KR101522967B1 - Lightning arrester - Google Patents

Abstract

An object of the present invention is to provide a lightning arrester capable of reducing the installation area even when the number of device columns to be electrically connected in parallel increases.

When a plurality of element pillars made of a nonlinear resistor are disposed in a hermetically sealed container and each of the element pillars is constituted by an electric connection between the upper plate-shaped conductor and the ground-side plate-like conductor electrically connected in parallel, And an odd-numbered (grounded) conductor 5 is electrically connected between the plate-shaped conductor 5 and the ground-side plate-shaped conductor 6 by electrically connecting the plate-shaped conductor 5 and the donor- The middle plate-shaped conductor 15a and the even-numbered middle plate-shaped conductor 15b are electrically connected to each other by the donor-shaped interlayer connecting conductors 11a and 11b, . A plurality of element pillars (18a to 21a, 18b to 21b, ...) are disposed at the respective ends between the ground-side plate-shaped conductor (6), each of the intermediate plate-shaped conductors and the upper plate-shaped conductor. Between the grounding-side plate-like conductor 5 and the odd-numbered intermediate plate-shaped conductor 15a from the ground side and between the ground-side plate-like conductor 6 and the even-numbered intermediate plate- The electrical connection is made by the interconnection conductors 11a and 11b placed in non-contact portions formed in the respective intermediate plate-shaped conductors.

Description

Lightning Arrester {LIGHTNING ARRESTER}

The present invention relates to a lightning arrester in which a plurality of element columns made of a plurality of nonlinear resistors are electrically connected in parallel.

In a lightning arrester that protects a low-voltage, large-capacity power device from an overvoltage, a nonlinear resistor, which is a zinc oxide element, is laminated by a small number in the direction of pressure resistance to constitute a column of elements, And the device pillars are electrically connected in parallel by juxtaposing between the plate-shaped conductors.

For example, a conventional arrester, 9 and is in a hermetically sealed container (1) for sealing the insulating medium such as SF ₆ gas, as shown in Figure 10, a pair of overcurrent side plate-shaped conductor 5 and the ground-side A total of 52 pieces of the device columns 18 constituted by stacking two nonlinear resistors are arranged between the plate-shaped conductors 6, for example.

The ground-side plate-shaped conductor 6 establishes a plurality of insulating rods 8 fixed to the sealed container 1 via the insulating strip 7. A center through hole of a donut-shaped nonlinear resistor is inserted into each of these insulating rods 8 and then a head thread of each insulating rod 8 is formed in a corresponding portion of the overlying plate- And the nut 9 is threadedly engaged with the head screw portion of each insulating rod 8 so that the upper plate-shaped conductor 5 is electrically insulated from the ground-side plate-like conductor 6 .

A spring 14 is disposed between the upper surface of each element column 18 and the upper plate-shaped conductor 5 and a spring 14 is disposed between each non-linear resistor of each element column 18 in the stacking direction Of the contact pressure. The over-current side plate-like conductor 5 and the ground-side plate-like conductor 6 are led out from the insulation via the insulation spacers 2a and 2b provided in the closed container 1, Terminal 4 as shown in Fig.

An insulating support 10 is disposed between the closed container 1 and the upper plate-shaped conductor 5 and the upper plate-shaped conductor 5 is held by the insulating container 10 in the closed container 1, As shown in Fig.

A conventional arrester disclosed in Japanese Patent Application Laid-Open No. 7-288168 (Patent Document 1), which is connected to each of the lines of each phase in a three-phase bridge circuit of a thyristor valve have. The lightning arrester comprises a lightning arrester unit in which a nonlinear resistor is disposed in a bushing provided with terminals at both ends and three lightning arrester units respectively connected between the respective phase lines are connected in the height direction , The arrangement of the lead wires connecting the terminals of each arrester unit is studied and three arrester units connected between the respective upper ends are integrally stacked

A conventional lightning arrester, which is connected between a primary winding and a secondary winding and a sealed container at a ground potential, is disclosed in, for example, Japanese Patent Application Laid-Open No. 11-111509 (Patent Document 2). The lightning arrester includes two lightning arrester units on the primary winding side or two lightning arrester units on the secondary winding side. Both terminals at both ends in the axial direction of the aerator pipe are connected to the winding sides of the other poles, and a common ground side conductor is led out in the axial middle portion of the aileron, and between this ground side conductor and the positive pole terminal, And the element columns of the linear resistor are disposed.

However, in the conventional lightning arrester shown in Figs. 9 and 10, as described above, a plurality of element columns are collectively arranged in one opposing portion of the over-plate-shaped conductor 5 and the ground- . Because of this, the sealed container 1 having a large floor area according to the number of element columns is disadvantageous in that the installation area of the power equipment connected with the lightning arrester becomes large.

