KR100946210B1 - Overvoltage protection apparatus for overhead electric line - Google Patents

Abstract

The present invention makes it possible to protect the main body insulator and the overhead wire even when the overvoltage protection device of the overhead wire is damaged. The overvoltage protection device is fixed to the cross arm 11 and fixed to the main body insulator 3 through which the overhead wire 12 is fixed by the bind wire 4 and the fixing bracket 6 to the main body insulator 3. And a ring horn 30 fixed to the upper end of the lightning arrester 20 and surrounding the main body insulator 3. The distance A between the outer circumference of the main body insulator 3 and the outer circumference of the lightning arrester 20 is set to 50 mm or more. Therefore, even when the overvoltage protection device of the overhead wire 12 is damaged, the main body insulator 3 and the overhead wire 12 can be protected.

Description

Overvoltage Protection Device for Overhead Wires {OVERVOLTAGE PROTECTION APPARATUS FOR OVERHEAD ELECTRIC LINE}

The present invention relates to an overvoltage protection device for overhead wires.

As an overvoltage protection device for overhead wires, a lightning arrester is provided on the side of the insulator main body via a fixing bracket, and is spaced apart from the insulator main body at the upper end of the arrester, as disclosed in Japanese Utility Model Publication No. 60-075925. A ring horn is horizontally fixed to one side so as to extend to the side, and a branch electrode for discharge is mounted on the wire so as to correspond to the ring horn.

If the ring horn extends to the side in this manner, the ring horn occupies a space, and thus there is a problem that the ring horn is liable to be disturbed when working on the pole. Moreover, since it is necessary to attach a discharge branch electrode to a ring horn in a process wire, workability was not good. In addition, there is also a problem that alien matter (飛來 物) easily occurs in the ring horn.

Therefore, in order to solve such a problem, the structure disclosed in "JP-A-60-109220" is considered. In the overvoltage protection device of the overhead wire of the above publication, a lightning arrester is provided on the side of the insulator main body via a fixing bracket, and an arcuate ring horn is attached to the upper end of the arrester to surround the insulator main body. For this reason, the extension to the side piece of a ring horn is eliminated, it becomes small, and work on an electric pole becomes easy. In addition, since the ring horn is formed in an arc shape, it is possible to reliably capture the high voltage current discharged from the overhead wire at the time of lightning surge occurrence in the ring horn through the air gap (gas) between the overhead wire and the ring horn. For this reason, the discharge branch electrode becomes unnecessary, and at the same time, the work of attaching the discharge branch electrode so as to correspond to the ring horn is unnecessary.

However, in the case where the overvoltage protection device of the overhead wire is damaged, i.e., when the insulation resistance is lowered due to the damage of the surfaces of the main body insulator and the lightning arrester, the insulation wire is lower than the surface of the insulator, so the overhead wire There is a possibility that a branch current or a flashover may occur, in which a grid voltage which normally flows is induced from the insulator surface to the surface of the lightning arrestor. Therefore, since the fouling resistance of the surface of the insulator main body is lowered, there is a fear that breakage of the insulator main body or an accident of disconnection of the processed wire may occur.

Therefore, even in such a damaged case, a specific attachment form that can protect the main body insulator and the overhead wire is required.

The present invention has been made to solve the above problems, and an object thereof is to provide an apparatus form which can protect the main body insulator and the overhead wire even when the overvoltage protection device of the overhead wire is damaged.

Hereinafter, the means for achieving the above object and the effect thereof will be described.

The present invention provides an insulator fixed to a cross arm and at the same time an overhead wire is fixed by a bind wire, an arrester fixed to the insulator through an apparatus member, and fixed to an upper end of the arrester. An overvoltage protection device for overhead wires having a ring horn surrounding the insulator, wherein the distance between the outer circumference of the insulator and the outer circumference of the lightning arrester is set to 50 mm or more.

According to the above configuration, the overvoltage protection device does not cause an operation failure even when a 50kA lightning impulse current flows, which is the breakdown limit of the lightning protection device, so that the distance between the outer periphery of the insulator and the lightning protection device flows. Therefore, when the overvoltage protection device of the overhead wire is damaged, that is, when the insulation resistance decreases due to the surface damage of the insulator and the arrester, the high voltage current captured through the air gap in the ring horn is removed from the surface of the insulator. It is possible to surely flow to the current-limiting element in the lightning protection element without flowing through the air gap on the surface. Therefore, the insulator and the overhead wire can be protected even when the overvoltage protection device of the overhead wire is damaged.

The overvoltage protection device for overhead wires according to the present invention is characterized in that the interval between the outer circumference of the insulator and the outer circumference of the lightning protection element is set to 55 mm or more.

According to the above constitution, the clearance between the outer circumference of the insulator and the outer circumference of the lightning arrester is set to 55 mm or more. In this case, it is possible to more reliably flow the high-voltage current captured by the ring horn through the air gap from the surface of the lightning arrestor to the current-limiting element in the lightning arrester without passing through the air gap from the surface of the lightning arrestor. Therefore, even when the overvoltage protection device of the overhead wire is damaged, the insulator and the overhead wire can be more reliably protected.

In the overvoltage protection device of the overhead wire, the gap between the overhead wire and the ring horn, the outer circumference of the insulator and the inner circumference of the ring horn indicates the distance between the overhead wire and the ring horn along the X axis, and In the coordinate plane consisting of the X axis and the Y axis representing the distance between the outer circumference and the inner circumference of the ring horn along the Y axis, the distances between the points (105 mm, 30 mm), points (105 mm, 80 mm), points (120 mm, 65 mm), points ( 120mm, 15mm) is characterized in that the four points are set to fall within the range connected in a straight line.

