DE764754C - Metal vapor discharge vessel - Google Patents

Description

Metal vapor discharge vessel The invention relates to metal vapor discharge vessels, in particular mercury vapor flow funnel with metallic vessel walls. For such Discharge vessels it is known to introduce cooling installations into the discharge space, which are flowed through by a cooling liquid. These cooling installations are on The lid of the metal discharge vessel is attached and extends up to the vicinity of the Cathode surface, where the cooling liquid from a supply pipe into the cooling installation occurs, so that the cooling in the vicinity of the cathode is particularly strong. By however, the liquid cooling increases the weight of the converter, namely on the one hand by the weight of the coolant itself and on the other hand by that the vessel and the coolant line because of the weight of the coolant harder to run. When using water for cooling occurs also has the disadvantage that by diffusing hydrogen ions through the wall of a cooling installation, the vacuum is worsened. This hydrogen diffusion is particularly disadvantageous when the discharge vessel is operated without a vacuum pump should, and therefore must in this case prevented by special measures "-earth.

The invention therefore does not use as a coolant, as those mentioned known bodies, a liquid but air. whereby the described Disadvantages inherent in liquid cooling can be avoided. One of Introducing the installation through which cooling air flows into the discharge space is required in the case of aluminum vapor discharge vessels already known from glass. In the known discharge vessels of this type, however, protrudes the cooling installation only slightly into the discharge space and, above all, not enough up close to the cathode, so that an intensive cooling of the cathode, which is at It is particularly important for highly loaded discharge vessels not to occur.

To switch from liquid cooling to air cooling, could remember that for metal vapor discharge vessels with a metallic vessel wall known, reaching up to the vicinity of the cathode cooling installations with essentially unchanged farm and air instead of the liquid coolant to let them flow through. However, this would not lead to success because the Thermal conductivity and heat capacity of the cooling air is much smaller than at a coolant. 'One could consider the cooling conditions for air cooling by increasing the size of the heat sink. However, this path is limited because of the Space in the discharge vessel is not feasible. The invention works because of this from the thought. the cooling air at the hottest point of the heat sink, namely in the vicinity of the cathode to issue a particularly high speed. In this way it is achieved that the vortex formation takes place in the area that needs to be cooled the most Place becomes particularly large, so that the entire amount of air flowing through the cross section is used evenly for cooling. At the other places of the cooling house on the other hand, the cooling air speed is kept lower. One would the cooling air speed, vindigkeit hold anywhere on the high value present near the cathode, so would the flow resistance of the cooling device will be extremely large and accordingly require strong fans or blowers. To achieve the aim of the invention The shape of the cooling structure is therefore also of essential importance.

The invention thus exists in the case of the aforesaid 'metal vapor discharge vessels. inshes s ondere otter silver steam converters, with metallic vessel walls and one introduced into the discharge space, especially cooling the cathode neighborhood Installation in that the cooling installation is air-cooled in a manner known per se and its lower part forms a slender cone that tapers towards the cathode and is designed so that the speed of the cooling air at the hottest point, namely in the vicinity of the cathode, is greatest.

As already mentioned, the cooling installation should have one in its lower part narrow cone tapering towards the cathode. This is the flow cross-section smallest for the cooling air near the cathode and the cooling air speed greatest there. In addition, this shape of the cooling installation is also used for the processes of particular advantage in the discharge space. Those rising from the cathode - '# letal: ldäinpfe do not find, as with the known fixtures, baffles, which give rise to the formation of eddies and the metal vapors in the vicinity of the anodes conduct. what is known to be avoided in terms of reignition safety is, rather the external shape of the cooling installation adapts to the natural steam flow largely and the steam rises unhindered and without vortex formation on the Wall of the cooling installation upwards. He always stays in close contact with the Cooling installation, so that a particularly favorable condensation effect occurs.

Some exemplary embodiments are shown in the drawing.