In the lightning arrester disclosed in Patent Documents 1 and 2, a plurality of lightning arrester units are configured in common with a part thereof, thereby achieving miniaturization. However, neither of these cases has a structure in which one arrester unit does not consider the case where the number of parallel connection of element columns increases as shown in Figs. 9 and 10. Therefore, when the present invention is applied to a lightning arrester constructed in a hermetically sealed container, the floor area of the hermetically sealed container also becomes large, which increases the installation area.

An object of the present invention is to provide a lightning arrester capable of reducing the installation area even if the number of element columns connected electrically in parallel increases.

In order to achieve the above object, a plurality of element columns made of a non-linear resistor are disposed in a closed vessel, and each of the element columns is electrically connected in parallel between the upper plate-shaped conductor and the ground- Shaped conductor and electrically connecting the ground-side plate-like conductor to the ground-side plate-like conductor when the ground-side plate-like conductor is connected to the ground- A plurality of element pillars are disposed at respective ends between the ground-side plate-like conductor, the intermediate plate-shaped conductor, and the upper-plate-shaped conductor, Between the side plate-shaped conductor and the odd-numbered intermediate plate-shaped conductors from the ground side, and between the ground-side plate-shaped conductor and the ground side, Shaped conductor is formed by an interconnection conductor placed in a non-contact portion formed in the intermediate plate-shaped conductor.

Preferably, each of the intermediate plate-shaped conductors has substantially the same structure including a non-contact portion, the odd-numbered intermediate plate-shaped conductors from the ground side electrically connected to the upper plate-shaped conductor, and the ground- And the even-numbered intermediate plate-shaped conductors from the ground side electrically connected to the conductors are arranged so that the positions of the respective non-contact portions are different from each other.

Further, the present invention is characterized in that, in a closed container for enclosing an insulating medium, element columns formed by laminating nonlinear resistive elements on a plurality of insulating rods formed on an insulating plate are disposed, Wherein the grounding side plate-like conductor formed with through holes in order from the side of the insulation plate on each of the insulation rods when the lightning arrester is electrically connected in parallel with the plate-like conductor, and the through- A plurality of the intermediate plate-shaped conductors having the same structure and the plurality of intermediate plate-shaped conductors having the same structure, and the upper plate-shaped conductors are inserted and disposed, and from the ground side electrically connected to the upper plate- , The even-numbered intermediate plate-shaped conductors electrically connected to the ground-side plate-shaped conductors are arranged on the upper side of each of the non-contact portions And the element pillars to be inserted into the respective insulating rods are arranged at respective ends between the ground-side plate-shaped conductor, the intermediate plate-shaped conductor and the upper-plate-shaped conductor, The electrical connection between the plate-shaped conductor and the grounded-side plate-like conductor and the odd-numbered plate-shaped conductor from the ground side and between the ground-side plate-shaped conductor and the grounded- And an interconnection conductor which is placed in a portion of the terminal.

Since the lightning arrester according to the present invention is constituted by disposing the element columns between the opposing portions composed of multiple stages by the intermediate plate-shaped conductor, the upper plate-shaped conductor and the ground-side plate-like conductor, The number of stages can be easily increased or decreased according to the size of the plate-like conductor and the ground-side plate-shaped conductor and the number of the element columns, so that the floor area of the closed container can be reduced and the installation area can be reduced. Further, since the plate-shaped conductors arranged at one pitch are electrically connected by the interconnection conductor disposed in the non-contact portion formed in the intermediate plate-shaped conductor, the bottom surface area of the closed container The installation area can be reduced.

In the lightning arrester of the present invention, the intermediate plate-shaped conductor electrically connected to the upper plate-shaped conductor and the intermediate plate-shaped conductor electrically connected to the ground-side plate-shaped conductor are arranged with different positions of the respective non-contact portions Therefore, all of the intermediate plate-shaped conductors can be formed to have substantially the same structure including the non-contact portion, and only by changing the installation angle, it is possible to cope with a large number of constituent elements, have.

(Example 1)

Hereinafter, the lightning arrester of the present invention will be described with reference to the drawings. 1 is a schematic vertical cross-sectional view of a lightning arrester of an embodiment of the present invention. The sealed container 1 in which the insulating medium such as the SF ₆ gas is sealed is provided with the overcharged terminal 3 and the grounded terminal 4 which are insulated from each other by using the central conductors of the insulating spacers 2a and 2b, ). The over-current side plate-like conductor 5 is electrically connected to the over-current side terminal 3, and the ground-side plate-like conductor 6 is electrically connected to the over-current side terminal 4.

A plurality of element pillars, which are electrically connected in parallel, are arranged between the upper-side plate-like conductor 5 and the ground-side plate-like conductor 6 arranged in the closed container 1 in opposition to each other. Here, each of the device columns has the same structure, and two donut-shaped nonlinear resistors having through-holes at the center are stacked to constitute one device column.