According to the above configuration, in the coordinate plane in which the distance between the overhead wire and the ring horn is shown along the X axis, and the distance between the outer circumference of the insulator and the inner circumference of the ring horn along the Y axis, the points (105 mm, 30 mm) and the points (120 mm, 15 mm) The gap is set to a value on the straight line or a value exceeding the straight line as a boundary line. Therefore, when the overvoltage protection device of the overhead wire is damaged, that is, when the insulation resistance is lowered due to the surface damage of the insulator and the lightning protection device, it is possible to prevent the occurrence of the classification or the flashover of the system voltage which normally flows through the overhead wire. have. Moreover, in the said coordinate name surface, both space | intervals are set to the value on the said straight line or less than that as the boundary line with the straight line which connects the points 105mm and 80mm and the points 120mm and 65mm. Therefore, when the overvoltage protection device of the overhead wire is damaged, that is, when the insulation resistance decreases due to the surface damage of the insulator and the lightning arrester, the high voltage current discharged from the overhead wire at the time of lightning surge occurs in the air of the overhead wire and the ring horn. It is possible to reliably capture the ring horn through the interval, and the captured high voltage current can be reliably flowed to the current-limiting element in the lightning arrester without passing through the air gap from the surface of the lightning arrester to the surface of the main body insulator.

In addition, since the distance between the overhead wire and the ring horn is 120 mm or less, for example, the lightning surge of the pole without the overvoltage protection device is installed even if all the overvoltage protection devices are installed instead of all the poles. Flashover accidents can be prevented. In the event of a lightning surge, it is possible to prevent high voltage current from flowing between the overhead wire and the mounting side bracket connected to the front and rear of the suspension insulator installed next to the overvoltage protection device. In addition, since the distance between the overhead wire and the ring horn is 105 mm or more, the overvoltage protection device can be prevented from operating against abnormal overvoltage occurring in the overhead wire during the disturbance of the system.

In the overvoltage protection device for overhead wire according to the above, the gap between the overhead wire and the ring horn, the outer circumference of the insulator and the inner circumference of the ring horn indicates the distance between the overhead wire and the ring horn along the X axis, In the coordinate plane consisting of the X-axis and the Y-axis showing the distance between the outer circumference of the insulator and the inner circumference of the ring horn along the Y-axis, both intervals are points (105 mm, 40 mm), points (105 mm, 55 mm), points (120 mm, 55 mm). , Characterized in that the four points of the point (120mm, 40mm) is set to be included in the range connected in a straight line.

According to the above configuration, in the coordinate plane in which the distance between the overhead wire and the ring horn is shown along the X-ray and the distance between the outer circumference of the insulator and the inner circumference of the ring horn is along the Y axis, the points (105 mm, 40 mm) and the points (120 mm). , 40 mm) is set as a boundary line, and both intervals are set to a value on the straight line or a value exceeding the straight line. Therefore, when the overvoltage protection device of the overhead wire is damaged, that is, when the insulation resistance is lowered due to the surface damage of the insulator and the lightning protection device, it is possible to prevent the occurrence of the classification or the flashover of the system voltage which normally flows through the overhead wire. have.

Moreover, in the said coordinate name surface, both space | intervals are set to the value on the said straight line or less than that as the boundary line with the straight line which connects the points 105mm and 55mm and the points 120mm and 55mm. Therefore, when the overvoltage protection device of the overhead wire is damaged, that is, when the insulation resistance decreases due to the surface damage of the insulator and the lightning arrester, the high-voltage current discharged from the overhead wire at the time of lightning surge occurs in the air gap between the overhead wire and the ring horn. Through this, the ring horn can be reliably captured, and the captured high voltage can be surely flowed from the surface of the lightning arrester to the current-limiting element in the lightning arrester without passing through the air gap from the surface of the main body insulator.

In addition, since the distance between the overhead wire and the ring horn is 120 mm or less, for example, the lightning surge of the pole without the overvoltage protection device is installed even if all the overvoltage protection devices are installed instead of all the poles. Flashover accidents can be prevented. In the event of a lightning surge, it is possible to prevent high voltage current from flowing between the overhead wire and the mounting side bracket connected to the front and rear of the suspension insulator installed next to the overvoltage protection device. In addition, the overvoltage protection device can be prevented from operating against abnormal overvoltage generated in the overhead wire when the system is disturbed.

In the overvoltage protection device for overhead wire according to the present invention, the distance between the overhead wire and the ring horn is set to 110 mm, and at the same time, the distance between the outer circumference of the insulator and the inner circumference of the ring horn is set to 44 mm. .

According to the above configuration, the distance between the overhead wire and the ring horn was 110 mm, and the distance between the outer circumference of the insulator and the inner circumference of the ring horn was 44 mm. Therefore, when the overvoltage protection device of the overhead wire is damaged, that is, when the insulation resistance decreases due to the surface damage of the insulator and the lightning protection device, the high voltage current discharged from the overhead wire at the time of lightning surge occurs in the air of the overhead wire and the ring horn. Through the intervals, the ring horn can be captured most reliably, and the captured high voltage current can be surely flowed to the current-limiting element without flowing through the air gap from the surface of the lightning protection element to the surface of the main body insulator.

Further, for example, even if the overvoltage protection device is not all poles, and even one pole is installed, it is possible to prevent the flashover accident caused by the lightning surge of the pole without the overvoltage protection device. In the event of a lightning surge, it is possible to prevent the high voltage current from flowing between the overhead wire and the mounting side bracket connected to the front and rear of the suspension insulator installed next to the overvoltage protection device. In addition, the overvoltage protection device can be prevented from operating against the abnormal overvoltage generated in the overhead wire when the system is disturbed.

In the overvoltage protection device for overhead wire according to the present invention, the ring horn is composed of a device portion fixed to an upper end of the lightning arrester and a ring portion surrounding the insulator, the device portion extending horizontally from the base end, The ring portion is formed at the front end of the device portion, and the device portion is adjustable in position along the extending direction with respect to the upper end of the lightning arrester.

