US3651380A

US3651380A - Gas discharge over voltage arrester filled with a noble gas

Info

Publication number: US3651380A
Application number: US120638A
Authority: US
Inventors: Gerhard Peche; Werner Seiffarth
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 1970-03-16
Filing date: 1971-03-03
Publication date: 1972-03-21
Anticipated expiration: 1989-03-21
Also published as: DE2012453A1; JPS547936B1; AT306833B; DE2012453B2; CH526866A; GB1319709A; FR2084660A5

Abstract

A gas discharge over voltage arrester having a cylindrical electrode coaxially surrounded by a hollow tubular electrode which forms a part of a gas filled vacuum-tight housing. The cylindrical electrode carries an end cap which with the hollow electrode, an intermediate annular insulator and a pair of thin wall connecting portions forms the vacuum-tight housing. The arrester is constructed and arranged to withstand brief high loads and extended low loads, and is dimensioned materially and geometrically to provide optimum performance and to provide a short circuit very rapidly without rupture when overloaded by alternating and lightning loads.

Description

States atent Peche et al.

1451 Mar. 21, 1972 [54] GAS DISCHARGE OVER VOLTAGE ARRESTER FILLED WITH A NOBLE FOREIGN PATENTS OR APPLICATIONS 714,139 11/1941 Germany GAS {72] Inventors: Gerhard Peche; Werner Seiifarth, both of Pr'mary Emfnmer*james f Berlin, Germany Attorney-Hill, Sherman, Merom, Gross & Simpson [73] Assignee: Siemens Aktiengesellschaft, Berlin and [5 7] ABSTRACT Munich, Germany A gas discharge over voltage arrester havmg a cylindrical elec- Flledi Mal. 1971 trode coaxially surrounded by a hollow tubular electrode [21] APPL NM 120,638 which forms a part of a gas filled vacuum-tight housing. The cylindrical electrode carries an end cap which with the hollow electrode, an intermediate annular insulator and a pair of thin [30] Forelgn Apphcatlon Pnomy Data wall connecting portions forms the vacuum-tight housing. The Mar. 16, 1970 Germany ..1 20 12 453.2 arrest" is Constructed and arranged to withstand brief high loads and extended low loads, and is dimensioned materially 52 u.s.c1 ..317/62, 313 214 and geometrically to provide optimum performance and to [5 l Int. Cl. ..H02h 9/06 p o e a sho t ci cuit ery rapidly without rupture when [58] Field of Search ..317/62; 313/214, DIG. 5 overloaded by alternating and lightning loads.

[ 56] References Cited 5 Claims, 1 Drawing Figure UN lTED STATES PATENTS 2,427,086 9/1947 Arnott et al. ..3l3/2l4 d 1 5 V .4? a 5 [I 1 I l 1 l BACKGROUND OF THE INVENTION 1. Field of the Invention This invention relates to a gas discharge over voltage arrester with a vacuum-tight housing having preferably a noble gas filling, and more particularly to an arrester in which a solid cylindrical electrode carrying an end cap on one end thereof is coaxially surrounded by a hollow electrode in the form of a hollow cylinder having an end wall, the end cap and the hollow electrode and an annular insulatingbody being connected to form the vacuum-tight housing.

2. Description of the Prior Art 1 Voltage arresters of the type mentioned above are generally known in the art; see, for example, German Pat. No. 714,139, in which, however, unlike the present-day constructions, the hollow electrode does not form a part of the vacuum-tight housing. In addition to small dimensions and low acquisition costs, these over voltage arresters are supposed to have the following properties which in part contradict one another:

The over voltage arrester is to be able to lead off or drain atmospheric discharge of high current strength, i.e., bolts of lightning;

In such action it must tolerate current pulses of up to 20 sec.

duration and up to 100 ka. of current repeatedly;

Current strengths of lesser magnitude must also be led off, but over longer durations of time, for example, in the case where inductive influencing of telecommunication lines or contact of telecommunication lines with high current lines is concerned; and

In both types of load situations, brief loads of high current and extended loads of low current, it is required that the arrester respond extremely rapidly. Only if ignition takes place immediately upon the occurrence of the over voltage that the installation which is to be protected is effectively protected.

