagonal end of the adjacent converter valve valve layer through an electrical connection part, and the voltage difference between each point of the adjacent converter valve valve layer can be balanced, so that the adjacent converter valve The voltage arch between the two points where the voltage difference between the valve layers is highest can be lowered. Furthermore, the requirements for the safety distance of the converter valve can be met by using a smaller inter-layer spacing, and the volume of the converter valve can be made relatively small.

Figure 3 shows a connection diagram between valve layers of the converter valve in the converter valve according to another embodiment of the present application.

As shown in Figure 3, the converter valve 3000 includes a converter valve valve layer 31, a converter valve valve layer 32, and an electrical connection part 33 (not shown). Among them,

The converter valve valve layer 31 includes two valve modules 311 and 312 connected in series and a connection part 313 electrically connected between the valve modules 311 and 312.

The converter valve valve layer 32 includes two valve modules 321 and 322 connected in series and a connection part 323 electrically connected between the valve modules 321 and 322.

The electrical connection part 33 includes a rigid conductive part 331, a supporting insulating ring 332 and a metal flexible bus bar 333. Among them, the rigid conductive portion 331 is electrically connected to the valve module 312. The metal flexible bus bar 333 has a flexible structure and is electrically connected between the rigid conductive portion 331 and the valve module 321. The support insulating ring 332 is insulated and supported between the rigid conductive portion 331 and the valve module 321. The support insulating ring 332 and the metal flexible bus bar 333 constitute a flexible connection.

Both ends of the electrical connection part 33 are electrically connected to diagonal ends (not shown) of the converter valve layer 31 and the converter valve layer 32, respectively.

As shown in Figure 3, optionally, the valve module 311 and the valve module 321 are stacked, and the valve module 312 and the valve module 322 are stacked. An air gap 35 is provided between the stacked valve module 311 and valve module 321 and the stacked valve module 312 and the valve module 322. Both ends of the electrical connection part 33 are electrically connected to diagonal ends (not shown) of the valve module 312 and the valve module 321, respectively, and the electrical connection part 33 is provided in the gap 35.

As shown in Figure 3, optionally, rigid conductive portion 331 is a rigid metal conductor. Optionally, the rigid conductive portion 331 may include a one-section straight bar-shaped structure (not shown).

As shown in Figure 3, optionally, converter valve 3000 may also include other types of flexible connections to connect between rigid conductor 331 and converter valve valve layer 32.

As shown in Figure 3, optionally, the electrical connection part 33 and the converter valve valve layer 31 may also include a flexible connection, which is directly electrically connected to the converter valve valve layer 32. As a further development, the electrical connection part 33 may also comprise a flexible connection at both ends.

As shown in Figure 3, optionally, the converter valve valve layer 31 and/or the converter valve valve layer 32 may also include three or more than three valve modules connected in series.

Optionally, converter valve 3000 may also include three or more converter valve layers connected in series. Furthermore, at least one pair of adjacent converter valve layers among the three or more than three converter valve layers is connected through an electrical connection part, and both ends of the electrical connection part are connected to the two adjacent converter valve layers, respectively. It is electrically connected to the diagonal end of the floor.

As shown in FIG. 3 , optionally, converter valve 3000 may include an insulator 34 . Among them, the insulator 34 is insulated and supported between the valve module 312 and the valve module 321.

Converter valve 3000 is one further refinement on the basis of converter valve 2000. On the basis of the beneficial effect of the converter valve 2000, since each converter valve valve layer includes two valve modules and also has an air gap between the valve modules, electrical connection parts are provided in the corresponding air gap. This design can further reduce the volume of the converter valve. In addition, the use of rigid direct connection for electrical connection parts can further reduce the distance between the valve layers of the converter valve and reduce the volume of the converter valve. Furthermore, providing a flexible connection at the end of a rigid directly connected electrical connection component can reduce installation difficulty and reduce stress caused by heating of the electrical connection component.

Figure 4 is a structural diagram of a converter valve according to another embodiment of the present application.

As shown in Figure 4, the converter valve 4000 includes a converter valve valve layer 41 (not shown) and a shielded contact terminal 421. Among them,

The converter valve valve layer 41 is the last level among at least two converter valve valve layers (not shown) connected in series.

The shield contact terminal 421 is electrically connected to the converter valve valve layer 41. The shield contact terminal 421 provides electromagnetic shielding for the converter valve 4000 and can also serve as a lead terminal of the converter valve valve layer 41.

