CS257069B1 - Electric resistance furnace for glass fibers production - Google Patents

Abstract

The furnace includes a nozzle tray in the bottom and in the side walls of the tray at least two vertical trapezoidal ones power supplies. The leads are inside their trapezoidal surface any cutout. The tray is on equipped with a protective insert with holes in in the walls and profiled into the walls trays.

Description

The invention relates to an electric resistance furnace for the production of glass fibers. The electric furnace consists of a tray with nozzles in the bottom, and in each side wall there is a vertically trapezoidal electricity supply with a cut-out. The tray is further provided with a perforated protective insert which is profiled into the tray space. The tray may be provided with an adjacent lid with stack chimneys and a control chimney.

V Čs. No. 131,649 discloses an electrical resistance furnace for the production of glass fiber from platinum-rhodium material, consisting of a tray with a lid, provided with nozzles in the bottom and one vertical trapezoidal power supply in each side divided by a slot adjacent to the tray side wall; in two parts. The fact that a single power supply of a given shape is used in the side wall of the tray results in recrystallization of the side walls of the tray and thus reduces the life of the entire furnace.

There is no uniform temperature in the furnace width and undesirable turbulence in the furnace drawing section. An increase in output is possible only at the expense of a considerable need for a greater weight of the platinumrhodium furnace and a reduction in its width, but this does not allow to increase the number of drawing nozzles in the transverse and longitudinal directions.

These disadvantages are avoided or substantially reduced by the electric furnace according to the invention, which is based on this. 3. The method of claim 1, wherein each side wall of the tray is provided with at least two trapezoidal power supplies, with a cut-out of any shape within its surface.

Preferably, the electric furnace formed by the tray with the adjacent lid has a tray height to the overall height with the lid in the ratio of 0.95 to 1: 1.

It is further preferred that the height of the pad to the overall height of the tray is in the range of 0.3 to 0.5: 1 and that the height of the perforation of the walls of the pad to its total height is in the ratio of 0.5 to 0.9: 1.

The shape and location of the power supplies according to the invention evenly distribute the electric current to the side walls of the tray. Perforation of the liner, its size and position protect the furnace shell in place, melting the glass. If the electric furnace is designed for two-stage drawing of glass fibers, a lid adjacent to the tray must be used. Thereafter, the lid may be flat or height-dimensioned relative to the overall furnace structure, in particular the total furnace height, optimally so as not to exceed 5% of the total furnace height.

The invention makes it possible to increase the melting of the glass and thus the furnace performance while reducing the weight of the platinum-rhodium material, as well as reducing the burn-through of the platinum-rhodium material and thereby increasing the life of the furnace.

An exemplary embodiment of the invention is described below and is schematically shown in the accompanying drawings, in which FIG. 1 is a longitudinal axial section of the furnace, FIG. 2 is a cross-sectional axial section of the furnace, and FIG.

Electric resistance platinum rhodium furnace / fig. 1, 2, 3) in a particular embodiment intended for two-stage drawing of glass fibers is formed by a tray 7 of the same wall thickness at its height. A lid 2 is sealed to the tray 7, provided with three feed stacks 13 and a control stack 4 for controlling the level of molten glass.

The height of the tray 1 to the total height of the furnace, i.e. the height of the tray 1 with the lid 2, is in the ratio of 0.97. In the single-stage drawing of the glass fiber, the cover 2 need not be used. In each side wall of the bath 7 there are two vertical trapezoidal inlets 6 of electricity / FIG. 3 / provided with a rectangular cut-out 2 inside the feed surface 6 / fig. 1 /.

Between the tray 2 and the lid 2 there is a protective insert 13, profiled into the interior of the tray 2, which prevents unwanted glass from penetrating the bottom of the furnace. The protective insert forms 40% of the total height of the tray. In the bottom two trays are in one or more rows arranged nozzle 2 P ^ro drawing glass fiber.

The device works as follows

Glass beads in the form of two-stage drawing is continuously fed chimneys _3 incorporation into the tray 2, which is heated by means of the trapezoidal cutouts provided with inlets 2 · The shape of the notch 2 ^is selected ^by the position or dimensions according to the desired treatment temperature and the glass according to the desired throughput rate. The glass melts in the tray 2 through the openings of the perforated protective liner 8, which prevents thermal shock to the walls of the tray 2 ^and also prevents leakage from the nozzles 9.

SUBJECT OF THE INVENTION

Claims (3)

SUBJECT OF THE INVENTION An electric glass-fiber resistance furnace, consisting of a tray provided with nozzles at the bottom, in each side wall a vertical trapezoidal power supply with a cut-out and a protective insert profiled into the tray space, characterized in that each side wall (5) of the tray (1) it is provided with at least two trapezoidal power supplies (6) with a cut-out (7) of any shape within its surface. 2. The electric furnace of claim 1, the tray of which is provided with an adjacent lid with stack chimneys and a control chimney, characterized in that the height of the tray (1) to the height of the tray (1) with the lid (2) is in the ratio of 0.95 to 1: 1. Electric furnace according to claim 1 and / or 2, characterized in that the height of the protective bed (8) is 0.3 to 0.5: 1 to the total height of the tray (1) and the perforation height of the walls of the protective insert (8). to the total height is in the ratio of 0.5 to 0.9: 1. 1 drawing