In addition to the short response time, fail-safe properties are required. This means that if the arrester, despite its capacity to bear both alternating current loads and lightening loads, is overloaded, it must bring about a certain short circuit. This function is fulfilled only if in the casing or housing of the device the electrodes fuse together before the arrester loosens or ruptures. The certainty of establishing a short circuit in response to an overload condition is extremely important in that the apparatus to be protected is in fact protected from penetration by an over voltage, although the apparatus may be temporarily inoperative. The cause or place of fault can then be easily identified and corresponding corrective action can be taken.

SUMMARY OF THE INVENTION All of the over voltage arresters heretofore known in the prior art fulfill some, but not all, of the above requirements. It is therefore the primary object of the present invention to remedy this situation.

In order to realize our improved voltage arrester of the above-mentioned type we propose that the cylindrical electrode consist of a first electrically conductive material (z) and has a diameter dimensioned in accordance with the expression DZ [0.625 ln 1+a,AT.

and that the coaxially disposed hollow electrode consist of a second electrically conductive material (k) with an inner diameter D at most 2d, equal to 2 mm., greater than the diameter D, of the cylindrical electrode, and an outside diameter D which is at most 15 mm. and dimensioned in accordance with the expression insulating body due to thermal effects.

with the principles of the invention.

where d is the spacing between the cylindrical electrode and v the hollow electrode, Q is a quotient of two products formed by, on the one hand, the temperature coefficients a( l/ C.) of the electrical resistance and the specific electrical resistance Gem.) of the particular electrode material and, on the other hand, by the mean specific heat c (Wsec./g. C.) and the specific weight 'y(g./cm.") of the particular electrode material, AT is the temperature difference between the operating temperature of a material and its melting temperature, l(A) is the maximum current, and t(s) is the mean time duration of the current flow.

In a gas filled voltage arrester according to the invention the cylindrical electrode and the hollow electrode would ordinarily be made of the same material. In this case the rule for dimensioning the hollow electrode with respect to the diameter D of the cylindrical electrode is simplified and expressed by the relation D (D,+2d) D If one proceeds assuming iron as a particularly advantageous electrode material and assumes that the maximum current strength of the most severe flashes of lightning does not exceed ka. and that the mean duration of this lightning does not exceed l0" seconds, the diameter of the cylindrical electrode according to this invention amounts to at least 3 mm.

The metal parts of the vacuum-tight housing of a gas filled voltage arrester, according to another feature of the invention, include wall portions which are thinner in the transition zone from each electrode to the intermediate annular insulating body than the wall thickness at other zones of the housing. This constructional feature provides between the electrodes, on the one hand, and the insulating body, on the other hand, a heat-conduction brake, which prevents the immediate transfer of heat to the insulating body upon the generation of heat at the electrodes during operation of the gas discharge excess voltage arrester. It is thereby assured with absolute certainty that, upon the occurrence of an overload condition, the cylindrical electrode will fuse first, before the gas discharge over voltage arrester could possibly loosen through cracking of the BRIEF DESCRIPTION OF THE "wwflfi Other objects, features and advantages of the invention, its organization, construction and operation, will be better understood from the following detailed description of an exemplary embodiment thereof, taken in conjunction with the accompanying drawing which carries a single FIGURE thereon illustrating, in a cross sectional elevational view, a gas discharge over voltage arrester constructed in accordance A gas discharge over voltage arrester is illustrated in the drawing as comprising a hollow electrode 1, a cylindrical electrode 2 and an insulating body 3. The hollow electrode I together with an end cap 4 carried by the cylindrical electrode 2 and the annular insulating body 3 are connected to form a vacuum-tight casing which is filled with noble gas. The justmentioned elements are connected by means of thin wall metal portions 5 and 6 at the transition zones between the electrodes and the insulating body. As is readily apparent in the drawing, the walls of the portions 5, 6 are much thinner than the other zones of the casing; this measure providing the protection of the insulating body 3 from overheating which could occur from the heat generated at the electrodes 1, 2 during an overload condition.

