SE435984B - LAMP HOLDER COMPOSED OF TWO PARTS - Google Patents

Abstract

A lampholder is composed of two parts which at least generally are located on opposite sides of an axial plane with respect to an incandescent lamp inserted in the lampholder. To facilitate manual mounting of electrical contact strips in the lamp holder and assembling of its halves and make possible automation of these two operations while maintaining a satisfactory mechanical rigidity the first part (1) comprises a central portion (2), which substantially forms part of a cylinder, and two annular ends (3, 4) integral therewith, while the second part (10) is comprised of a lid or cover member (10) which substantially forms part of a cylinder and is joined with the central portion of the first part and portions of its annular ends. One half of the thread of the incandescent lamp, which is located on one side of an axial plane, is provided on the lid member (10). This permits cores utilized during the moulding of the halves of the lampholder to be drawn out of the mould, which makes possible automation of the manufacture of the lampholder.

Description

7907268-2 The process of silicon encapsulation is extremely difficult to carry out in mass production. Varis large discs are encapsulated in said silicon by means of a casting operation and individual dual varistor disks or a pair of disks must be inserted in a separate form before the silicon encapsulation material is added.

After a sufficient period of time has elapsed for the silicon material to harden, the encapsulated disks must be manually removed from the molds. The high material costs for the quantity of silicon material required, as well as the usual molding operation, has made the use of zinc oxide varistors in surge arresters very expensive. The object of the present invention is to provide a surge arrester comprising zinc oxide varistor with an improved heat dissipation capacity to a significant significantly reduced manufacturing cost.

The zinc oxide varistor disks are equipped with heat traps in form of metal plates. The combination of heat traps and varistor disks are kept in intimate thermal contact with each other.

The metal discs quickly remove heat from the varis discs under surge voltage conditions and transfer said heat 11111 a casing.

The particular characteristic of the invention is subject to the following claims.

The invention is described in more detail below with reference to to the accompanying drawings.

Fig. 1 is a sectional view through a surge voltage conductors containing a plurality of varistor disks.

Fig. 2 is an enlarged perspective view of a zinc oxide varistor disk according to Fig. 1, partly in section.

Fig. 3 is a front view, partly in section, of one surge arrester containing a heat transfer arrangements according to the invention.

Fig. 4 graphically illustrates the power loss of a zinc oxide varistor as a function of varistor temperature.

Fig. 5 is a sectional view through the surge voltage the conductor of Fig. 3, along the plane 5-5. 7907268-2 Fig. 6 is a side sectional view through the thermal transfer the guide arrangement according to the invention.

Fig. 7 is a side view of the arrangement of Fig. 6.

Fig. 8 is an enlarged cross-sectional view through the heat exchanger. the arrangement of the varistors in the surge arrester _ according to Fig. 3.

Fig. 9 is a plan view of another embodiment of a heat transfer arrangement for varistors according to the finding.

Fig. 10 is a perspective view of another embodiment of a heat transfer arrangement for varistors according to fig. 9. ' Fig. 11 is a side sectional view through a further embodiment. embodiment of a heat transfer arrangement according to the finding.

Fig. 1 shows a typical surge arrester 10 thereof type comprising a porcelain casing 11 with an upper end joint end 12 and a top connection 13 electrically connected a plurality of zinc oxide varistors 16 via a spring 15. The diverter further comprises a gas space 17 to allow gas discharge in the event of a varistor error. Diversionary the arrangement is closed at the bottom by means of a batten closure 18 and electrical connections to the bottom are obtained via a bottom connection 14. The varistors used in the diverter is of the type containing a sintered sheet of zinc oxide material 19, as shown in Fig. 2, and having an electrode layer 20 on the top and bottom surfaces.

The varistor is enclosed in a single collar 21 to prevent a discharge from occurring between the electrode layers along the periphery of the varistor and while bypassing the zinc the oxide material.

For dissipation of heat generated in the varistor body during operation in a diverter device similar to the surge voltage the diverter according to Fig. 1, a heat transfer arrangement according to Fig. 3. The diverter 10 according to Fig. 3 is similar the one according to Fig. 1 and the same reference number is used for display to the corresponding element. Heat sink discs 23 with 79ü °? 263'ï2 i »B high thermal capacity and the varistors 16 are surrounded by flexible elastic sleeves 22 so that the varistors are kept in intimate electrical and electrical contact with each other and with end-to-end by means of the spring 15. The flexible, elastic sleeve 22 is kept in thermal contact with the porcelain casing 11 by means of a positioning means 24, which is inserted between the housing 11 and it heat transfer device, including the elastic sleeve san 22 and the heat sink plate 23 on the varistor 16. At In the embodiment according to Fig. 3, the heat sink disc 23 may consist of a material with high thermal capacity, such as steel.

Then shock currents flow through a typical zinc oxide varistor the temperature of the varistor rises directly with the amount-energy absorbed by the varistor and inversely proportional to the vål the mass as the specific heat of the varistor. Then the temperature at the varistor increases, the power loss in the varistor increases at normal voltage as shown in Fig. 4, in which the thermal the conductivity of the surge arrester A is compared with varistor power loss per rated voltage unit at operating voltage B. After a high surge current flow, the power the conduction requirement for the varistors increase to such an extent that the power loss for varistors B exceeds the heat dissipation the ability of the surge arrester A, as shown at C, so that an avalanche-like thermal course is obtained. Then the heat trap 23, which is held against the varistor by means of the flexible elastic the sleeve 22, as shown in the embodiment of Fig. 3, used, the temperature of the varistor rises directly with the amount energy absorbed by the varistor and inversely proportional with the combined masses and specific heat for both varistor 16 and heat trap 23, due to the fast the heat flow from the varistor to the heat trap. Temperature step ~ the ring of the varistor is now kept at a sufficiently low level, so that the possible heat flow through the sleeve 22 is greater than the power the loss of the varistor, whereby the varistor is effectively cooled a normal working temperature. The functional relationship between the positioning member 24 and the varistor 16 are shown in Fig. 5, of which it appears that a gas space 9 is provided for gas expansion in event of varistor error. The thermal transfer arrangement goat according to Fig. 3 is shown in more detail in Figs. 6 and 8, wherein '7907268-2 U1 varistor 16 has upper and lower electrode layers 20 on top resp. the bottom surface of the zinc oxide material and a ceramic collar 21 around the periphery of the zinc oxide material. Further includes a metal plate 23 which is kept in thermal contact with the water the grate by means of the elastic sleeve 22. The material which selected for the elastic sleeve consists of a silicon resin with a high degree of flexibility and good heat-conducting properties.

