DE846748C - Electric discharge device - Google Patents

Description

Electric discharge device The invention relates to 'Metalldampfent- charging equipment with liquid cathode and deals in particular finitely with such institutions, in which the piston llaul) actually consists of a glass-like or ceramic material. These 1 devices can be grid controlled and a constantly sustained excitement own arc. In such establishments, the Intladtiiig developed heat can be dissipated. so that clei pressure inside the piston does not exceed a vc »-hestininites maximum increases. This can can be achieved in different ways, however is used for: Tig the cooling; in the cathode hands of the institution concentrated, there, if the C) overfill the catholyte itself can be adequately cooled, a higher operating temperature is permitted in the other part of the vessel than would otherwise be permitted. This is particularly advantageous in the case of single-atomic devices, or of a type of natural-anodic device, where the anodes are located in the main body of the vessel and not in side arms, since in such cases the arrangement of the large vapor condensing dome usually used when such side arms are used provided is inconvenient.

According to the invention has a metal vapor discharge device, With wL'lcher the piston mainly made of glass-like or ceramic material consists, a cathode consists of a flat @ tetalliquid filling. that of a nearly planes: metal plate is supported, which is a part of the piston of the device and is in heat exchange with a coolant. In this way there is a relatively short path for the line through created the cathode material and presented a large cooling surface for your coolant. In addition, the path of heat conduction from the cathode surface to the coolant run completely in metal and results in a bessexe @% lärmeül> yield than if the Heat must pass through the flask of the vessel.

The exact relationship between the area of the cathode liquid and its depth will depend to a large extent on the size of the liquid filling, since a considerable amount of care is required in large facilities (e.g. those with a cathode area of about 75 cm2 or more) "The level control prior to commissioning would be justified", while in the case of smaller facilities, the user would be expected to have greater leeway with regard to the operating situation. In practice a ratio of the outer diameter to the average depth of 6: 1 or more is satisfactory, and for larger cathodes this ratio can e.g. B. can be increased up to about 30: 1 for a cathode with an area of about 192 cm2.

The mentioned level: metal plate can be made entirely of one material, such as z. B. Kovar, which can be melted directly into glass, and they can have an upstanding flange, the edge of which is attached to the end of one of the pistons the device forming the glass tube is melted, or it can be a plane Be a disc on which (the glass tube is bluntly sniffed. In a different way the plate can be made of steel or some other material which is attached to a tape made of Kovar is welded on. In each case there is expediently the meltdown according to a further NZerknial of the invention below the mirror of the surface of the Catholyte. This arrangement has in the case of continuously excited devices the advantage that the melting through the mercury against the effects of the Arc is protected.

Further details and advantages of the invention emerge from the following description of preferred embodiments as rectifiers can be described on the basis of the drawing. However, these facilities can also used for other purposes.

In Fig. T, which shows a section through the lower part of a rectifier according to the invention, a flat Kovar plate @i, the edges of which are drawn at right angles to form a flange, is melted at 2 to (the end of a tubular glass bulb 3 and carries a mercury filling 4 A cooler 5 provided with cooling surfaces 6 is attached to the Kovar disk n, and since the latter tries to warp when it is heated to produce the seal, an intermediate stiffening element 7 is attached to the plate 1 by copper killing. This stiffening disk does not extend over the entire diameter of the plate 1 in order to avoid tearing of the enclosure 2 when the temperature changes.

A grid connection 8 is introduced through the cathode by means of a glass seal 9 and a Kovarring to which is welded to the plate 1. The insulation of the grid connection formed by the seal 9 extends to a point above the mercury level 4, and between this point and its upper end, where it is connected to a grid protection plate ti by a flexible connection 12, it is provided with insulating beads 13, the purpose of which is described below. Another connection r14 is introduced through the cathode by means of an identical seal 1, 5 and a ring 10 and provided with glass insulation 17. This connection serves as an introduction for the supply of the excitation arc and is connected to the carrier T8 of a magnetically actuated ignition or immersion electrode ig. When the immersion electrode rg is activated, it ignites. They create an electric arc, uni on the surface of the mercury 4 a: cathode spot, and a plate 20 is provided for fixing the spot, which extends over the surface of the mercury near the I, tide of the dew electric (1e icq protrudes.

When operating the rectifier, the grid line 8 takes during the non-igniting part of the period a considerable return current in the form of positive Ions from the excitation arc. This is especially the case when the Grid is at a negative potential, like a grid control the tension. This results in an undesirably low grid resistance and resistance high tax output required. This difficulty is resolved by the incomplete Isolation of the grid line 8 in the form of beads 13, the gaps between the Beads form a highly deionized path to line 8.

This preferred embodiment of a rectifier according to the invention has a cathode surface area of approximately 51 em2, and the average depth of the mercury fill is 9, 5 mm. The flange of the plate t is dimensioned so that at this depth of the mercury the mirror lies above the seal 2 so that the cathode spot cannot fix itself under any circumstances on any part of the plate i. If the mercury level were below the seal 2, the cathode spot could tend to move to the exposed part of the plate 1 and either burn a hole in it or generate enough heat that the seal 2 breaks up. The average current density. the cathode is expediently held under 8 amperes per 6.4 cm 2 direct current on the vertical projection of the plate 1, which is in contact with the cathode filling 4.

I> The use of the plate 2o to fix the spot results in a increased stirring movement of the Ouecl <sillcei-fiilltltlg I, whereby The heat transfer from (pure mercury to the plate i is further improved will.

As can be seen, 1> e1 the depicted on -]) on the cooler s and its cooling surfaces 6 serve as bulk for the \ 'connectionetl 8 and @ia and their hetrettetideti Eittscliinelzutlgetc and also for a. \ Llschtliclzt-0111-21.