The over voltage arrester represented should be available in particular in a small structural form. In practice this means that the outside diameter D of the hollow electrode 1 should be limited to at most 15 mm., in that diameters in excess of this FIGURE cannot be allowed for an over voltage arrester because of the high constituent of space requirement and because of the sum of total space occupied by gas filled over voltage arresters in a modern plant. A small structural form, however, raises the problem that high current impacts (i.e., flashes of lightning) could bring about an immediate melting or even evaporation of the electrodes. It has been discovered that this undesirable situation can be avoided with certainty if, as according to the invention, the outside diameter D, of the cylindrical electrode 2 is established in accordance with the expression 1 Q2 0.625 ln HM/m) The significations of the expression are:

Q= (/v) I= time in seconds (s) I= current flowing through an electrode in amperes (a.) g specific resistance of electrode material at initial temperature in ohm-centimeters (item) a temperature coefficient of the electrical resistance of electrode material per degree centigrade l/ C.) AT temperature increase from initial temperature (temperature of the environment) to the melting point of the electrode in degrees Centigrade C.) c means specific heat of the electrode material in wattseconds per gram and per degree Centigrade (Wsec./g. C.) 'y specific weight of an electrode in grams per cubic centimeter (g./cm. D, diameter of the cylindrical electrode 2 in centimeters (cm.) D diameter of the hollow electrode 1 in centimeters (cm.) z, k indices for the physical properties of the cylindrical electrode (z) and the hollow electrode (k) in a practical example of execution iron serves as the electrode material. A substitution of the properties of iron in the expression above for the diameter D, of the cylindrical electrode 2, and an assumption that the strongest known flashes of lightning will not exceed 100 ka. and a duration of 100 used, the diameter D is provided as equal to or greater than 2.94 mm., or rounded of, to 3 mm. The initial temperature is assumed in this case to be 20 C.

in order that a gas discharge over voltage arrester be possessed of fail-safe properties, i.e., in order that a short circuit occurs before destruction in response to an overload condition, it is essential that the hollow electrode 1 withstand a higher heating than the cylindrical electrode 2. it is then certain that the integrity of the housing is assured and the cylindrical electrode 2 melts before the hollow electrode 1 acquires a rupture or holes therein. The distance d of the hollow electrode 1 from the cylindrical electrode 2 must therefore be no greater than 1 mm. in order to assure a sufficiently short response time. With the observance of these two boundary conditions, and according to the invention, the relationship between the hollow and cylindrical electrodes is established by the expression This specification for the dimensioning of the outer diameter D,,.,, of the hollow electrode 1 is considerably simplified if, as is the usual practice, the inner electrode and the outer electrode are made of the same material (Fit). The expression then becomes The arrester withstands both brief discharges of high current strength (flashes of lightning) and extended alternating current loads;

In case of overloading the conductors effect a short circuit, and more particularly the electrodes establish the short circuit before destruction of the vacuum-tight casing, i.e., an assured short circuit condition; and

The over voltage arrester ignites so rapidly upon loading with a shock wave that the apparatus to be protected does not suffer damage.

Although we have described our invention by reference to a specific illustrative embodiment, many changes and modifications will become readily apparent and may be made in our invention by those skilled in the art, and it is to be understood that we intend to include within the patent warranted hereon all such changes and modifications as may reasonably and properly be included within the scope of our contribution to the art.