According to the above configuration, the position of the device of the ring horn can be accurately adjusted by positioning the device portion along the extension direction (length direction) of the upper end of the lightning arrester. That is, the distance between the outer circumference of the insulator and the inner circumference of the ring horn can be adjusted accurately.

In the overvoltage protection device for overhead wires according to the present invention, the ring horn is fixed to the upper end of the lightning arrester by a fastening member, and the fastening member regulates displacement of the ring horn at the time of tightening and tightens the fastening member. Allowing displacement of the ring horn at the time of release.

In the overvoltage protection device for overhead wires according to the present invention, the ring portion of the ring horn has an opening located on the side opposite to the device portion, and at the same time has a pair of hanging portions folded on the outside of the opening portion. And a connecting member for connecting the branch, wherein the connecting member is formed of a wire rod, and a gap between the end portion of the one ruled end portion to which the connection member is attached and the ring portion is narrower than the wire diameter of the connection member. It is characterized by being formed.

According to the said structure, since the space | interval of the edge part and the ring part of the one side to which the connection member was affixed between the two connection parts is formed narrower than the wire diameter of the connection member, the fall or loss of a connection member can be prevented.

In the overvoltage protection device for overhead wires according to the present invention, the device member includes a cross arm fixing part fixed to the cross arm, an arrester element fixing part to which the lightning arrester is fixed, the cross arm fixing part and the lightning protection The inclined inclined portion is formed by connecting the element fixing portion and the length of the cross arm fixing portion and the bent portion of the inclined portion is fixed to the cross arm of the device member. It is characterized in that the length that can be rotated every 45 degrees in one side in the left and right direction around the fixed part.

According to the above constitution, when a member such as a cross arm support bracket on which the overvoltage protection device of the overhead wire is installed is already installed, the device member can be rotated up to 45 degrees in either of the left and right directions, so that the It can be attached flexibly to existing members.

In the overvoltage protection device for overhead wire according to the present invention, the product specification display member is provided below the lightning protection device fixing part of the device member.

According to the above structure, since the display member of the product specification is provided below the lightning protection element fixing part of the apparatus member, the specification of the apparatus can be easily confirmed from the ground. If the display member of the product specification lists the rated voltage, the nominal discharge current, the manufacturer's name, the date of manufacture, and the like, it is possible to improve the maintenance, inspection, and switching of the apparatus.

In the overvoltage protection device for overhead wire according to the present invention, a bent portion is formed as a product specification identification portion at the tip of the fixed portion of the lightning arrester element of the device member.

According to the above configuration, since the bent portion is provided as the product specification identification portion at the upper end of the lightning protection element fixing portion of the device member, for example, the overvoltage protection device for general use is not provided with the bent portion, and only the overvoltage protection device for flame resistance is bent. By providing a part, it can identify that it is an overvoltage protection device for flameproofing.

In the over-voltage protection device for overhead wire according to the present invention, the product specification display member is characterized in that part is cut so as not to interfere with the bent portion of the arrester.

According to the above configuration, the rated voltage of the device, the nominal discharge current, the name of the manufacturer and the date of manufacture can be easily checked from the ground, and for example, the general overvoltage protection device does not have a bent portion, and the overvoltage protection device for flame resistance By providing only the bent portion and the display member of the product specification of the cut shape, it can be identified that the overvoltage protection device for flame resistance.

As described above, even when the overvoltage protection device of the overhead wire according to the present invention is damaged, the main body insulator and the overhead wire can be protected.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

(First embodiment)

Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. 1 to 3.

As shown in FIG. 1, the overhead wire 12 is supported by the wire support insulator 10 fixed to the upper part of the cross arm 11. As shown in FIG. The wire support insulator 10 includes a main body insulator 3 having a head portion 3a supporting the overhead wire 12, a base bracket 2 fixed to the lower part of the main body insulator 3, and a base bracket ( It is composed of a pin plaquette 1 fixed to the lower part of 2). The pin support 1 is inserted from the upper side into the hole (not shown) formed in the cross arm 11, and the wire support insulator 10 is tightened by tightening the plurality of nuts 7 from the lower side into the pin bracket 1. It is fixed to the cross arm 11. As shown in FIG. 2, a wire receiving groove 3b is formed in the head portion 3a of the main body insulator 3, and a processed wire 12 is disposed in the wire receiving groove 3b. The overhead wire 12 is fixed to the main body insulator 3 by (4). Here, the system voltage 22.9 kV is distributed to the overhead wire 12.

As shown in FIG. 1, the overvoltage protection device includes an lightning arrester 20 fixed to the pin bracket 1 of the wire support insulator 10 through a fixing bracket 6 as a device member, and the lightning arrester 20. Has a ring horn 30 fixed to the top of the. The lightning arrester 20 includes a ground electrode 21 and an overelectrode 22. Between the ground side electrode 21 and the overside electrode 22, a current-limiting element 23, which is a non-linear resistance element of ZnO (zinc oxide) system, is squeezed, and an insulating film 24 made of an insulating material having excellent elasticity on the outer circumference thereof. ) Is molded.

The fixing bracket 6 has a proximal end 6a as a cross fixing part fixed to the cross arm 11, a proximal end 6b as a lightening element fixing part to which the lightning protection element 20 is fixed, a proximal end 6a and a proximal end ( 6b) is bent and the inclined inclined part 6c is bent. As shown in FIG. 3, a hole 6d for inserting the pin bracket 1 is formed in the base end 6a of the fixing bracket 6, and the lightning arrester 20 is formed at the tip 6b of the fixing bracket 6. The hole 6e for inserting the ground-side electrode 21 of () is formed.