The above-mentioned over-current side plate-like conductor 5 and the ground-side plate-like conductor 6 have substantially the same shape, and the ground-side plate-like conductor 6 is connected via a plurality of insulating strips 7 And are fixed to the bottom of the hermetically sealed container 1 in a state of being electrically insulated from the hermetically sealed container 1 and the insulating rods 8a to 8f are respectively fixed to the respective insulating ribs 7. [

2, the upper end portions of the insulating rods 8a to 8f are used, and at the same time, the upper end portion of each of the insulating rods 8a- And is supported and fixed in a state of being electrically insulated from the closed container 1 by an insulating support 10 or the like fixed to the upper part of the housing.

Six through-holes are formed in the over-current-side plate-like conductor 5 at substantially equal intervals in accordance with the shape thereof. The top ends of the six insulating rods 8a to 8f are connected to the through- Respectively. Each upper end of each of the insulating rods 8a to 8f is inserted into each of the through holes of the upper plate-shaped conductor 5 and then a nut (not shown) is inserted into each threaded portion formed at each upper end of each of the insulating rods 8a to 8f 9a to 9f are screwed and fixed to the upper plate-shaped conductor 5 in a screwed manner.

Shaped donut-shaped connection conductors 13a to 13f and a donor-type donut-shaped connection conductors 13a to 13f for supporting the donor-type donut-shaped connection conductors 13a to 13f in which through- (14a to 14f) disposed between the lower surface of the base plate (5) and the lower surface of the base plate (5).

Each of the springs 14a to 14f applies a contact pressure to a lamination member such as a column of elements supported by the insulating rods 8a to 8f through donut-shaped connecting conductors 13a to 13f for support, Shape conductive conductors 13a to 13f and the upper-side plate-shaped conductor 5, as shown in FIG.

The insulating rods 8a to 8d among the six insulating rods 8a to 8f are used for supporting element pillars made of a donut-shaped non-linear resistor as will be described later in detail, and the remaining insulating rods 8e and 8f Are used to support the donut-shaped inter-connection conductors 11a and 11b for electrical connection and the donut-shaped insulation 12a for electrical insulation, respectively.

In the lightning arrester shown in Fig. 1, twelve intermediate plate-shaped conductors 15a to 15m are arranged in a substantially parallel relationship in each element column disposed between the upper-side plate-like conductor 5 and the ground- . As will be described later in detail, the arrangement of the intermediate plate-shaped conductors 15a to 15m is such that the arrangement of the intermediate plate-shaped conductors 15a to 15m is an even-numbered intermediate plate shape having one pitch as viewed from the ground- The conductors 15b to 15m are electrically connected to the ground-side plate-shaped conductor 6 and the remaining odd-numbered intermediate plate-shaped conductors 15a to 15l are connected to the over- And is electrically connected.

As will be described in detail later, each of the intermediate plate-shaped conductors 15a to 15m has a non-contact portion and a non-contact portion, and also forms a counter support portion on both sides of the non-contact portion and the non- And four element columns made of two donut-shaped nonlinear resistors are arranged in this opposing support portion. Each of the intermediate plate shaped conductors 15a to 15m has two kinds of the same thickness, and one type thereof is first described with the intermediate plate shaped conductor 15a shown in Fig.

The first intermediate plate-shaped conductor 15a on the side of the ground-side plate-shaped conductor 6 has a through hole at a position corresponding to each of the through holes of the upper plate-shaped conductor 5 shown in Fig. 2 And is similar to the over-current-side plate-like conductor 5.

As shown in Fig. 3, the intermediate plate-shaped conductor 15a is provided with through holes 16a to 16d which are formed in the right and left opposite support portions and into which the respective insulating rods 8a to 8d are inserted and through holes 16b and 16d And the insulating rod 8e is formed by cutting out a portion located between the through holes 16a and 16c and a through hole 16e formed in the exclusive contact portion located between the through holes 16a and 16b and into which the insulating rod 8f is inserted, And has a substantially C-shaped configuration with a non-contact portion 16f to be disposed.

The size of the noncontact portion 16f of the intermediate plate shaped conductor 15a is determined by the size of the donut-shaped interconnection conductors 11a and 11b and the donut- Is selected so as to secure a necessary insulation distance between the outer periphery of the linear resistor and the intermediate plate-like conductor 15a.

Another type of each of the intermediate plate shaped conductors 15a to 15m will be described as the second intermediate plate shaped conductor 15b shown in Fig. The intermediate plate shaped conductor 15b is a shape in which the intermediate plate type conductor 15a shown in Fig. 3 is rotated 180 degrees on the same plane to change its direction.