What we claim is:

l. A gas discharge over voltage arrester of the type having a vacuum-tight casing filled with noble gas, a solid cylindrical electrode carrying an end cap which forms a portion of the casing, a hollow electrode which is disposed coaxially of the cylindrical electrode and forming a portion of the casing, and an annular insulating body connecting the end cap and the hollow electrode in a vacuum-tight manner, the improvement therein comprising the provision of the cylindrical electrode of a first electrically conductive material (z) which has a diameter D, in accordance with the expression and the hollow electrode of a second electrically conductive material (It) having an inside diameter D,,., which is at most equal to 2 mm. greater than the diameter D, and an outside diameter D which is at most 15 mm. greater than the diameter of D, as established by the relation where d is the spacing between the cylindrical and hollow electrodes, where Q is the quotient (alloy) of two products which are formed of the temperature coefficient (l/ C.) of the electrical resistance and the specific electrical resistance (l-cm.) of the respective electrode material, as identified by the subscripts k and z, and of the mean specific heat c(Wsec./g. C.) and the specific weight 'y(g./cm. of the respective electrode material, where AT is the temperature difference between the operating and melting temperatures of the electrodes in each case as identified by the subscripts It and z, where l(A) is the maximum current strength, and t(.r) is the mean time duration of the current flow.

2. The voltage arrester according to claim 1, wherein the cylindrical and hollow electrodes are of the same material and the outside diameter D of the hollow electrode over the diameter D of the cylindrical electrode is in accordance with the relation 3. The voltage arrester according to claim 2, wherein the factor Ft is established by the maximum current strength of the strongest known flashes of lightning of I= ka. and a mean duration of i=1 0, whereby FFIO /Fs.

4. The voltage arrester according to claim 3, wherein the electrode material is iron and the diameter D is at least 3 mm.

5. The voltage arrester according to claim 1, comprising metal portions forming portions of the housing and connecting the annular insulating body vacuum-tight with the hollow electrode and the end cap, said metal portions being thin with respect to the remainder of the housing.

Claims

1. A gas discharge over voltage arrester of the type having a vacuum-tight casing filled with noble gas, a solid cylindrical electrode carrying an end cap which forms a portion of the casing, a hollow electrode which is disposed coaxially of the cylindrical electrode and forming a portion of the casing, and an annular insulating body connecting the end cap and the hollow electrode in a vacuum-tight manner, the improvement therein comprising the provision of the cylindrical electrode of a first electrically conductive material (z) which has a diameter Dz in accordance with the expression and the hollow electrode of a second electrically conductive material (k) having an inside diameter Dki which is at most equal to 2 mm. greater than the diameter Dz and an outside diameter Dka which is at most 15 mm. greater than the diameter of Dz as established by the relation where d is the spacing between the cylindrical and hollow electrodes, where Q is the quotient ( Alpha . Zeta /c. gamma ) of two products which are formed of the temperature coefficient (1/* C.) of the electrical resistance and the specific electrical resistance Zeta ( Omega .cm.) of the respective electrode material, as identified by the subscripts k and z, and of the mean specific heat c(Wsec./g. * C.) and the specific weight gamma (g./cm.3) of the respective electrode material, where Delta T is the temperature difference between the operating and melting temperatures of the electrodes in each case as identified by the subscripts k and z, where I(A) is the maximum current strength, and t(s) is the mean time duration of the current flow.

2. The voltage arrester according to claim 1, wherein the cylindrical and hollow electrodes are of the same material and the outside diameter Dka of the hollow electrode over the diameter Dz of the cylindrical electrode is in accordance with the relation Dka2-(Dz+2d)2>Dz2.

3. The voltage arrester according to claim 2, wherein the factor I2t is established by the maximum current strength of the strongest known flashes of lightning of I 100 ka. and a mean duration of t 10 4, whereby I2t 106A2s.

4. The voltage arrester according to claim 3, wherein the electrode material is iron and the diameter Dz is at least 3 mm.