As shown in FIG. 1, the proximal end 6a of the fixing bracket 6 is connected by a plurality of nuts 7 to contact the cross arm 11 with respect to the pin bracket 1 of the wire support insulator 10. It is fixed. As shown in FIG. 5, the fixing bracket 6 is usually attached horizontally to protrude perpendicularly to the cross arm 11. However, when a cross arm support bracket or the like is already installed around the cross arm 11, the pin bracket 1, i.e., the hole 6d, is positioned at a predetermined angle θ (here, θ) in either of the left and right directions. The length E of the base end 6a of the fixing bracket 6 is determined so that it can be rotated and installed up to = 45 °). That is, the length E from the center of the hole 6d of the base end 6a to the bent portion is based on the width B of the fixing bracket 6 and the width C of the cross arm 11. It is calculated | required by Formula 1.

As shown in FIG. 1, the ground-side electrode 21 of the lightning arrester 20 is fixed to the tip portion 6b of the fixing bracket 6 by the nut 8 from the lower side, and the lightning arrester 20 The ring horn 30 is fixed to the over-electrode side 22. As shown in Fig. 4, between the distal end 6b of the fixing bracket 6 and the nut 8, a disk-shaped name plate 40 as a product specification display member is fixed by the nut 8. The outer diameter of the name plate 40 is larger than the outer diameter of the nut 8, and the stain portion extending radially from the outer diameter of the nut 8 includes a rated voltage, a nominal discharge current, a manufacturer's name, and a manufacturing date. Etc. are described.

As shown in FIG. 2, the ring horn 30 is formed of a conductive metal wire. The ring horn 30 is composed of a device portion 31 fixed to the over-electrode side 22 of the lightning arrester 20 and a ring portion 32 surrounding the main body insulator 3. The device part 31 of the ring horn 30 extends in parallel from the base end formed in U shape. The ring portion 32 of the ring horn 30 is formed in an annular shape by two circular arc portions connected to the tip of the device portion 31. The tip end of each circular arc portion of the ring portion 32 is folded outward to constitute the hanging portion 32a. The opening part 34 is formed by spaced apart from each other 32a. Both hanging portions 32a are connected by a ring-shaped connecting member 35 made of a metal wire. The space | interval d of the edge part of the rubbing part 32a of one side, and the ring part 32 is formed narrower than the wire diameter D of the connection member 35 among the rubbing parts 32a. The device portion 31 of the ring horn 30 is fixed to the over-electrode side 22 of the lightning arrester 20 by the fastening member 33. The tightening member 33 is formed with three restricting pieces 33a bent downward so as to face the base end of the ring horn 30 and both side surfaces of the device portion 31 of the ring horn 30. In the ring horn 30, when the tightening member 33 is loosened, displacement in the longitudinal direction (extension direction) of the device portion 31 is allowed, and the position of the ring horn 30 with respect to the main body insulator 3 can be adjusted. When the tightening member 33 is tightened, the displacement in the longitudinal direction (extension direction) is regulated, and the displacement to both sides of the apparatus 31 is also regulated and fixed to the lightning arrester 20.

Next, as shown in FIG. 1, the ring horn 30 is provided at intervals G with respect to the overhead wire 12. In addition, the inner circumference of the ring horn 30 and the outer circumference of the main body insulator 3 are provided at intervals W, and at the same time, the outer circumference of the main body insulator 3 and the outer circumference of the lightning arrester 20 are provided at intervals A. do.

The distance G between the overhead wire 12 and the ring horn 30, that is, the discharge gap G, and the distance W between the inner circumference of the ring horn 30 and the outer circumference of the main body insulator 3 are shown in FIG. Are set together. In FIG. 6, the X axis represents the distance G between the overhead wire 12 and the ring horn 30, and the Y axis represents the distance W between the inner circumference of the ring horn 30 and the outer circumference of the main body insulator 3. . FIG. 6 is a test result showing whether the system voltage is classified or flashed over without damaging the overvoltage protection device, and whether the system is normally operated and whether the ring horn 30 is captured through the air gap. . Here, the configuration of the overvoltage protection device is the same as that shown in FIG. 1, and the damage degree of the overvoltage protection device is 0.5 mg / cm ² . Here, the damage degree shows the equivalent salt adhesion density well-known to those skilled in the art, and shows the damage degree of the surface of an insulator by the salt contained in seawater.

In addition, the test is carried out with a commercial frequency voltage of 20 to 25 kV and a lightning impulse voltage corresponding to the occurrence of a lightning surge of 120 to 200 kV.

As shown in Fig. 6, the interval G between the overhead wire 12 and the ring horn 30, the outer circumference W of the main body insulator 3, and the inner circumference of the ring horn 30 are set as follows. . That is, the distance G between the overhead wire 12 and the ring horn 30 is shown along the X axis, and the distance W between the outer circumference of the main body insulator 3 and the inner circumference of the ring horn 30 is shown along the Y axis. In the coordinate plane of the axis and the Y axis, points (105 mm, 30 mm), points (105 mm, 80 mm), points (120 mm, 65 mm), and points (120 mm, 15 mm) indicated by the XY coordinates between the gaps G and W. It is set so that it may be contained in the range M which connected four points of with a straight line.

In the coordinate plane, if the distance G, W is a straight line connecting the points (105 mm, 30 mm) and the points (120 mm, 15 mm) as the boundary line, or the value exceeding the straight line, the overhead wire 12 When the overvoltage protection device is damaged, i.e., when the insulation resistance is lowered due to damage to the surfaces of the main body insulator 3 and the lightning arrester 20, the classification or flashing of the system voltage normally flowing through the overhead wire 12 Over can be prevented from occurring.

In the coordinate plane, if the distance G, W is a straight line connecting the points 105 mm, 80 mm and the points 120 mm, 65 mm, and is equal to or less than the value on the straight line, the processed wire ( High voltage discharged from the overhead wire 12 at the time of lightning surge occurs when the overvoltage protection device of 12) is damaged, that is, when the insulation resistance is lowered due to damage of the surfaces of the main body insulator 3 and the lightning arrester 20. The electric current can be reliably captured in the ring horn 30 through the air gap between the overhead wire 12 and the ring horn 30, and the captured high voltage is passed through the air gap from the surface of the lightning arrestor to the surface of the main body insulator. It can flow to the current-limiting element certainly without flowing.