As shown in Figure 4, optionally, the converter valve valve layer 41 may include a valve module 411, a valve module 412, and a connection component 413. Among them, the valve module 411 and the valve module 412 are connected in series through a connection part 413. Both ends of the connection part 413 are electrically connected to the low-voltage end 4112 of the valve module 411 and the high-voltage end of the valve module 4121, respectively. The high pressure end 4111 of the valve module 411 is also the lead-out end of the converter valve valve layer 41. The high voltage terminal 4111 is electrically connected to the shielded contact terminal 421.

As shown in FIG. 4 , optionally, converter valve 4000 may include an insulator 44 . The insulator 44 is insulated and supported between the shielded contact terminal 421 and the valve module 411.

As shown in FIG. 4 , optionally, the converter valve 4000 may also be provided on top of the valve module 412 including a grading ring 422 . Grading ring 422 provides electromagnetic shielding for converter valve 4000.

As shown in Figure 4, optionally, shielded contact terminal 421 and/or grading ring 422 are half rings.

As shown in Figure 4, optionally, the converter valve valve layer 41 may be provided on top of the at least two converter valve valve layers described above, and the shield contact terminal 421 and the grading ring 422 may be The converter valve may be provided on top of the valve layer 41. Optionally, the converter valve valve layer 41 may also be provided at the bottom of the at least two converter valve valve layers described above, and the shield contact terminal 421 and the grading ring 422 are provided at the converter valve valve layer 41. It may be provided at the bottom of.

Optionally, converter valve 4000 may include a lightning arrester 43. Both ends of the lightning arrester 43 are electrically connected to the shielded contact terminal 421 and the low voltage terminal 4122 of the valve module 412, respectively.

Through the above design, it is possible to simultaneously achieve the functions of electromagnetic shielding and lead-out by using a shielded contact terminal, save one component for the converter valve, and reduce the volume of the converter valve.

Figure 5 is a connection diagram of a converter valve according to another embodiment of the present application.

As shown in Figure 5, the converter valve 5000 includes a converter valve valve layer 511, a converter valve valve layer 512, an electrical connection part 52, and a lightning arrester 53. Among them,

The converter valve valve layer 511 and the converter valve valve layer 512 are connected in series through an electrical connection part 52. Both ends of the electrical connection part 52 are electrically connected to diagonal ends of the converter valve layer 511 and the converter valve layer 512, respectively.

The lightning arrester 53 is provided on one side of the converter valve 5000 and is connected in parallel with the converter valve valve layer 512.

Optionally, the lightning arrester 53 is in an open state under normal conditions, and quickly conducts and absorbs energy under an instantaneous overvoltage condition to protect the electronic device in the converter valve valve layer 512 from being damaged.

Optionally, converter valve 5000 may also include a lightning arrester 532 (not shown) connected in parallel with converter valve layer 511. Protects the electronic device in the converter valve valve layer 511.

Furthermore, the converter valve 5000 may also be connected in parallel with three or more converter valve layers, and three or more converter valve layers, including three or more arresters.

Figure 6 is a local structural diagram of a converter valve according to another embodiment of the present application.

As shown in Figure 6, the converter valve 6000 includes a converter valve valve layer 611, a converter valve valve layer 612, and a pressure-resistant insulator 631. Among them, the pressure-resistant insulator 631 is insulated and supported between the converter valve layer 611 and the converter valve layer 612.

As shown in FIG. 6 , converter valve 6000 may also include platform-type fittings 632 and 633 and delivery support structure 634. Among them, the platform-type fittings 632 and 633 are pressed and connected to both ends of the pressure-resistant insulator 631. The transmission support structure 634 is connected to the platform-type fitting 633 and is also connected to the converter valve valve layer 612.

Optionally, a hole structure (not shown) may be provided in the vertical direction of the transmission support structure 634, and may be connected to the converter valve valve layer 612 through a thread using the hole structure. Optionally, the corresponding hole structure is larger than the corresponding thread, and this feature can be used to adjust the horizontal relative position between the converter valve valve layer 612 and the pressure-resistant insulator 631 during installation, thereby allowing installation of the converter valve 6000. It is advantageous to

Optionally, the transmission support structure 634 may be a “工” shaped structure.

Optionally, a transfer support structure may also be included between the converter valve valve layer 611 and the platform fitting 632.