As previously described, the metal plate 23 includes a steel plate. composition, but other materials, such as iron, aluminum and copper, other metal alloys, as well as other heat conductors materials with a relatively high heat capacity, can also be used jacket.

The thermal transfer arrangement of Fig. 6 shown in Fig. 7, the elastic sleeve 22 surrounding the varistor 16 and the heat trap 23. Electrical contact is achieved between each varistors in a series arrangement of a plurality of varistors by means of the electrode layer 20 of a varistor and the metal plate 23 on the next varistor in the series. In some applications The ceramic collar 21 can be eliminated, whereby it the elastic sleeve 22 provides electrical insulation between the electrode layers on the disk, to which it holds the metal disk and the varistor in good physical contact.

The positioning member 24 holding the varistor and the metal the heat trap in thermal contact with the arrester in Fig. 3 is shown in more detail in Fig. 8. As soon as the elastic sleeve 22 has applied around the heating arm and the metal plate is inserted the metal plate and the varistor in the diverter housing. Po- the sizing member 24 has the shape of a dog bone, which is stretched by applying a voltage to both ends, which brings the middle portion of the position element to be extended. So soon the varistor, the metal plate and the elastic sleeve have been placed in the housing, the voltage is removed from the ends of the position the element for pressing the varistor device directly against the housing jet. The element 24 can suitably be made of a flexible polymer, such as silicon resin or other electrical insulation the materials with good thermal conductivity.

Fig. 9 shows the electrical sleeve 22 and positional the element 24, the element 24 being held between the varistor 16 7907268 -2 and the sleeve.

Pig. 10 shows a combined elastic sleeve 22 'and a protrusions 24 'made in one piece. The projection 24 'comes in equal with the position element 24 to hold the device against the housing.

With the new heat transfer arrangement according to finding, the thermal transfer characteristics can be tailored to sewn for each special product requirement. Then high heat capacity required together with good thermal conductivity, metal alloys are tailored to suit the special thermal requirements.

The important requirements are that heat must be able to are led away from the varistor and that the heat storage capacity of the disc-shaped heat traps is sufficient to prevent an excessive temperature rise of the varistor. The purpose of the elastic sleeve is to provide good thermal contact between both the varistor and the heat trap and with the wall of the porcelain casing. In the case of the elastic the sleeve is omitted and the heat trap is attached by means of an adhesive with a high melting point, such as a metal alloy, the geometry of the heat trap is adjusted to better match the interior the geometry of the porcelain casing for efficient heat transfer.

In some applications the binder may be excluded and the heat trap lan is allowed to be in direct contact with the varistor. The outer the surface of the disc-shaped heat trap can be surrounded by the elastic the sleeve to provide good thermal contact between the housing and the heat trap without allowing the electrically conductive heat the trap to be in direct contact with the housing. _ Fig. 11 shows an embodiment in which the elastic the sleeve 22 surrounds the disc-shaped heat trap 23, varying tower is slightly recessed in the heat trap for placement purposes.

The heat sink is oversized relative to the varistor diameters to provide a geometry that adapts closely to the inner geometrhxhos housing for efficient thermal transfer förinq.

Although the thermal transfer system according to the invention has been described for use in surge voltage leading housings, this is just one example. System according to the present invention can find use everywhere there zinc oxide arresters can be used.

Claims (4)

'7-'907268-2 Patent Claim Shock surge arrester comprising a substantially cylindrical housing (11) and connecting means (13, 14) mounted at opposite ends of the housing, characterized by a plurality of zinc oxide sheets (19), each provided with electrodes (29) on opposite surfaces of the disc, and a plurality of heat traps (73), each made of an alloy of iron and having a volume corresponding to a substantial part of the volume of the individual zinc oxide sheets (19) and a high thermal capacity, which sheets and heat traps are arranged in an alternating sequence forming a stack in said housing (11) and electrically connected in the form of a series arrangement between said connecting means (13, 14), said heat traps (23) being in intimate thermal contact with adjacent pairs of zinc oxide sheets (19) and is in electrical contact with their electrodes (20), whereby said heat traps rapidly absorb heat from said discs to effectively limit the temperature rise of them, when current thereby flows under surge conditions. A arrester according to claim 1, characterized in that it further comprises a plurality of insulating sleeves (22), each of which surrounds different of said discs (19) and heat traps (22) in order to maintain them in pairs thermally and electrically interconnected. 1 A trap according to claim 1 or 2, characterized in that said heat traps are in the form of sheets (23) with mutually the same diameters, which substantially correspond to the diameter of said zinc oxide sheets (19). Diverter according to one of Claims 1 to 3, characterized in that the heat traps (23) are made of steel. of a arrester according to any one of claims 1-4, characterized in that it further comprises means (24) for arranging said stack of zinc oxide sheets (19) and heat traps (23) in heat transfer contact with said housing (11) .