SU1642217A1 - Device for heating charge of bricks - Google Patents

Abstract

The invention relates to the building materials industry and can be used in kilns for firing ceramic products, for example, in brick ring-type kilns with a batch structure and removable vaults. The purpose of the invention is to intensify the heating of the charge and save thermal energy. Between the brick packages there is a screen made of refractory fiber along the entire length of the charge in the direction of the heat carrier. The thickness of the screen prevents penetration of the light beam through it. As the screen heats up faster, it begins to transfer its heat to the charge by radiant heat exchange. Increasing the warm-up rate of the load increases the turnaround of the furnace, increases its productivity and reduces fuel consumption. 2 Il.

Description

The invention relates to the building materials industry and can be used in kilns for ceramic products, for example, brick factories in ring kilns with batch piles of bricks.

The purpose of the invention is to intensify the heating of the charge and save thermal energy.

FIG. 1 shows a diagram of a heat shield; in fig. 2 - placement of a heat shield between brick packages.

The main grid of screen 1 is made of ceramic pipes 2 and a grid of n / a chrome wire 3 (reinforcement function) on which the refractory fiber 4 is attached. Screen 1 is installed between brick packages 5, on which is supported by ceramic pipes 6. The arrows indicate the direction of movement at the end of the corridor between the packs, the screen forks to form an angle of 110 °. A gap 7 is formed between the screen and the walls of the bag.

Intensification of heat transfer is achieved due to the redistribution of the coolant. Its share, penetrating the load, is increased to 30-40% due to the fact that a heat shield is placed in the corridor between the packages. The design of the latter, splitting it into two branches, creates a support for the coolant, a significant part of it rushes into the gaps between the bricks of the cage. The movement of the coolant along the corridor between the packages is prevented by the divergence of the screen in the form of a dovetail, and the gaps between the cage and the screen do not exceed the maximum gaps in width between the bricks in the cage. The angle between the diverging branches of the screen is taken in front 4

yo to

90-120 °, providing movement of the coolant along the surfaces of the screen without forming zones of stagnation. The screen thickness of the refractory fiber is increased to a thickness sufficient so that the light beam does not penetrate through the screen, eliminating the radiant heat exchange between the packages, which makes it possible to maximize the surface of the screen to heat the charge packages between the radiant heat. The screen, heated by the coolant, radiates heat energy to the package. The effect is based on the fact that the screen is made of a light material and its volumetric heat capacity is much lower than that of a brick, therefore the screen heats up faster. Both the bag and the screen are heated from one coolant, flue gases, and the heat transfer is mainly carried out by conventional means. Convective heat transfer is directly proportional to the surface area to be blown. As the screen heats up faster than the packet, it begins to transfer its heat to the charge by radiant heat exchange. Secondly, the living section of the corridors between the packages for the passage of the coolant is reduced. The heat absorption by the bricks of the package increases due to an increase in the area washed by the coolant. Increasing the heating rate of the brickwork increases the turnover of the furnace, increases its productivity and reduces consumption

process fuel.

Claims (1)

The invention of the device for heating the brickwork mainly in a ring furnace, containing elements for redistributing the coolant flow in the furnace, characterized in that, in order to intensify the heating of the charge and save thermal energy, the elements are made in the form of screens placed along the entire length of the charge in the direction of the heat transfer fluid, of refractory fiber and thickness that eliminates the penetration of light beam through the screen. 1 FIG. Z