SU533552A1 - Apparatus for cooling the underfilter zone of a glass melting vessel - Google Patents

Description

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The invention relates to the production of continuous glass fiber, in particular to a device for cooling the underfilter zone of a glass melting vessel, and can be used in glass fiber factories.

A device is known where the under-filtering zone is cooled due to the presence of a cooling agent distributor connected to the air duct 1. A device for cooling the under-filter zone of a melting vessel with longitudinal and transverse rows of dies is known, including a cooling agent distributor connected to the air duct 2.

A disadvantage of these devices is that they do not provide the possibility of forming fibers from low-viscous melts, especially in multi-vessel vessels, due to the varying degree of air flow on distant rows of stretch fibers. In addition, a device designed to use fan air is cumbersome and, in the case of using compressed air, becomes uneconomical.

The aim of the invention is to ensure the formation of fibers from low-viscosity melts.

What is achieved by the fact that the device is equipped with an alignment chamber installed in front of the coolant distributor

pressure, and the coolant distributor is designed as a stepped nozzle with channels and set at an angle of 106-113 ° to the pressure equalization chamber, the ratio of the length of the step to its height is 2.5-3.5, the channel length to its diameter is 10 -20, and the channel spacing is 0.35-0.5 pitch dies in longitudinal rows of the vessel.

FIG. 1 shows a device in an installation scheme for producing continuous glass fibers, a general view; in fig. 2 - the same, side view; in fig. 3 is a section along A-A in FIG. 1. The device includes a cooling agent distributor, made in the form of a nozzle 1, in front of which a pressure equalization chamber 2 is installed. The nozzle consists of steps 3 with channels 4 in each step and is set at an angle of (a) 106-113 ° to the chamber

pressure equalization; A water-cooling coil 5 is located around the nozzle.

The device is installed in the underfilter zone of a glass melting vessel 6 with longitudinal and transverse rows of dies 7. The channels in the steps are arranged in increments (t) corresponding to 0.35-0.5 steps (k) of dies in the longitudinal rows of the vessel. The steps in the nozzle are designed so that the ratio of their length (b) to height (a) is 2.5-3.5, and the ratio

the length (/) of the channel to its diameter (d) is 10–20.

For forming fiberglass, a thread-forming sizing device 8 is installed under the cooling unit, and below it a stretching and winding mechanism 9 for replaceable forgings 10.

The device works as follows.

From the common line, through the air duct, pressure equalization chamber 2 is supplied with filtered, pressure stabilized compressed air or another cooling agent — gas (argon, nitrogen, water vapor, etc.), the required flow rate of which is determined by a valve as measured by a manometer in a known manner. From this chamber, compressed air passes through several rows of channels 4 in steps x 3 of metal nozzle 1 cooled by coil water 5. From nozzle 1 one-sided air flow enters the subfilter zone of the melting vessel 6, cooling the bulbs 11 formed after the exhaust mechanism exhausts and winding the melt flowing through the dies 7 of the glass-melting vessel 6. Performing the nozzle steps with a ratio of the length of the step to its height within 10-20 ensures laminar flow of the cooling agent. The uniformity of flow along the length of each row of channels is ensured by the fact that the channel pitch corresponds to 0.35-0.5 steps of the nozzles 7 in the longitudinal rows of the vessel 6, and the uniformity of the effect of the flow on the distant rows of bulbs - by the ratio of the step length to its height - 2.5-3.5.

The proposed device, tested under experimental conditions, makes it possible to carry out a stable fiber-forming process on multi-glass-melting vessels (feeders) at low melt viscosity (10, 10 poises), which is technically impractical when using the known devices.

This ensures the production of continuous glass fibers from a range of high modulus, high strength and other special glasses, such as magnesium aluminum silicate glasses of different chemical composition, calcium aluminate, invert glass with a limited content of silica oxides (5-25 wt.%), Glasses with a high concentration of rare earth oxides, for example oxides of yttri, laptan, cerium, niobium, tantalum, gallium, neodymium, presodymium, etc., and obtaining increased strength based on new fibers of fiberglass, strength with specified specimens physical and chemical properties.

Claims (2)

1. US patent No. 3475148, 65-2, 1969 2. Auth. St. No. 103274, cl. S OZ 5/02, 1955. (prototype). 3 , J nnnnnnnnnp -:, P  and 1 ii / / tti7, / 7 -