DE728971C - Electric salt bath oven - Google Patents

Description

Electric salt bath oven When operating electric salt bath ovens You can catm the molten salt in two different ways, liquid and, as required Maintain operating temperature, namely through direct or indirect heating.

In the case of direct heating, the operating current is passed through the as Resistance serving molten salt passed. Since the workpieces to be treated are in a current-carrying bath are brought, you have to protect the operating staff work with low voltages. With the usual high voltages of the 1 \ Tetz So the salt bath furnace cannot simply be connected to it, but a low-voltage transformer must be connected upstream. Again, that is not the case required for indirect heating of the molten salt through which no electricity flows by means of electric radiators, e.g. B. metal pipes in which there are heating coils o, like, are located. Often this indirect heating of salt baths is carried out in such a way that that the heating tubes are arranged above the inner bottom of the bath tank.

Due to the formation of sludge and also material falling from the loading baskets however, there is often such a reduction in heat transfer that overstressing occurs this floor heating element, uneven temperature distribution and also burning out the heating coils occurs. Try side heating with the radiator on the long sides and 'or on the front sides of the bath, resulted an inadequate heat flow to the center of the bath and thus uneven Temperature distribution in the bathroom. Also the introduction of side-mounted radiators, z. B. Pipes welded to the container end walls are, presents a variety of difficulties such as pan warping, cracking and occurrence of leaks. Due to the bath liquid flowing upwards, there is also a disadvantageous overstressing of the upper parts of the heating pipes or heating element instead.

Although the immediate heating discussed at the beginning is more even and is more economical, there are, on the other hand, certain disadvantages when heating such Salt bath stoves. Since the solid salt does not conduct electricity, one must first take special precautions to liquefy it. For example, it is suggested the lower ends of the electrodes immersed in the B.adraiim through a to connect resistance consisting of dralite or band-shaped material, -der when the electricity is switched on it is heated and the salt melts until the melt the direct passage of current from electrode to electrode to the next Operational heating takes over. With this arrangement of a heating resistor between The electrodes, however, restrict the free immersion space of the bath, so that one ate the workpieces to be treated only next to the electrodes, but not between can bring the same.

It is also known to use the electrodes themselves as heating resistors use. The same are in at least two places for power supply and drainage set up and connected to a switching device that initially the Electricity to melt the salt through the electrodes, which act as heating resistors goes and later after the salt has been melted and after switching over the Electrodes through which the molten salt flows. These known salt bath ovens are but cumbersome switching devices and a special shape of the electrodes required in order to: use the same one after the other for their two functions to be able to. Another disadvantage is that the electrodes are made of resistive material exist that is permanently in the molten salt and its high operating temperature is exposed.

According to the invention, the mentioned, made of jacketed heating coils and the like existing heating elements used for indirect heating of the salt bath only used to melt the salt, after its liquefaction the metal sheaths the heating elements as electrodes for the immediate operational heating of the liquid Serve salt bath. As a result, the heating elements are only switched on until the melting temperature is reached of the bath, which is usually 300 to q.oo 'lower than the working temperature. During the working period, the heating elements in the metal jackets take the Bath temperature, but are not polluted and not exposed to the attack of the salt, so that a substantial increase in their service life is achieved.

The invention is shown in FIGS. In Fig. I is i the electrode body, which is also the protective jacket for the heating element 2 forms (resistance heating element). The same thing consists of, for example, in ceramic Mass embedded wire spirals, but it can also be in any other known per se Way to be trained.

The hollow electrode body i is expanded at the top to form a housing 3, which is closed with a lid 4. and the terminals 8 for the heating coils 2, which encloses the. Heating current received directly from the network R, S, T. The power supplies c) are passed through glands 5 during the meltdown period the metal electrodes i are de-energized. If by the warming from the inside of the electrodes i the solid salt mass: e in the crucible furnace; essentially liquefied is, the power supply line 9 is switched off, and it is to the: then as Electrode sheaths i low-voltage alternating current, applied in a : Transformer provided with regulating stages i i generated and over the busbars io is passed to the connecting tabs 6 of the metal electrodes i.

You can, depending on the operating conditions, with three-phase current or one or two-phase alternating current.

Claims (2)

PATENT CLAIMS: i. Electric S: alzbadofen with jacketed and for indirect heating of the salt: serving heating elements. characterized, that the heating elements connected directly to the mains with power supply lines (9) (2; arranged in hollow metal sheaths (i) which also serve as electrodes are. those on power supply rails (i o) of a low-voltage transformer (i i i are connected. 2. Salzb: adofen according to claim i, characterized in that that the electrodes (i) on one side or on different sides of the bath and / or are arranged alternately at the bottom of the same.