Optionally, the converter valve 6000 may include three or more converter valve layers and may also include a pressure-resistant insulator between two adjacent converter valve layers.

Through the converter valve, support installation of the converter valve can be implemented using a pressure-resistant insulator, a platform-type fitting, and a transmission support structure. Converter valve 6000 can be formed by adding a small number of components on the basis of converter valves 2000-5000.

Figure 7 is a local structural diagram of a converter valve according to another embodiment of the present application.

As shown in Figure 7, the converter valve 7000 includes a converter valve valve layer 711, a converter valve valve layer 712, and a tensile insulator 731. Among them, the tensile insulator 731 is insulated and stretched between the converter valve valve layer 711 and the converter valve valve layer 712.

Optionally, converter valve 7000 may also include ring-shaped fittings 732 and 733 and lugs 734 and 735. Among them,

Ring-shaped fittings 732 and 733 are pressed and connected to both ends of the tensile insulator 731. Ring-shaped fitting 732 includes a hole structure 7321, and ring-shaped fitting 733 also includes a hole structure 7331.

The lug 734 is fixed on the converter valve valve layer 711 and is also in combination with the hole structure 7321. It is fixed to the lug 735 and the converter valve valve layer 712, and is also connected to the hole structure 7331.

Optionally, converter valve 7000 may include three or more converter valve layers and may also include a tensioned insulator between every two adjacent converter valve layers.

Using the converter valve, suspension installation of the converter valve can be implemented through a tension-type insulator, ring-type fitting, and lug. Converter valve 7000 can be formed by adding a small number of components on the basis of converter valves 2000-5000.

Using the technical features of the converter valve 6000 and the converter valve 7000, on the basis of the converter valve 2000-5000, two installation methods can be considered: support installation and suspension installation using a small number of parts. .

Figure 8 shows a structural diagram of a converter valve in another embodiment of the present application.

As shown in Figure 8, the converter valve 8000 may include three converter valve layers 811, 812, and 813 (not shown) that are stacked. Among them, each converter valve valve layer consists of two series-connected valve modules. Specifically, the converter valve valve layer 811 is composed of valve modules 8111 and 8112, the converter valve valve layer 812 is composed of valve modules 8121 and 8122, and the converter valve valve layer 813 is composed of It consists of valve modules (8131 and 8132). The valve modules 8111, 8121, and 8131 are stacked, and the valve modules 8112, 8122, and 8132 are stacked.

As shown in Figure 8, adjacent converter valve valve layers may be electrically connected in series with electrical connection components in a diagonal manner. Specifically, the converter valve valve layers 811 and 812 may have electrical connection parts 821 connected in series in a diagonal manner, and the converter valve valve layers 812 and 813 may have electrical connection parts 822 in series in a diagonal manner. You can connect.

As shown in Figure 8, converter valve 8000 may also include a plurality of water hoses, such as water hoses 831, 832, 833 and 844 in the figure. The plurality of water hoses may be divided into an inlet pipe and an outlet pipe, and are connected to a cooling system (not shown) on each valve module. The inlet pipe inputs the cooling medium into the cooling system, and the outlet pipe discharges the cooling medium after heat exchange. At least one of the plurality of water hoses includes a plurality of S-curve structures or spiral structures.

As shown in Figure 8, the converter valve 8000 may also include a plurality of insulated pull rods, such as insulated pull rod 851 in Figure 8. Both ends of the insulating pull rod 851 are connected to the valve module 8132 and the water hose 834, respectively, so that the water hose 834 can be fixed. The end of the insulating pull rod 851 can be sheathed onto the water hose 834, including an insulating pull ring (not shown).

As shown in Figure 8, converter valve 8000 may also include a plurality of optical cables, such as optical cables 841, 842, 843 and 844 in Figure 8. The plurality of optical cables are each connected to a plurality of valve modules and transmit communication information. At least one of the plurality of optical cables includes a plurality of S-curve structures or spiral structures.

Figure 9 shows a structural diagram of a converter valve in another embodiment of the present application.

As shown in Figure 9, the converter valve 9000 includes a plurality of converter valve layers (e.g., 911, 912, 913 and 914 in Figure 9) and two frame layers, that is, an upper frame layer 921 and a bottom frame. It may include a layer 922. Each of the two adjacent layers can be connected using a plurality of insulators, for example, 971 in Figure 9.

The upper frame layer may include a shielded contact terminal 9211 and a grading ring 922.

