RU47020U1 - PROTECTIVE SCREEN - Google Patents

Abstract

The utility model relates to protective coating structures and can be used as a protective fence for building structures, as well as a protective coating for metallurgical equipment. The technical task is to increase the heat-shielding properties of the screen. The problem is solved in that the protective screen includes sequentially arranged carrier 1, heat-insulating 2 and refractory layers 3. In this case, the carrier layer 1 is made in the form of a metal sheet, the heat-insulating layer 2 is made in the form of rollers 4 rigidly fixed along the sheet 1 to each other mineral fiber heat-insulating material with a thermal conductivity equal to λ = 0.11-0.13 (Bm / m · K), and the refractory layer 3 is made of fire-resistant glaze deposited on the outer surface of the rollers 4. Moreover, as non-fibrous heat-insulating material used refractory felt of mullite - corundum fiber.

Layers 1, 2, 3 can be made in the form of a protected surface. 2 s.p. f-ly, 2 ill.

Description

The utility model relates to protective coating structures and can be used as a protective fence for building structures, for example, crane beams, as well as a protective coating for metallurgical equipment.

Known protective coating of the steel element, made in the form of a rigidly fixed layer of mineral wool impregnated with cement mixture (see Japanese application No. 3240600 B2 07076891 A, E 04 B 1/94).

The disadvantage of this coating is its low heat-shielding properties due to insufficient heat absorption by a layer of cement mortar and mineral wool, which have a high coefficient of thermal conductivity. In addition, the attachment points of mineral wool to the steel element are additional conductors of the heat flux due to the high thermal conductivity of steel.

The closest analogue is the heat-insulating panel, which includes successive supporting, heat-insulating and refractory layers. In this case, the carrier layer is made in the form of a frame to which anchors are attached around the perimeter, connected to the reinforcement of the refractory layer (see ed. St. USSR No. 554366, E 04 B 1/76).

A disadvantage of the known panel is its low heat-shielding properties due to the fact that the outer refractory layer reflects only a small part of the heat flux, which leads to heating of the layer and, consequently, to a decrease in its absorption capacity. The main part of the energy of the heat flux is perceived by the insulating layer of the panel, which cannot ensure complete absorption of heat due to the high coefficient of thermal conductivity. The carrier layer of the panel also cannot be an obstacle to the heat flux to the protected structure, since it is made in the form of a frame.

The problem solved by the utility model is to increase the heat-shielding properties of the screen.

The problem is solved in that in the known protective screen, including successively bearing, heat-insulating and refractory layers, according to the change, the bearing layer is made in the form of a metal sheet, the heat-insulating layer is made in the form of tightly adjacent to each other rolls of refractory mullito - corundum felt, and the refractory layer is made of fire-resistant glaze deposited on the outer surface of the rollers.

Moreover, the layers are made in the form of a protected surface.

The essence of the utility model is illustrated by drawings, where:

figure 1 shows a protective screen, in a perspective view;

figure 2 is a protective screen made in the form of a crane beam box section, in a perspective view.

The protective screen consists of a sequentially located carrier 1 (1, 2), heat-insulating 2 and refractory 3 layers. In this case, the carrier layer 1 is made of a metal sheet. The heat-insulating layer 2 is made in the form of pre-twisted rollers 4 of refractory mullite - corundum felt rigidly fixed along the metal sheet 1 tightly to each other. Refractory mullite - corundum felt is a mineral fiber thermal insulation material with a thermal conductivity of λ = 0.11 W / (m · K}. Due to this design, the thermal insulation layer 2 becomes more dense with a reduced thermal conductivity, which contributes to maximum heat absorption.

The rigid fixation of the rollers 4 to the metal sheet 1 is carried out, for example, using anchors 5 (Fig.1, 2).

The refractory layer 3 of the protective screen is made of fire-resistant glaze, applied in the form of a continuous coating on the entire outer surface of the rollers 4. Due to the glossy surface, the glaze has a high reflectivity and also absorbency due to its structure.

Layers 1, 2, 3 of the claimed protective screen can be made in the form of a protected surface, for example, a crane beam 6 (figure 2) box section.

The protective screen is made as follows.

On the metal sheet 1 (FIGS. 1, 2), the heat-insulating layer 2 is rigidly fixed, made in the form of twisted rollers 4 from a refractory mullite - corundum felt. The fixing of the rollers 4 is carried out using anchors 5 or any other known connecting elements. The rollers 4 are fixed close to each other, thus forming a dense heat-insulating layer 2 with a low coefficient of thermal conductivity.

Then, on the entire outer surface of the rollers 4, a layer of fire-resistant glaze 3 is applied with a thickness of at least 2 mm.

The protective shield made in this way is attached by any known method to the protected structure. Then the screen is ready to work.

If the protected object has large dimensions, for example, a crane beam 6 (Fig.2), then the layers of the claimed protective screen are made in the shape of the object and can be mounted using the above technology directly on the specified object.

The protective screen works as follows:

The heat flux from the radiation source (not shown in the Fig.) First falls on the refractory layer 3 (Fig.1, 2), made of fireproof glaze. Due to the glossy surface of layer 3, the heat flux is partially reflected from it, and partially absorbed and enters the heat-insulating layer 2.

Layer 2, made in the form of pre-twisted rollers 4 tightly adjacent to each other from refractory mullite - corundum

felt, provides: firstly, an increase in the area of the absorbing surface, and secondly, a decrease in the coefficient of thermal conductivity due to compaction of layer 2. As a result, the heat flux falling on layer 2 is evenly distributed over the cross section of the rollers 4, and along their length, which ensures maximum heat absorption by the layer 2. As a result, the heat layer 1 enters the carrier layer 1, made in the form of a metal sheet, at a temperature much lower than the initial temperature from the radiation source. When the heat flux interacts with the metal sheet 1, the surface of the latter heats up, which leads to the subsequent absorption of part of the thermal energy of the specified flow, and, consequently, to a decrease in its temperature. In addition, the thermal energy from the radiation of the heated sheet will be additionally absorbed by the air gap located between the claimed protective screen and the protected structure, for example a crane beam (see figure 2).

Thus, due to its heat-shielding properties, the inventive screen allows to reduce the heating temperature of the protected surface to the level of normal operating temperature.

Claims (2)

1. A protective screen, comprising successive supporting, heat-insulating and refractory layers, characterized in that the supporting layer is made in the form of a metal sheet, the heat-insulating layer is made in the form of tightly adhering rolls of refractory mullite-corundum felt rigidly adjacent to each other, and the refractory layer is made of fire-resistant glaze deposited on the outer surface of the rollers. 2. The screen according to claim 1, characterized in that the layers are made in the form of a protected surface.