In addition, when the distance between the overhead wire 12 and the ring horn 30 is 120 mm or less, even if the overvoltage protection devices are not all poles and are installed every other pole, lightning surges of the poles without the overvoltage protection device are installed. Flash over accidents can be prevented. In the event of a lightning surge, it is possible to prevent the high voltage current from flowing between the overhead wire and the mounting side bracket connected to the front and rear of the suspension insulator installed next to the overvoltage protection device. If the distance between the overhead wire 12 and the ring horn 30 is 105 mm or more, the overvoltage protection device can be prevented from operating against the abnormal overvoltage generated in the overhead wire 12 when the system is disturbed.

The gap G between the overhead wire 12 and the ring horn 30 and the inner circumference W of the body insulator 3 and the inner circumference of the ring horn 30 are the outer periphery of the main body insulator 3 and the ring horn 30. Space (W) in the inner circumference of) and four points of points (105mm, 40mm), points (105mm, 55mm), points (120mm, 55mm), points (120mm, 40mm) in the coordinate plane. It is more preferable if it is set to fall within the range N connected by the straight line. In addition, the gap G between the overhead wire 12 and the ring horn 30 is set to 110 mm, and the gap W between the outer circumference of the main body insulator 3 and the inner circumference of the ring horn 30 is set to 44 mm. desirable.

The interval A between the outer circumference of the main body insulator 3 and the outer circumference of the lightning arrester 20 is set as shown in FIG. 7.

Fig. 7 is a test of whether the overvoltage protection device operates normally with respect to the lightning impulse current when the distance A between the outer circumference of the main body insulator 3 and the outer circumference of the lightning arrester 20 is damaged when the overvoltage protection device is damaged. The result is. Here, the configuration of the overvoltage protection device is as shown in Figure 1, the damage degree of the overvoltage protection device is 0.5mg / cm ² . Moreover, the lightning impulse current with respect to the overhead wire 12 was tested as 1-50 kA. The distance A between the outer circumference of the main body insulator 3 and the outer circumference of the lightning arrester 20 is shown in FIG. 7 even if a lightning impulse current flows at 50 kA, which is the breakdown limit of the lightning arrester 20. 20 is set to 50 mm or more to operate normally. That is, the high voltage current discharged from the overhead wire 12 at the time of lightning surge is reliably captured by the ring horn 30 through the air gap between the overhead wire 12 and the ring horn 30, and then the captured high voltage current is captured. It is set to 50 mm or more so as not to flow through the air gap from the surface of the lightning arrester 20 to the surface of the main body insulator 3 through the air gap. Moreover, it is desirable to set it as 55 mm or more to have margin.

Next, the operation of the overvoltage protection device configured as described above will be described.

When an impact overvoltage is applied to the wire path by lightning surge, discharge is generated from the overhead wire 12 or the bind wire 4. In the case of insulated wires, the coating is accompanied with breakage. This discharge is captured by the ring portion 32 of the ring horn 30 via the air gap G from the overhead wire 12. The lightning surge captured by the ring horn 30 is discharged to the ground via the current-limiting element 23 through the ground-side electrode 21 and the cross arm 11 rather than the over-electrode 22 of the lightning arrester 20. When the shock overvoltage is applied to the current-limiting element 23, the current-limiting element 23 reduces the resistance value and passes the large current of the lightning surge due to the non-linearity of the voltage current characteristic provided with the element itself. Recovers its resistance, immediately limits and interrupts discharge of the follow current, and quickly restores insulation. For this reason, a rapid arc does not generate | occur | produce, and damage, such as a disconnection of a line and damage of an insulator, is reliably prevented.

As described above, according to the described embodiment, the following effects can be obtained.

(1) Even if the distance A between the outer circumference of the main body insulator 3 and the outer circumference of the lightning arrester 20 flows through a lightning impulse current of 50 kA, which is the destruction limit of the lightning arrester 20, the overvoltage protection device fails to operate. It was made into 50 mm or more so that it might not arise. For this reason, when the overvoltage protection device of the overhead wire 12 is damaged, that is, when the insulation resistance decreases due to the damage of the surfaces of the main body insulator 3 and the lightning protection element 20, the air flows into the ring horn 30. The high-voltage current captured through the intermediate intervals does not flow from the surface of the lightning arrester 20 to the surface of the main body insulator 3 through the air gap, and certainly flows to the current-limiting element 23 in the lightning arrester 20. Can be. Therefore, even when the overvoltage protection device of the overhead wire 12 is damaged, the main body insulator 3 and the overhead wire 12 can be protected.

(2) Even if a distance (A) of the outer circumference of the main body insulator 3 and the outer circumference of the lightning arrester 20 flows, a lightning impulse current of 50 kA, which is the destruction limit of the lightning arrester 20, does not cause the overvoltage protection device to malfunction. It was made to be 55 mm or more, to have a margin so that it might be allowed. Therefore, when the overvoltage protection device of the overhead wire 12 is damaged, that is, when the insulation resistance decreases due to the surface damage of the main body insulator 3 and the lightning protection device 20, the ring horn 30 is spaced in the air. The captured high voltage current is not allowed to flow from the surface of the lightning arrester 20 to the surface of the main body insulator 3 through the air gap, so that it can flow to the current-limiting element 23 in the lightning arrester 20 more reliably. Therefore, even when the overvoltage protection device of the overhead wire 12 is damaged, the main body insulator 3 and the overhead wire 12 can be protected more reliably.