In the bottom frame layer collecting board 961, a water leak detector 9611 may be provided on the collecting board 961.

As shown in Figure 9, the converter valve 9000 may also include a plurality of arresters, each of which may be connected in parallel with a plurality of converter valve layers. The plurality of lightning arresters are 931, 932, 933, and 934, respectively, as shown in FIG. 9. The plurality of lightning arresters may be insulated and supported through the insulator 972.

As shown in Figure 9, the converter valve 9000 may also include a plurality of spiral water hoses (eg, 941) and a plurality of spiral optical cables (eg, 951).

In the above embodiments, the techniques for each embodiment are all focused, and parts that are not described in detail in one embodiment may refer to related techniques in other embodiments. Each technical feature of the above embodiment can be combined in any arbitrary way. However, for the sake of brief explanation, all possible combinations of each technical feature in the above embodiment have not been described. However, if the combination of these technical features does not conflict, the present invention It would be said to fall within the scope.

In the above, the present application has been shown and described with respect to specific embodiments, but the present application is not limited to the above-described embodiments. Those of ordinary skill in the technical field to which this application pertains will be able to make various changes without departing from the gist of the technical idea of this application as set forth in the claims below. In summary, the contents of this specification should not be construed as limiting the present application.

Claims (16)

A converter valve comprising at least two converter valve valve layers and at least one electrical connection component,
Each valve layer of the at least two converter valve layers includes a first stage and a second stage diagonal from the first stage, and the at least two converter valve layers are stacked on each other; The adjacent converter valve layer of the at least two converter valve layers includes the at least one electrical connection component from a first end of one of the adjacent converter valve layers to a second end of the other of the adjacent converter valve layers. electrically connected in series diagonally through one of the
The converter valve valve layer further includes a pressure-resistant insulator insulated and supported between the two adjacent converter valve valve layers and a tension-type insulator insulated and pulled between the two adjacent converter valve valve layers, so that the converter valve A converter valve characterized in that it allows switching between a supported converter valve and a suspension type converter valve. According to paragraph 1,
A converter valve, characterized in that the at least two converter valve valve layers are parallel to each other. According to paragraph 1,
Converter valve, characterized in that the electrical connection part includes a rigid conductive part. According to clause 3,
A converter valve, characterized in that the rigid conduction part includes a rigid straight bar-shaped conduction part. According to clause 3,
A converter valve comprising at least one end of both ends of the electrical connection part a flexible connection part electrically connected to the rigid conductive part and electrically connected to one converter valve layer among at least two converter valve valve layers. . According to clause 5,
A converter valve, wherein the flexible connection portion has a flexible structure and includes a metal flexible bus bar electrically connected between the rigid conductive portion and the valve layer of the one converter valve. According to paragraph 1,
The at least two converter valve layers include a first converter valve layer and a second converter valve layer,
The first converter valve valve layer includes a first valve module and a second valve module; The second converter valve layer includes a third valve module and a fourth valve module;
The first valve module is stacked with the third valve module;
A converter valve, characterized in that the second valve module is stacked with the fourth valve module. In clause 7,
An air gap exists between the first and third valve modules that are stacked and the second and fourth valve modules that are stacked;
The converter valve, characterized in that the electrical connection part is electrically connected between the second valve module and the third valve module and is provided in the air gap. According to paragraph 1,
A converter valve comprising a shielded contact terminal adjacent to a last level converter valve layer among the at least two converter valve layers and electrically connected to the last level converter valve layer. According to clause 9,
A converter valve, characterized in that the shielded contact terminal has a half ring shape. According to paragraph 1,
A converter valve comprising at least two lightning arresters connected in parallel to the at least two converter valve valve layers. According to paragraph 1,
a platform-type fitting that is pressed and connected to both ends of the pressure-resistant insulator;
comprising a transmission support structure connected to the platform-type fitting;
The transmission support structure includes a first hole, and is connected to one converter valve layer of the adjacent converter valve layers using a stud bolt through the first hole, and the first hole is connected to the stud. A converter valve characterized by a larger cross section than the bolt. According to clause 12,
A converter valve, characterized in that the transmission support structure is a “工”-shaped transmission support structure. According to paragraph 1,
a ring-shaped fitting that is press-connected to both ends of the tensile insulator and includes a second hole;
A converter valve comprising a lug fixedly connected to one of the two adjacent converter valve layers and connected to the second hole.
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