SU1754785A1 - Saline bath - Google Patents

Abstract

The invention relates to electrical engineering. The bath contains lining (F) 1 and electrodes 2, made in the form of plates (P) with evenly spaced protrusions (B) 3 connected to the current leads (T) 4. P 2 are located in the lower part of the bath and buried in F 1 in parallel the walls of the bath so that B 3 is located on the F side. The surface of the electrode plates on the F side is covered with an organic or organosilicate coating 5. T 4 can be made in the form of wire, mesh, etc. and are connected to B 3 plates. T, connected to P and reinforcing F. not dkigp y-1 - s, since protected by a layer of concrete and are located in the depth of F, where the temperature is lower than i t of P. 1 Cp f-ly, 2 ill.

Description

Fig i

The invention relates to electrical engineering, in particular, to salt baths and electric resistance furnaces.

Salt baths are known with wide-spaced electrodes of the bottom structure made in the form of bars arranged perpendicular to the bath wall so that the working part of the electrodes are their ends.

The disadvantage of this design is the relatively low power that can be isolated using a single electrode group.

The reduction of the melt resistance due to an increase in the working surface of the electrodes is limited by design considerations, since with the diameter of the electrodes over 80 mm, the cooling and moving assembly of the electrodes is cumbersome and inconvenient during operation. Reducing the distance between the electrodes results in: a decrease in the working space of the bath, which is not always acceptable.

The closest to the claimed is the salt on the bath containing the lining, electrodes made in the form of parallel to the walls of the bath and the plates embedded in the lining, and leads. The leads of the electrodes in this case are a continuation of the electrodes and are above the level of the melt.

The disadvantage of this design is the low lifetime of the electrodes due to the fact that the electrodes with the leads are exposed to oxygen and salt vapors at a high temperature at the salt-air interface.

In addition, this furnace has a low lining life due to the fact that a large difference in thermal expansion coefficients of the lining and electrodes leads to the formation of cracks due to temperature changes during operation of the furnace (switching on and off).

The purpose of the invention is to increase the service life of the bath and increase productivity.

This goal is achieved by the fact that in a salt bath containing a body, lining with cavities and electrodes installed in the cavities with current leads, the cavities are made in the lower part of the lining, the electrodes are made in the form of plates with uniformly spaced protrusions facing the body, Thereby, the protrusions are connected to the current leads, and the surfaces of the plates with the protrusions facing the body are made with a protective coating to compensate for thermal expansions of the lining material and the electrodes.

The essence of the invention is that: firstly, the entire working surface

the electrode is immersed in molten salt, and the electrode leads are not in contact with the salt at the level of the melt and are not exposed to oxygen and salt vapors at high temperatures. In addition, the coating on the electrode creates a backlash between the lining, the electrode and the thickened leads, so that the lining and electrodes do not deteriorate with temperature.

Known constructions of salt baths, in

which conclusions are located on the side surface of the electrode and not in contact with the melt. They are massive current leads with water cooling, which are unreliable because of the possibility

corroding the linings and subsequent damage to the water cooling system, leading to an emergency. Thus, the specified structure is unreliable and unsafe in operation. However, the design of electrodes with leads does not require water cooling and ensures high reliability and service life of electrodes and lining,

FIG. 1 and 2 are represented by salt on the bath.

Sol on the bath contains lining 1 and electrodes 2, made in the form of plates with evenly spaced protrusions 3 connected to current leads 4,

The plates 2 are located in the lower part of the bath and are buried in the lining 1 parallel to the walls of the bath so that the protruding parts 3 are located on the lining side. The surface of the electrode plates on the lining side is coated with a protective coating to compensate for thermal expansions of the lining materials and electrodes — an organic or organosilicate coating 5. Conclusions A can be

Vmde wire, mesh, etc. They are connected to the protrusions 3 of the plate.

Plates can be made of various iron-chromium-aluminum, chromium-nickel and other heat-resistant alloys,

for example, Х27 06АТ, Х23Ю5А p 20Н80идр.1, depending on the temperature of the melt in a salt bath.

The current leads attached to the protrusions of the plates can be made of iron-chromium-aluminum alloys with a small amount of chromium.

Organic or organosilicate coatings for application to the surface of the plate, embedded in the lining, can

be the most diverse, such as dextrin i dye, etc.

Concrete for a dense lining layer, in which the lead ends of electrodes in the form of a mesh, wire, etc., are embedded, may consist of components resistant to molten salt in a salt bath. The aggregate for concrete can be chamotte with a content of from 60 to 100% or magnesite, magnesite-chromite or chamotte from spindle refractories. High-alumina and alumina cement, as well as magnesia cement can be used as a binder.

The bath sol works in the following way.

When voltage is applied to the current terminals A and the connection of the plates 2 with temporary conductors, partial salt melting occurs, for example BaCl2. Electric current passes to the discharge leads 4 through the protrusions 3 of the plates and the plates 2 themselves and completely melts the salt. The molten salt from the bottom of the bath with the bottom plates of the bath rises, causing the whole mass of salt to mix.

This achieves uniformity in volume over the entire volume of the bath. The plates are heated with molten salt. An organic or organosilicate coating on the side of the plate embedded in the lining burns out, due to which there is a gap (gap) between the lining and the plate. Due to the formation of a backlash, the concrete lining is not destroyed by the plates due to the difference t of the thermal expansion coefficients of concrete and the metal of the electrodes. Conclusions connected to the plates of the electrodes and reinforcing the concrete lining are not

are oxidized and are not exposed to corrosive effects of salt vapors due to the fact that they are protected by a layer of concrete and are located in the depth of the lining, where the temperature is lower than on the plates in contact with the molten salt.

Thus, the service life of the bath in the proposed solution is higher than in the prototype. In addition, in the proposed salt bath, the material of the leads and electrodes made of scarce nickel-nickel alloys is much more efficiently used.

The large working surface of the electrode plates in the bath increases the output power accordingly. The increase in power that can be released in the bath melt leads to an increase in productivity; tyk the bath time is reduced.

Claims (2)

1. A bath salt containing a housing, lined with cavities and electrodes installed in the cavities with current leads, characterized by 4 and 4 in that, in order to increase service life and increase productivity, the cavities are made in the lower part of the lining, plates with one-sidedly spaced protrusions facing the body, while the protrusions are connected to the current leads, and the surface of the plates and. protrusions with current leads are made with a protective coating to compensate for thermal expansions of the lining material and electrodes. 2. Bathtub according to claim 1, characterized in that the protective coating is made of an organosilicate material. ABOUT Editor A.Mikovska Tehred M. Morgenthal Order 2870 Circulation: Subscription VNIIPI State Committee for Inventions and Discoveries at the State Committee on Science and Technology of the USSR 113035, Moscow, Zh-35, 4/5 Raushsk nab. Production and Publishing Combine Patent, g, Uzhgorod, Gagarin st., 101 Proofreader A.Osaulenko