(3) The distance G between the overhead wire 12 and the ring horn 30 is shown along the X axis, and the distance W between the outer circumference of the main body insulator 3 and the inner circumference of the ring horn 30 is shown along the Y axis. In the coordinate plane, a straight line connecting both the gaps G and W to the points 105 mm and 30 mm and the points 120 mm and 15 mm is set to the value on the straight line or a value exceeding that as a boundary line. Therefore, when the overvoltage protection device of the overhead wire 12 is damaged, that is, it is possible to prevent generation of a system voltage or a flashover that normally flows through the main body insulator 3 and the wire 12. Moreover, in the said coordinate plane, the straight line which connects both space | interval G and W to the point 105mm, 80mm and the point 120mm, 65mm is made into a linear value or less than a boundary line as a boundary line. Therefore, in the case where the overvoltage protection device of the overhead wire 12 is damaged, that is, when the insulation resistance is lowered due to the surface damage of the main body insulator 3 and the lightning protection element 20, the overhead wire 12 at the time of lightning surge occurs. Can be surely captured by the ring horn 30 through the air gap between the overhead wire 12 and the ring horn 30, and the captured high voltage can be captured on the surface of the lightning arrester 20. The surface of (3) does not flow through the air gap, and can flow to the current-limiting element 23 in the lightning arrester 20 reliably.

In addition, since the distance between the overhead wire 12 and the ring horn 30 is 120 mm or less, for example, the overvoltage protection devices are not all poles, and even if one pole is provided, the overvoltage protection device is not provided. It can prevent the flash over accident caused by the lightning surge of the last week. In the event of a lightning surge, it is possible to prevent the high voltage current from flowing between the overhead wire 12 connected to the front and rear of the suspension insulator provided next to the overvoltage protection device and the mounting side bracket.

Further, since the distance between the overhead wire 12 and the ring horn 30 is 105 mm or more, the overvoltage protection device can be prevented from operating against abnormal overvoltage generated in the overhead wire 12 during system disturbance.

(4) The distance G between the overhead wire 12 and the ring horn 30 is shown along the X axis, and the distance W between the outer circumference of the main body insulator 3 and the inner circumference of the ring horn 30 is shown along the Y axis. In the coordinate plane, a straight line connecting both the gaps G and W with the points 105 mm and 40 mm and the points 120 mm and 40 mm was set as a value above the straight line as a boundary line. Therefore, when the overvoltage protection device of the overhead wire 12 is damaged, that is, when the insulation resistance decreases due to the damage of the surfaces of the main body insulator 3 and the lightning protection element 20, the overhead wire 12 is normally flowing. It is possible to prevent the classification of the grid voltage and the occurrence of flashover.

Moreover, in the said coordinate plane, the straight line which connects both space | interval G and (W) with the point 105mm, 55mm and the point 120mm, 55mm was set to the value of the said straight line or less as a boundary line. . Therefore, when the overvoltage protection device of the overhead wire 12 is damaged, that is, when the insulation resistance is lowered due to the surface damage of the main body insulator 3 and the lightning arrester 20, the overhead wire 12 is generated at the time of lightning surge. It is possible to reliably capture the high voltage current discharged from the overhead wire 12 and the ring horn 30 through the air gap between the overhead wire 12 and the ring horn 30, and the captured high voltage current is captured on the surface of the lightning arrester 20 on the main body insulator ( It does not flow through the air gap on the surface of 3), and it can flow to the current-limiting element 23 in the lightning arrester 20 reliably.

In addition, since the distance G between the overhead wire 12 and the ring horn 30 is 120 mm or less, for example, the overvoltage protection devices are not all poles, and the overvoltage protection device is provided even when one pole is installed. Flashover accidents caused by lightning surges that are not installed can be prevented. In the event of a lightning surge, it is possible to prevent the high voltage current from flowing between the overhead wire 12 connected to the front and rear of the suspension insulator provided next to the overvoltage protection device and the mounting side bracket. In addition, the overvoltage protection device can be prevented from operating against the abnormal overvoltage generated in the overhead wire 12 when the system is disturbed.

(5) Since the distance G between the overhead wire 12 and the ring horn 30 was 110 mm, the interval W between the outer circumference of the main body insulator 3 and the inner circumference of the ring horn 30 was 44 mm. High voltage discharged from the overhead wire 12 at the time of lightning surge, in the case where the overvoltage protection device of the c) is damaged, that is, when the insulation resistance is lowered due to the damage of the surface of the main body insulator 3 and the lightning protection element 20. The electric current can be most reliably captured by the ring horn 30 through the air gap between the overhead wire 12 and the ring horn 30, and the captured high voltage current is removed from the surface of the lightning arrester 20 by the body insulator 3. It does not flow through the air gap on the surface, and can flow to the current-limiting element 20 reliably.

In addition, even if the overvoltage protection devices are not all poles, for example, even if every pole is installed one by one, it is possible to prevent the flashover accident caused by the lightning surge of the poles without the overvoltage protection device. In the event of a lightning surge, it is possible to prevent the high voltage current from flowing between the overhead wire 12 connected to the front and rear of the suspension insulator provided next to the overvoltage protection device and the mounting side bracket. In addition, the overvoltage protection device can be prevented from operating against the abnormal overvoltage generated in the overhead wire 12 when the system is disturbed.

(6) At the upper end of the lightning arrester 20, by positioning the device 31 of the ring horn 30 along its longitudinal direction (extension direction), the device position of the ring horn 30 can be precisely adjusted. have. That is, the interval W of the outer circumference of the main body insulator 3 and the inner circumference of the ring horn 30 can be accurately adjusted.

(7) The position adjustment of the ring horn 30 is possible by allowing the displacement along the longitudinal direction (extension direction) of the ring horn 30 by the fastening member 33.

In addition, since the three restraining pieces 33a are bent on the lower side of the tightening member 33, when the tightening member 33 is tightened, the displacement along the longitudinal direction can be restricted, and the device portion ( The displacement in both lateral directions can also be regulated.

(8) Since the opening 34 is provided in the ring portion 32 of the ring horn 30, the main body insulator 3 can be opened by widening the opening 34 even when the overhead wire 12 is fixed to the wire support insulator 10. It can pass through, and the ring part 32 can be arrange | positioned around the main body insulator 3.