The intermediate plate shaped conductor 15b is also formed in the right and left opposite support portions so as to be inserted into the through holes 17a to 17d through which the insulating rods 8a to 8d are inserted and between the through holes 17b and 17d And the insulating rod 8e is inserted into the non-contact portion 17e where the insulating rod 8f is disposed and the penetration holes 17a and 17c, And has a substantially C-shape with a through hole 17f.

The size of the noncontact portion 17e is determined by the size of the donut-shaped interconnection conductors 11a and 11b supported by the adjacent insulating rods 8a to 8f and the donut-shaped non- Between the outer periphery of the intermediate plate-shaped conductor 15a and the intermediate plate-shaped conductor 15b.

The twelve intermediate plate-shaped conductors 15a to 15m arranged in multiple stages between the upper-side plate-like conductor 5 and the ground-side plate-like conductor 6 are formed by the above-described two intermediate plate- And the intermediate plate shaped conductors 15b are arranged alternately.

The above-mentioned non-contact portions 16f and 17e are formed in the respective intermediate plate shaped conductors 15a to 15m. Therefore, when these are alternately stacked in multiple stages at predetermined intervals, the odd-numbered intermediate plate-like conductors 15a, ..., and 15l and the even-numbered intermediate plates 16b, The upper-side plate-shaped conductor 5 or the ground-side plate-shaped conductor 6 which are adjacent to each other between the mutual contact portions of the shape conductors 15b, ..., 15m and on both sides thereof in the up and down direction are opposed to each other.

The donut-shaped interconnection conductors 11a, 11b, ... are disposed using the contact-through portions of the intermediate plate-like conductors 15a to 15m. The even-numbered intermediate plate-shaped conductors 15b, ..., and 15m are electrically connected to the ground-side plate-shaped conductor 6 from the ground side by the interconnection conductors 11a, 11b, The odd-numbered intermediate plate-shaped conductors 15a, ..., and 15l can be electrically connected to the overheat-side plate-shaped conductor 5 all together. In this way, the portion of the upper-plate-shaped conductor 5 connected to the upper-side terminal 3, the portion of the ground-side plate-shaped conductor 6 connected to the ground-side terminal 4, (15a to 15m), 13 opposing portions are formed.

Fourteen element columns are arranged in multiple stages by using the above-mentioned 13 opposed portions, and as a whole, 52 element columns are formed in the same manner as in the conventional case, and the upper-side plate-shaped conductor 5 and the ground- And the conductors 6 are connected in parallel.

Next, the structure of each element column arranged along the axial direction of each of the insulating rods 8a to 8d will be described. 5 is a cross-sectional view taken along line A-A in Fig. 1, which is a plan view of the ground-side plate-like conductor 6 shown in Fig. Six insulating rods 8a to 8f are formed on the ground-side plate-shaped conductor 6 and four insulating pillars 8a to 8d are used to form the first- And the through holes are inserted and arranged.

However, the donut-shaped interconnection conductor 11a is disposed in the insulating rod 8e by inserting a through-hole formed in the central portion thereof, and the insulating rod 8f is provided with a donut- And a through hole formed in the through hole. The donut-shaped interconnection conductor 11a and the donut-shaped insulator 12a are formed to have the same shape and the same axial length as one element column, and a through hole for inserting the insulating rod is formed at the center thereof .

6 is a cross-sectional view taken along the line B-B in Fig. 1, which is a plan view of the intermediate plate-shaped conductor 15a. The intermediate plate shaped conductor 15a is mounted on the upper portion of the portion of Fig. 5 and the upper ends of the element columns 18a to 21a, which are inserted into the insulating rods 8a to 8d, And the second-stage element columns 18b to 21b are respectively supported on the upper surfaces of the opposing supporting portions of the intermediate plate-like conductor 15a.

The upper end portion of the donut-shaped insulating member 12a having the same height as that of the first-tier element pillars 18a to 21a is brought into contact with the lower surface of the intermediate plate-like conductor 15a at the support portion by the insulating rod 8f have. On the upper surface of the intermediate plate-like conductor 15a, a second-stage donut-shaped interconnection conductor 11b having the same configuration as the donut-shaped interconnection conductor 11a is supported.

On the other hand, in the insulating rod 8e, since the upper end portion of the donut-shaped interconnection conductor 11a shown in Fig. 5 is located in the non-contact portion 16f formed in the intermediate plate-shaped conductor 15a, And is electrically insulated from the first electrode 15a. A donut-shaped interconnection conductor 11lb of the second stage is supported on the upper end of the donut-shaped interconnection conductor 11a through a donut-shaped thin plate conductor of the same thickness as the intermediate plate-like conductor 15a .