Figs. I to () show various forms of mercury vapor flow devices with iron vessels in a vertical section. That by means of the fan i from below cooled converter vessel? consists of iron and is mainly in the form of a steep-walled truncated cone 3. in its shell the anode arms ..M inserted steeply are. The anode arms .I have cooling fins 3. On the double-walled truncated cone formed cover 6 is a second fan 7, which with the interior of the cooling unit S is in connection. The cooling installation S is in its upper part g cylindrical. conical in the lower part io, such. that the part with smallest cross section in the neighborhood of the cathode surface. At the inside of the cooling installation S there is a guide similar to the jacket of the cooling installation i i. de in the embodiment to return the double-walled through the hollow Cone 6 sucked in cooling air is used. The suction opening 1a of the double-walled cone 6 is like this. that the fresh air from your territory of the Anode entries is sucked off. The fresh air then passes through the between the outer jacket and the inner installation i i located cavity to the tip 13 of the conical part, to through the opening 14 or the holes 15 inside the part i i to the fan 7 to be guided. By tapering the cross-section of the cooling installation in the lower Part of an increase in the speed of the coolant is achieved and thus its effectiveness increased. In the cavity 16 cooling fins 17 and 18, which decrease in size and number from top to bottom.

In the embodiment according to Fig. 2, the cooling air flow takes its Way in the opposite direction. He is sucked in by the fan i9, is against the lower part 2o of the cooling assembly 2i is pressed and rises through the cavity 22 back to the lid, through the hollow walls 23 of which it reaches the outlet nozzles 24, which direct it directly against the anode entries 25. Here unites the. exhaust air flow emerging from the nozzles 24 with the air flow rising from below, the direction of flow of which is illustrated by the arrow 26. It will be like this. one intensive cooling of the anode insertion points achieved.

In the embodiment according to Fig. 3, the air flow from the ascending Cooling flow sucked in at 27 and counteracted by means of the fan 28 through the nozzles 29 the anode leads 30 pressed. Here, too, are located in the cavity 31 of the Cooling fixture 32 ribs 33 which are welded to the outer wall of the cooling fixture.

In the embodiment according to Fig. D. fresh air is sucked in at 34, which has previously, as indicated, cooled the anode inlets. The exit of the Exhaust air takes place above the vessel at 35. In the embodiment according to Fig. 5 special intake pipes 36 are provided, which remove the fresh air from the area of the Include anode entries.

In the embodiment of Fig. 6 are in place of a single Cooling installation, the lower part of which is conical, several cooling installations provided, which are arranged in staggering, again in the sense that the cross-section the cooling installations in the lower part is much smaller than the cross-section of the Cooling fixtures in the upper part of the vessel.

In the embodiment described, the cap 37 of the cooling installation may be used as an ignition or excitation electrode. To this end it must be connected to a power line in a manner known per se and in a suitable manner Way to be isolated. As can be seen from the illustrated embodiments, it is valuable to attach the fan directly to the metal vessels themselves, and preferably oberbiailb, to be attached in such a way that the cooling air flow removes the fan motor from the warm Metal walls separates. It is achieved in this way that excessive heating of the fan motor avoided, which have a shortening of the service life of the fan as a result would. In the illustrated embodiments, the fan is on that of the discharge space remote end of the cooling installation attached.

Claims (7)

PATENT CLAIMS: i. Metal vapor discharge vessel, in particular mercury vapor converter, with metallic vessel wall and one introduced into the discharge space, especially the cathode neighborhood cooling installation, characterized in that the cooling installation is air-cooled in a manner known per se and its lower part follows one another the cathode is tapered to form a slender cone and is designed so that the speed of the cooling air at the hottest point, namely in the neighborhood the cathode, is largest. 2. Discharge vessel according to claim i, characterized in that that the cover carrying the cooling installation is conical and preferably has a double-walled guide for the coolant. 3. Discharge vessel after Claim i, characterized in that the fresh air on the outside of the cooling installation is guided against the wall part of the built-in located near the cathode and the Concentrically enclosing discharge for the air. d .. Discharge vessel according to claim 3, characterized in that the anode arm ends, in particular the sealing point, are in the way of the coolant flow going through the cooling installation. 5. Discharge vessel according to claim i, characterized in that cooling fins in the cooling installation protrude into the coolant paths: 6. Discharge vessel according to claim 5, characterized characterized in that the cooling fins decrease in number and size from top to bottom. 7. Discharge vessel according to claim i, characterized in that the fan is attached to the metal vessel itself, preferably above the same, so that the cooling air flow separates the fan motor from the warm metal walls. B. Discharge vessel according to claims i and 7, characterized in that the fan is attached to the end of the cooling installation remote from the discharge space. To distinguish the subject matter of the invention from the state of the art, the following publications were taken into account in the granting procedure: Deutsche Patentschriften -Tr. 537227, 6 0 2 115, 603 324 .; Swiss patent specification 1r. 163 677; British patents \ r. 455 5-1 # 8, 4178-18, U.S. Patent We. r 769 092; ; is reachable patent specification 1r. 132280.