(9) Since the connecting member 35 can be attached to and detached from the tip of the ring portion 32 of the ring horn 30, the opening 34 can be opened and closed. In addition, the outer diameter of the changed ring portion 32 can be maintained by using the connecting member 35 along the gap of the opening 34.

(10) The distance d between the outer end of the hanging portion 32a on which the connecting member 35 is installed and the ring portion 32 of both hanging portions 32a is smaller than the diameter D of the connecting member 35. Since it is narrowly formed, the fall or the loss of the connection member 35 can be prevented.

(11) When a cross arm support bracket or the like is already installed around the cross arm 11 on which the overvoltage protection device of the processed wire 12 is installed, the fixing bracket 6 is turned 45 degrees in either of the right and left directions. Since it can turn to install, a device can be installed with respect to an existing member flexibly.

(12) Since the name plate 40 is provided below the tip 6b of the fixing bracket 6, the specification of the device can be easily confirmed from the ground (from the bottom of FIG. 1). Therefore, if the rating plate, the nominal discharge current, the manufacturer's name, the production date, and the like are written on the name plate 40, the maintenance, inspection and switching of the apparatus can be made more efficient.

(Second embodiment)

Hereinafter, a second embodiment of the present invention will be described with reference to FIGS. 8 and 9. The overvoltage protection device for the overhead wire of this embodiment differs from the first embodiment in that the main body insulator is a flameproof insulator and the end of the fixing bracket is bent. Hereinafter, a description will be given focusing on differences from the first embodiment. In addition, the overvoltage protection device of the overhead wire of this embodiment has a structure substantially the same as the overvoltage protection device of the overhead wire of 1st Example shown in FIG.

As shown in FIG. 8, the overhead wire 12 is supported by the wire support insulator 110 fixed to the upper part of the cross arm 11. As shown in FIG. The wire support insulator 110 includes a main body insulator 103 having a head portion 3a supporting the overhead wire 12, a base bracket 102 fixed to the lower part of the main body insulator 103, and a base bracket ( It is comprised by the pin bracket 101 which adheres to the lower part of 102. The overvoltage protection device includes an arrester 20 fixed to the pin bracket 101 of the wire support insulator 110 through a fixing bracket 106 as a device member, and a ring horn 30 fixed to an upper end of the arrester 20. ).

The fixing bracket 106 includes a proximal end 106a serving as a cross arm fixing unit secured to the cross arm 11, a distal end 106b serving as a lightning arrester fixing unit to which the lightning arrester 20 is fixed, and a proximal end 106a. The inclined portion 106c is bent while being connected to the tip portion 106b. At the tip of the tip portion 106b of the fixing bracket 106, a bent portion 109 is formed so that the overvoltage protection device can be identified from the ground (from the bottom in FIG. 8) for flame resistance.

As shown in Fig. 9, between the distal end portion 106b of the fixing bracket 106 and the nut 8, a name plate 140 as a product specification display member is fixed by the nut 8. The name plate 140 is a shape in which the notch 140a is formed in a part of the disk so as not to interfere with the bent portion 109. The outer diameter of the name plate 140 is larger than the outer diameter of the nut 8, and the rated portion, the nominal discharge current, the manufacturer's name, the manufacturing date, and the like are described in the stain portion extending in the radial direction from the outer diameter of the nut 8. have.

As described above, according to the described embodiment, the following effects can be achieved in addition to the effects of (1) to (12) of the first embodiment.

(13) Since the bent portion 109 as the product specification identification portion is provided at the tip of the tip portion 106b of the fixing bracket 106, the bending portion is not provided in the general overvoltage protection device, and is bent only in the flameproof overvoltage protection device. By providing the unit 109, it can be identified that the flame-resistant overvoltage protection device.

(14) Since the name plate 140 having a part cut out is provided, the rated voltage, the nominal discharge current, the manufacturer's name, the manufacturing date, etc. of the apparatus can be easily checked from the ground (from the bottom of FIG. 8). At the same time, it can be identified as a flameproof overvoltage protection device. Moreover, by providing it with the bend part 109, it is easy to identify that it is a flameproof overvoltage protection device.

In addition, the said Example can be implemented with the following forms which changed this suitably.

In the above configuration, the main body insulator 3 is not limited to magnetic materials, and synthetic resins can be employed.

In the first embodiment, a hole 6d into which the pin bracket 1 is inserted is formed in the base end 6a of the fixing bracket 6. However, as shown in FIG. 10, the recessed part 206d may be formed in the base end part 206a of the fixing bracket 206, and the pin bracket 1 can be inserted from the side piece. In addition, the fixing bracket 206 is formed by bending the inclined portion 206c at the same time as connecting the tip portion 206b as the lightning arrester fixing portion, the base portion 206a and the tip portion 206b. A hole 206e is formed in the tip portion 206b of the fixing bracket 206 as in the above embodiment. According to this configuration, even if the wire support insulator 10 is already installed on the cross arm 11 via the pin bracket 1, the arrester 20 and the ring horn 30 are provided through the fixing bracket 206. Can be installed and easy to install.

Further, the hole 106d of the base end portion 106a of the fixing bracket 106 of the second embodiment may be formed by the recessed portion 206d shown in FIG.

In the second embodiment, the bent portion 109 is provided in the flameproof overvoltage protection device, but the bent portion may be provided in the general overvoltage protection device and the bent portion may not be provided in the flameproof overvoltage protection device. In this way, the general overvoltage protection device and the flameproof overvoltage protection device can be identified as in the second embodiment.

In the second embodiment, the cutout portion 140a is formed in a circular portion of the name plate 140. However, the cutout portion 140a is not limited to this shape and may be cut out like a gear. In addition, the name plate may be colored.