The above-described donut-shaped interconnection conductors 11a and 11b can adopt various configurations. In the above-described structure, the donut-shaped interconnection conductor 11a and the donut-shaped interconnection conductor 11b are formed by the block having the same shape and the same axial length as one element column. A donut-shaped thin plate conductor having the same thickness as that of the intermediate plate-shaped conductor 15a is added between the donut-shaped interconnection conductor 11a and the donut-shaped interconnection conductor 11b to form the interconnection conductor 11a 1lb in the first embodiment.

However, the donut-shaped interconnection conductor 11a and the donut-shaped interconnection conductor 11b may be integrally formed so as to have the same axial length as the above-described configuration, Shaped thin plate conductors may be omitted. In addition, both end portions in the axial direction have end plates provided with through holes through which the insulating rods 8e are inserted, but the intermediate portions may be made hollow and lightweight. In either case, it is preferable to form the through hole into which the insulating rod 8e is inserted, and to support it squarely by the insulating rod 8e.

In this laminated state, the lower end face of the power supply contact portion of the interconnection conductor 11a is in contact with the donut-shaped insulation 12a shown in Fig. 5 and is electrically insulated from the ground-side plate-like conductor 6 have. On the other hand, the upper end face of the power supply contact portion of the interconnection conductor 11b electrically connected to the interconnection conductor 11a via the donut-shaped thin plate conductor is the same as the upper end face of the element columns 18b to 21b of the second- Height.

7 is a cross-sectional view taken along the line C-C in Fig. 1, which is a plan view of the intermediate plate-like conductor 15b. The intermediate plate-shaped conductor 15b is mounted on the upper portion of the portion of Fig. 6 and inserted into the insulating rods 8a to 8d so that the upper ends of the element posts 18b to 21b are connected to the opposed- As shown in Fig. The third-stage element pillars 18c to 21c are respectively supported on the upper surface of the opposing support portion of the intermediate plate-like conductor 15b.

In the insulating rod 8e, the upper end portion of the donut-shaped interconnection conductor 11b is in contact with the lower surface of the opposing support portion of the intermediate plate-like conductor 15b. Further, a donut-shaped interconnection conductor 11c of the third stage is supported on the upper surface of the opposing support portion of the intermediate plate-shaped conductor 15b.

Since the upper portion of the donut-shaped interconnection conductor 22b shown in Fig. 6 is located in the non-contact portion 17e formed in the intermediate plate-shaped conductor 15b in the portion of the insulating rod 8e, And is electrically insulated from the conductor 15b. A donut-shaped thin-film conductor of the same thickness as that of the intermediate plate-shaped conductor 15b is disposed on the upper end of the donut-shaped short-circuit-connecting conductor 22b, and a third- ).

These donut-shaped interconnection conductors 22b and 22c also have the same configuration as the donut-shaped interconnection conductors 11a and 11b. Therefore, the upper end portion of the donut-shaped interconnection conductor 22c is at the same height as the upper end of the third-stage element columns 18c to 21c.

Therefore, if the intermediate plate-like conductor 15c is disposed on the upper portion of the intermediate plate-shaped conductor 15b, the intermediate plate-shaped conductor 15a and the intermediate plate- And electrically connects the opposing supporting portions of the shape conductor 15c.

The other end portions of the other portions are formed by alternately stacking the intermediate plate-shaped conductor 15a shown in Fig. 6 and the intermediate plate-shaped conductor 15b shown in Fig. 7 in the same manner. The even-numbered arrangement corresponding to the intermediate-plate-shaped conductor 15b is an arrangement of the odd-numbered arrangement corresponding to the intermediate-plate-like conductor 15a, which is electrically connected to the ground- Is electrically connected to the over-current-side plate-like conductor 5.

In Fig. 1, among the two donut-shaped nonlinear resistors constituting the column of elements at each stage, a donut-shaped nonlinear resistor located on the side electrically connected to the ground-side plate-like conductor 6 The nonlinear resistor having the donut shape located on the side electrically connected to the upper plate-shaped conductor 5 by the symbol N is shown by the symbol P in the nonlinear resistor. As can be seen from the symbols N and P in these nonlinear resistors, the nonlinear resistors constituting the element columns are arranged in a stacked manner in pairs in pairs in the axial direction of the insulating rods 8a to 8d, NP, NP, ... ... ... ... , NP, NP, PN, ..., and so on. ... ... ... , NP, and PN are repeated with nonlinear resistors of adjacent device columns.

Here, in order to further clarify the relationship between the above-mentioned over-lay plate-shaped conductor 5, the ground-side plate-like conductor 6, each of the intermediate plate-shaped conductors 15a to 15c, . The drawing is a development view schematically showing only the main constituent members described above, and details of supporting structures of the insulating rods 8a to 8f and the like are omitted.