U il '. 2 and 3 show "a vertical Sclitiitt (LTTT-C1 i (gen lower" healing of another form of t @ leichricliters gcniül.i of the invention and a section along the line 111-111 of Fig. 2.

11e1 of this example, the cathode 22 has IZiiigf (u-tn u11 (1 it is accommodated in a space between a reclirfiirmigett Atißecthiille 23 and an inner k (>; t @ ialetc tube 24, through the upper closed l? It, ( le l: itifiilirtiligslinien> 3 "n (126 for the excitation, - or lattice; lcl: tr (ude and a: \ l) s" ittg- and melting tube 27 side clitii (ilz (#u are. Fitie with a flange verselceice K (lvarl> latte 28 has a central opening, aii which, z. 1). is fixed by welding, a Kovarri @>, g 2 () and (the open linden of the tube 2.1. is act (l a free edge of this ring I: itlc ring lath 3o from tKovar is attached by Kttl) fet-liitttiig to (, an underside of the plate 28 for its mounting, and the flanged "part of the putty> 8 is to (learn the lower end the I Hille 23 is melted. E = in the cooler 31 is made of soft steel; attached in the \ 'egg-stiffening plate 30 , t111 (1 (read is expediently after your \ ttslieizeii (Ittrcli Uiten made. The solder (can lauer a melting point (z. B. i # 5O, C) have. Of lower than the annealing temperature, (l (1a1.1 the T'Iatte 30 and the 'cooler 31 only Tiber a G limited temperature range with each other Matt katm then the contacting part (k # s I11 -iililers 31 1111 diameter more similar to that of the plate 3o, without the risk of breaking the melt. An excitation electrode 32 is provided and is similar to the one on the basis of Fig It is carried (locli by l) ri'Lliten 33, which serve as a pivot pin and which are fastened to a bracket 34 surrounding the ear 24. ?.. let them the I lektrode shown at (learning tube 24 as shown in Fig 3 3 2 when actuated do not abut a recessed cover plate 3 (> is above the opening in the plate 28 for estimating the:. fitted \ bschinelzrohrs 27 and with () provided through which the lines 25 tucd 26 (church. In ande In this way, the leading 2; tiud 26 end at suitable connections that are attached to the: \ 1) (leak) lath 36.

In order to reduce the amount of Ktttli (i (leiim: itcri @ il used and to increase the Gesrhwiu (ligl: cit (lcr \\ - ürtneiberigenous between the surface of the cathode _r2 and the bucket 31, 1 : a1111 an IZingk @ irlcer 37 can be attached below the surface of the I @ ath0de 22. The body 37 liat a liiiliere \\ 'in conductivity than the Katlc (uletincatt # rial lind 1: a1111 in] case of a mercuryl: at @ c (c (Ie zwecl: m; il.iig; consist of steel, the thermal conductivity of which is a multiple of that of mercury. The body 37 is held at a distance from the plate 28 so that the cathode material can bring about an intimate, heat-conducting contact between them Furthermore, the body 37 is designed or provided with a spot fixing ring 38. In another embodiment, the body 37 itself can form the larger part of the cathode support plate, with Kovar rings, which are welded on its outer and inner periphery, to the Sleeve 23 and your lZohr 2.1 will be melted down. In this case the stiffening plate 30 can be left and the cooler 31 attached directly to the 'body 37'.

Another: Execution in which the amount of cathode material is diminished, becomes in hig. 4 shown. 13e1 this structure is attached to your tubular Glass bulb 4o melted on a flange 41 of a metal plate d2 on its lower IZ @ uld, which serves as a carrier for the cathode-ray material 43. In this case the 14ewiinsclite "Depth of the cathode material 42 is less than the length of the flange 41, which is required is. uni adequate radial flexibility in the area of the seal reach ". The larger part of the plate .42 therefore jumps in, so that (read cathode material the melt is still covered, while the average flow of cathode material is left is decreased. In the case of the designs described above, there is a stiffening plate 44 attached to the plate 42 by copper soldering and serves as a carrier and for heat-conducting Contact with a rivet body 43 which is provided with cooling surfaces 46. As beforehand, a spot fixing latte 17 is attached to the plate 42.

Claims (3)

PATENT CLAIMS: c. Metal vapor discharge device with an in the main thing is made of glass-like or traditional material, characterized in that the cathode consists of a flat metal liquid filling ordered. that of an approximately flat, part (total piston of the device forming `1 \ letallplatte is carried, this plate in \ Viirineatistatic with a coolant. 2. Metal roof discharge device according to: \ nspruch i, characterized in, (let the melt between the plate and the piston part below the mirror (total cathode metal is arranged. 3. Set up after Claim 1 oller 2, characterized in that the ratio of the cathode diameter the depth of the cathode material is between 6: 1 and 30: 1. .I. Facility according to claim: i or the following, characterized. : (ate the one carrying the cathode Metal plate on the edge is finitely provided with a flange, which is attached to the piston of the I, 'iici-iclitung atigeschniolzen is. Device according to claim .i or the following, characterized in that the metal plate carrying the cathode is in the form of a Flat disc is formed on which the piston of the device is butt fused is. 6. Device according to claim 2 or the following, characterized in that the total amount of cathode material is reduced by the fact that a body consists of full metal on the upper surface of the metal plate supporting the cathode and below the surface of the cathode material is arranged. 7. Device according to claim 6, characterized in that the solid metal body is in the form of a ring is formed and Einführurngsdräfhte for electrodes of the device through a Tube are melted, which itself through a central opening of the cathode supporting metal plate is inserted tightly throughout. B. Establishment according to Claim 2 to 5, characterized in that the total amount of the cathode material is reduced by the fact that the greater part of the plate carrying the cathode recedes is trained.