In the above configuration, a spacer may be arranged between the base brackets 2 and 102 and the fixing brackets 6 and 106. According to this structure, the space | interval between the base end part 6a of the fixed bracket 6 and the base bracket 2 can be easily adjusted by changing the number of spacers. In addition, the distance between the overhead wire 12 and the ring horn 30, that is, the discharge gap (G) can be easily adjusted. Moreover, you may form a recessed part in the spacer so that it may be attached to the pin bracket 1 from a side piece.

1 is a side view of an overvoltage protection device.

2 is a plan view of the overvoltage protection device.

3 is a plan view of the fixing bracket.

4 is a bottom view of the overvoltage protection device.

It is a figure which shows the movable form of a fixing bracket.

Fig. 6 shows the test results of the overvoltage protection device in case of damage.

7 is a diagram showing a test result of an overvoltage protection device in case of damage.

8 is a side view of the overvoltage protection device.

9 is a bottom view of the overvoltage protection device.

10 is a plan view of the fixing bracket.

(Explanation of the sign)

1: pin bracket 2: base bracket 3: body insulator

3a: head portion 3b: wire receiving groove 4: bind wire

5: spacer 6: fixing bracket 6a: base end

6b: tip 6c: slope 6d, 6e: hole

7: nut 10: wire support insulator 11: cross arm

12: overhead wire 16: fixed bracket 16a: proximal end

16b: tip portion 16c: inclined portion 16d: recessed portion

16e: hole 20: lightning arrester 21: ground-side electrode

22: over-side electrode 23: current-limiting element 24: insulating film

30 ring horn 31 device portion 32 ring portion

32a: hanging portion 33: tightening member 34: opening

35: connecting member 40: name plate 101: pin bracket

102: base bracket 103: main body insulator 106: fixing bracket

106a: proximal end 106b: distal end 106c: inclined part

106d, 106e: Hole 109: Bend 110: Wire support insulator

140: Nameplate 140a: Notch 206: Fixed bracket

206a: base end 206b: tip end 206c: inclined part

206d: recess 206e: hole A: gap

B, C: Width D: Diameter d: Thickness

E: length G: discharge gap M, N: range

W: thickness

Claims (12)

An insulator fixed to a cross arm and at the same time an overhead wire is fixed by a bind wire, an arrester fixed to the insulator through a device member, and fixed to an upper end of the arrester; An overvoltage protection device for overhead wires having a ring horn surrounding the The outer circumference of the insulator and the outer circumference of the lightning arrester are set in a range of 50 mm to 55 mm, The distance between the overhead wire and the ring horn, the outer circumference of the insulator and the inner circumference of the ring horn indicates the distance between the overhead wire and the ring horn along the X axis, and the interval between the outer circumference of the insulator and the inner circumference of the ring horn. In the coordinate plane consisting of the X-axis and the Y-axis along the Y-axis, the distance between two points is a straight line of four points (105 mm, 30 mm), points (105 mm, 80 mm), points (120 mm, 65 mm) and points (120 mm, 15 mm). Overvoltage protection device for overhead wires, characterized in that it is set within the range connected. The distance between the overhead wire and the ring horn, the outer circumference of the insulator and the inner circumference of the ring horn indicates the distance between the overhead wire and the ring horn along the X axis, and the outer circumference of the insulator and the In the coordinate plane consisting of the X-axis and the Y-axis showing the intervals of the inner circumference of the ring horn along the Y-axis, the distances between the points (105mm, 40mm), points (105mm, 55mm), points (120mm, 55mm), points (120mm, 40mm) Overvoltage protection device for overhead wires, characterized in that it is set to fall within the range of connecting the four points of the straight line. 3. The overvoltage protection device for overhead wire according to claim 2, wherein the distance between the overhead wire and the ring horn is set to 110 mm, and at the same time the interval between the outer circumference of the insulator and the inner circumference of the ring horn is set to 44 mm. 4. The ring horn according to claim 3, wherein the ring horn comprises a device portion fixed to an upper end of the lightning arrester and a ring portion surrounding the insulator, and the device portion extends horizontally from the base end, and the ring portion at the tip of the device portion. It is formed, with respect to the upper end of the lightning protection element over-voltage protection device of the overhead line, characterized in that the position adjustable in the extending direction. 5. The ring horn according to claim 4, wherein the ring horn is fixed to an upper end of the lightning arrester by a tightening member, and the tightening member regulates displacement of the ring horn at the time of tightening, and at the time of release of the tightening. Overvoltage protection device for overhead wire, characterized in that to allow displacement. The ring portion of the ring horn has an opening positioned on the side opposite to the device portion, and at the same time has a pair of ruled portions folded on the outside of the opening, and has a connecting member for connecting both ruled portions. The connecting member may be formed of a wire rod, and a gap between an end portion of the pair of hanging portions to which the connecting member is attached and the ring portion may be narrower than the wire diameter of the connecting member. Overvoltage Protection. 7. The apparatus of claim 6, wherein the device member comprises: a cross arm fixing portion fixed to the cross arm, a lightning protection element fixing portion to which the lightning protection element is fixed, and the cross arm fixing portion and the lightning protection element fixing portion; At the same time, the inclined inclined portion is formed by bending, and the length from the portion fixed to the cross arm of the apparatus member to the bent portion of the cross arm fixing portion and the inclined portion is centered on the portion of the apparatus member fixed to the cross arm. An overvoltage protection device for overhead wires, characterized by a length that can be turned every 45 degrees in one direction. 8. The overvoltage protection device for a overhead wire according to claim 7, wherein a product specification display member is provided under the lightning arrester fixing portion of the device member. 9. The overvoltage protection device for overhead wire according to claim 8, wherein a bent portion is formed as a product specification identification portion at the tip of the lightning protection element fixing portion of the device member. 10. The overvoltage protection device of claim 9, wherein the product specification display member is partially cut so as not to interfere with the bent portion of the arrester. delete delete

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