The four element pillars 18a to 21a constituting the first stage, the donut-shaped interconnection conductor 11a and the donut-shaped insulator 12a are respectively set on the upper surface of the ground-side plate- Position. The upper surface of the first intermediate plate-shaped conductor 15a disposed on the upper portion of the ground-side plate-like conductor 6 is provided with the second-stage element pillars 18b 21b are disposed.

A donut-shaped thin plate conductor 23a having the same thickness as that of the intermediate plate-like conductor 15a is interposed in the upper portion of the donut-shaped interconnection conductor 11a disposed at the first level, And a donut-shaped interconnection conductor 11b is disposed. Since the first intermediate plate shaped conductor 15a is provided with the noncontact portion 16f, the donut-shaped interconnection conductor 11a arranged by using the noncontact portion 16f, the donut-shaped thin plate conductor 23a and the donut-shaped interconnection conductor 11b are electrically insulated from the intermediate plate-shaped conductor 15a.

On the upper surface of the second intermediate plate-like conductor 15b disposed on the upper portion of the intermediate plate-shaped conductor 15a, the upper end of each of the element pillars 18c to 18d coaxially with the second- And the upper end surfaces of the element pillars 18b to 21b in the second stage are electrically in contact with the lower surface of the intermediate plate-shaped conductor 15b. The upper end surfaces of the interconnection conductors 11b for arranging the third-stage element columns 18c to 21c are brought into contact with the lower surface of the intermediate plate-shaped conductor 15b.

In this contact state, the ground-side plate-shaped conductor 6 and the intermediate plate-shaped conductor 15a, which are adjacent to each other in the vertical direction of the unidirectional direction of the intermediate plate-shaped conductor 15a by the noncontact portion 16f formed in the intermediate plate- And the opposing surfaces are formed between the communicating contact surfaces of the contact portions 15b. Side plate-like conductor 6 and the intermediate plate 11 are connected to each other by the donut-shaped interconnection conductor 11a, the donut-shaped thin-plate conductor 23a, and the donut-shaped interconnection conductor 11b, And the shape conductor 15b are electrically connected to form a coincident electric potential.

On the other hand, the upper portion of the donut-shaped interconnection conductor 22b disposed at the second stage as described above is located in the non-contact portion 17e formed in the second intermediate plate-shaped conductor 15b, (Not shown).

The donut-shaped interconnection conductor 22c disposed coaxially via the donut-shaped thin-plate conductor 23b on the upper end surface of the second interconnection conductor 22b is likewise interposed in the middle by the non- And is electrically insulated from the plate-like conductor 15b. Therefore, the intermediate plate-like conductor 15a and the intermediate plate-like conductor 15b do not coincide. On the upper surface of the intermediate plate-shaped conductor 15b, a third-stage donut-shaped interconnection conductor 11c is disposed coaxially with the second-stage donut-shaped interconnection conductor 11b.

When the third intermediate plate-shaped conductor 15c constructed in the same manner as the first intermediate plate-shaped conductor 15a is disposed on the intermediate plate-shaped conductor 15b, the intermediate plate-shaped conductor 15b and the intermediate plate- The shape conductor 15c is electrically insulated. However, the upper surface of the donut-shaped interconnection conductor 22c comes into contact with the lower surface of the intermediate plate-shaped conductor 15c, and the donut-shaped interconnection conductor 22b, the donut-shaped thin conductor 23b, The first intermediate plate-shaped conductor 15a and the third intermediate plate-shaped conductor 15c are electrically connected to each other by the interconnection conductor 22c.

In the state of Fig. 8, three intermediate plate-shaped conductors 15a to 15c are used, and the first intermediate plate-shaped conductor 15a and the third intermediate plate-shaped conductor 15c are on the same potential, The shape conductor 6 and the second intermediate plate-shaped conductor 15b are on the same potential. Therefore, when the third middle plate-shaped conductor 15c is electrically connected to the upper-plate-shaped conductor 5, the third-plate-shaped conductor 15 is provided between the upper-plate-shaped conductor 5 and the ground- The element columns of the structure are electrically connected in parallel. That is, in this state, twelve device columns are electrically connected in parallel between the upper plate-shaped conductor 5 and the ground-side plate-shaped conductor 6.

Like the case of the first-stage intermediate plate-shaped conductor 15a and the second intermediate plate-shaped conductor 15b, the two intermediate plate-shaped conductors are alternately arranged alternately and a plurality of intermediate plate-shaped conductors 15a To 15 m). Thereafter, when the upper-side plate-like conductor 5 is connected to the upper-side terminal 3 and the ground-side plate-like conductor 6 is connected to the ground-side terminal 4, the second intermediate plate- , The odd-numbered intermediate plate-shaped conductors represented by the first intermediate plate-shaped conductor 15a become the ground potential similarly to the ground-side plate-like conductor 6, and the odd- Like-shaped conductor 5 becomes an over-potential. Therefore, as in the conventional art, a total of 52 element columns are electrically connected in parallel between the overcharged side terminal 3 and the grounded side terminal 4.

As described above, by arranging the element columns and the intermediate plate-shaped conductors alternately in order above the ground-side plate-like conductor 6, it is possible to electrically connect the upper plate-shaped conductor 5 and the ground- Even when the number of element columns to be connected in parallel is large, element pillars can be easily increased in the axial direction of each of the insulating rods 8a to 8f with a floor area as large as represented by the ground side plate- Therefore, as compared with the conventional case where all the device columns are arranged at one end as in the conventional art, the lightning arrester can be constructed with a greatly reduced installation area.

Further, in order to electrically connect the plate-shaped conductors between the odd-numbered and even-numbered pitches of one pitch and raise the coin, for example, between the ground-side plate-shaped conductor 6 and the even- Are electrically connected. Therefore, the non-contact portion 16f formed on the odd-numbered intermediate plate-shaped conductor 15a located between the ground-side plate-shaped conductor 6 and the intermediate plate-shaped conductor 15b is used, Side plate-like conductor 6 and the intermediate plate-like conductor 15b adjacent to the unidirectional side of the intermediate plate-like conductor 15a. Since the donut-shaped interconnection conductors 11a and 11b are disposed between the opposing face portions, it is possible to prevent the protruding portions from being projected from the opposing projection regions of the over-planar-shaped conductor 5 and the ground- can do. Therefore, it is possible to reliably accommodate a plurality of stages of device columns in the sealed container 1 without complicating the configuration.

In the above-described configuration, the element posts, the donut-shaped interconnection conductors 11a to 11c, the donut-shaped interconnection conductors 22b and 22c, and the donut-shaped insulator 12a, Shaped structure. For this reason, it is apparent that only element columns are present between the upper-plate-side conductor 5, the ground-side plate-like conductor 6 and the intermediate-plate-like conductors 15a and 15b, and these plate- As a special structure does not exist, the structure can be simplified neatly.

However, in another example of the present invention, the outer shape of the donut-shaped interconnection conductors 11a to 11c and the donut-shaped interconnection conductors 22b and 22c can be arbitrarily determined according to the energizing capacity.

Even in this case, while using the non-contact portion 16f formed on the first intermediate plate-shaped conductor 15a located between the ground-side plate-shaped conductor 6 and the second intermediate plate-shaped conductor 15b, The non-contact portion 16f forms an opposing face portion as a contact portion for contact between the ground-side plate-like conductor 6 and the intermediate plate-shaped conductor 15b which are adjacent to each other in one direction. The donor-shaped interconnection conductors 11a to 11c and the donut-shaped interconnection conductors 22b and 22c are disposed between the opposing face portions so that the ground-side plate-like conductor 6 and the intermediate plate- 15b are electrically connected to each other.

In the embodiment shown in Fig. 1, a donut-shaped nonlinear resistor is laminated at the time of constituting the element column, and the insulating rods 8a to 8f inserted into the through holes formed at the central portion thereof are used. As a result, the supporting structure is covered in each element column, and the element column dispersedly stacked in multiple stages in the axial direction does not have a support structure apparently, and the structure of the lightning arrester can be simplified to make it neat have.

Further, by the supporting structure using the insulating rods 8a to 8f, it is possible to arrange each element column electrically in parallel at the same stage relatively close to each other. As a result, the plate-like conductors 5, 6, 15a to 15m can be made small, and the closed container 1 for accommodating the same parts can be made compact and the installation area can be reduced.

In the embodiment shown in Fig. 1, a donut-shaped insulating material 12a is disposed between the lowermost ground-side plate-like conductor 6 and the intermediate plate-shaped conductor 15a located above and adjacent to the ground- . The same donut-shaped insulating material is also provided between the uppermost over-plate-shaped conductor 5 and the intermediate plate-shaped conductor 15m located at the lower portion adjacent to the uppermost over-plate-shaped conductor 5, and electrically insulates them from each other.

If the intermediate plate-like conductor 15c shown in Fig. 8 is referred to as an upper-plate-side plate-like conductor 5 located at the uppermost position, And the plate-like conductor 11c is replaced with an insulator. When these donut-shaped insulators 12a and the like are positively installed, the structures of the axially supporting members in the insulating rods 8a to 8f are all substantially the same, and the load sharing becomes approximately equal.

 However, if the difference in load sharing does not affect the supporting structure, the donut-shaped insulating member 12a or the like may be omitted. In addition, although the number of the element columns at each end is the same, if the number of element columns is different for each end, a donut-shaped insulation 12a or the like may be substituted for element columns.

In another example of the present invention, it is also possible to use a non-linear resistor having no through hole at the central portion and a lightning arrester provided with a different supporting structure at the outer periphery thereof. In the above-described embodiment, the number of device columns arranged at each end in the stacking direction is four for each stage, but the present invention is not limited to this. For example, by disposing six device columns at each end, it is possible to reduce the number of stages in the stacking direction and to suppress the height of the closed container 1.

The upper plate-shaped conductor 5, the ground-side plate-shaped conductor 6, the intermediate plate-shaped conductor 15a, and the intermediate plate-shaped conductor 15b are not limited to the quadrangular or C- , And various shapes can be employed. For example, all of them may be formed into a disc shape, or may be formed into an L shape.

In this case, the non-contact portions 16f and 17e formed in the respective intermediate plate-like conductors 15a to 15m are formed by the cut-out portion, but the corresponding portions are formed by through-holes having the same size . Also, the position of formation thereof is not limited to the opposite side rotated 180 degrees on the same plane as in the non-contact portions 16f and 17e shown in Figs. 6 and 7, and is formed relatively close to each other. Two types of intermediate plate-like conductors 15a to 15m can be easily formed which have different non-contact portions.

However, in the case of the intermediate plate-like conductors 15a to 15m other than the disc shape, when they are formed on the side opposite to the non-contact portions 16f and 17e rotated by 180 degrees, one kind of shape is prepared, It is economical because two types of intermediate plate shaped conductors 15a to 15m can be used.

It is also possible to use a gas space in the closed vessel 1 existing in the upper portion of the over-current-side plate-like conductor 5 in Fig.

The lightning arrester according to the present invention is not limited to the structure shown in the drawing, but can be applied to lightning arresters having other structures for protecting electric devices of low voltage and large current.

1 is a schematic longitudinal sectional view showing a portion of a lightning arrester of an embodiment of the present invention,

FIG. 2 is a partial cross-sectional top view of the lightning arrester shown in FIG. 1,

Fig. 3 is a plan view showing one kind of intermediate plate-shaped conductor of the lightning arrester shown in Fig. 1,

Fig. 4 is a plan view showing another kind of intermediate plate-shaped conductor of the lightning arrester shown in Fig. 1,

5 is a sectional view taken along the line A-A in Fig. 1,

6 is a sectional view taken along the line B-B in Fig. 1,

7 is a sectional view taken along the line C-C in Fig. 1,

FIG. 8 is an exploded view schematically showing a main part of the lightning arrester shown in FIG. 1;

9 is a partial sectional top view of a conventional lightning arrester,

10 is a schematic longitudinal sectional view of the lightning arrester shown in Fig.

Claims (3)

A lightning arrestor in which a plurality of element columns made of a nonlinear resistor are disposed in a hermetically closed container and each of the element pillars is electrically connected in parallel between an overlying plate conductor and a grounding plate conductor, An intermediate plate-shaped conductor which is electrically connected to the upper plate-shaped conductor, and an intermediate plate-shaped conductor which is electrically connected to the ground-side plate-shaped conductor are alternately arranged between the upper- A plurality of element pillars are disposed at each end between the ground-side plate-shaped conductor, the intermediate plate-shaped conductor and the upper-plate-shaped conductor, and the upper-plate-shaped conductor and the ground- The electrical connection between the odd-numbered intermediate plate-shaped conductors and between the ground-side plate-like conductor and the grounded-side even-numbered intermediate plate- Wherein the lightning arrester comprises: The method according to claim 1, Wherein each of the intermediate plate-shaped conductors has the same structure including a non-contact portion, and the odd-numbered intermediate plate-shaped conductors are electrically connected to the ground-side plate-shaped conductors from the ground side electrically connected to the over- And the even-numbered intermediate plate-shaped conductors from one ground side are arranged with different positions of the respective non-contact portions. A device column comprising a nonlinear resistor laminated on a plurality of insulating rods formed on an insulating strip is disposed in a hermetically sealed container for enclosing an insulating medium, and the device column is disposed between the upper plate-shaped conductor and the ground- In the lightning arrester electrically connected in parallel, Side plate-like conductor formed with through holes in order from the side of the insulation plate on each of the insulation rods, a plurality of intermediate plate-shaped conductors having the same structure in which through holes and non-contact portions are formed, And a plurality of first conductors connected to the first and second conductors are electrically connected to the first plate-like conductor and the second plate-like conductor, Wherein the intermediate plate-shaped conductor is disposed so that the positions of the non-contact portions are different from each other, and the element column inserted into each of the insulating rods is disposed between the ground-side plate-like conductor and the intermediate plate- And between the upper plate-shaped conductor and the odd-numbered intermediate plate-shaped conductors from the ground side, and between the ground-side Wherein the electrical connection between the plate-shaped conductor and the even-numbered middle plate-shaped conductor is made by an interconnection conductor placed in a non-contact portion formed in the intermediate plate-shaped conductor.

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