RU2814877C1 - Method for double-sided high-temperature heating of thin-layer paint coatings (intumescent paints of fire-retardant type) - Google Patents

Abstract

FIELD: various technological processes.

SUBSTANCE: invention relates to quality control of intumescent fire-retardant coatings of metal structures directly on site. Uniqueness of this equipment (device) consists in double-sided heating of the fire-retardant coating, which enables to achieve absolute swelling of the intumescent fire-retardant coating mounted on the metal structure. Proposed design of the device includes: a device of thermal and/or induction-thermal action, which enables to carry out heating of the fire-retardant coating applied to the metal structures from the outside; device which enables to heat the fire-retardant coating applied on the metal structures from the contact side of the coating and the metal structure, by means of local induction heating of the metal structure itself; a compartment for localization of swelling with a scale for estimating swelling coefficient of an intumescent fire-retardant coating.

EFFECT: providing the necessary and sufficient temperatures for absolute swelling and implementation of the natural mechanism of action of the intumescent coating, as well as creation of optimal conditions for absolute swelling of the intumescent fire-retardant coating by the method of double-sided thermal and/or induction-thermal heating to the whole depth for determining the swelling coefficient index with subsequent evaluation of quality of fire-retardant coating mounted on metal structures.

1 cl, 3 dwg

Description

The invention relates to a method and technique for quality control of intumescent (intumescent) fire-retardant coatings on metal structures and can be used to assess the swelling coefficient of intumescent fire-retardant coatings on metal structures directly on site. It is equipment for testing the quality of fire-retardant treatment of metal structures directly on site (field research method) and consists of a method of bilateral heating of fire-retardant type intumescent paints.

Depending on the composition of intumescent paints and the compliance of the coating work performed with the requirements of technical regulations and coating passports, the quality of the fire retardant coating may differ radically in physical and chemical properties and negatively affect the achievement of the required result. The mechanism of fire-retardant intumescent paints consists of repeated swelling (foaming) of the coating, followed by hardening and the formation of foam coke, resistant to high temperatures. 15 minutes after the start of temperature exposure, the supporting metal structures begin to become severely deformed. The purpose of fire-retardant coatings is to protect metal structures from temperature effects resulting from a fire. Given the complex and often heterogeneous structure of fire-retardant coatings, it is impossible to establish a strict correlation between fire-retardant efficiency and the values of other parameters.

At this level of development of science and technology, there is no way to check the quality of fire-retardant intumescent paints directly on site. Currently existing methods are labor-intensive and resource-intensive.

Similar technical solutions are known as methods for determining the quality of fire retardant coating of metal structures:

1) “Method for determining fire retardant efficiency” is regulated by GOST R 53295-2009.

The essence of the method is to select samples of compositions for fire protection of metal structures in an uncured form and check the fire retardant effectiveness of such compositions in accordance with section 6 of GOST R 53295-2009 under thermal influence on the prototype and determining the time from the beginning of thermal exposure to the onset of the limiting state (the sample reaches the temperature at 500°C) prototype. For testing, two identical samples are made in the form of I-section columns 1.7 m long.

2) “Quality control of fire protection work on metal” is regulated by section 6, clause 6.4.3 of GOST R 59637-2021.

The essence of the method is to select samples of compositions for fire protection of metal structures in uncured form and check the quality of the fire retardant compositions used by assessing the heat-insulating properties. One sample is made for testing. A steel plate measuring 600×600×5 mm with a fire protection agent applied to it is used as a sample.

3) “Quality control of fire-retardant work for intumescent fire-retardant coatings” is regulated by section 6, clause 6.5 of GOST R 59637-2021.

The essence of the method is to take samples of fire-retardant coatings from structural fragments and study them in laboratory conditions. To do this, fire retardant coatings applied to metal surfaces are removed down to the ground without touching it. Disks with a diameter of 3-5 mm are cut out from the coating samples in an amount of at least 3 pieces, which are placed on a non-flammable heat-resistant substrate at a distance of at least 10 mm from each other. Next, the swelling coefficient is determined. The swelling of the coating is carried out in a heating cabinet with the sample held at a temperature of 600°C for 5 minutes. The swelling coefficient of the coating is determined as the arithmetic mean of three measurements for a given fire-retardant coating sample.

These methods have a significant drawback, which is the need to take samples of compositions for fire protection of metal structures in an uncured (liquid) form; in this form, samples can be taken only before the coating is applied (mounted) to a metal structure and the actual indicators of the swelling coefficient of the installed coating at the site can be checked with these methods is impossible, and an important disadvantage is the need to conduct research in laboratory conditions, which entails a highly labor-intensive process (research requires special installations, prototypes, and a large amount of time).

The closest analogues, adopted as a prototype, are: A device that allows one to achieve the temperature necessary for swelling of the intumescent fire-retardant coating “Technical Hair Dryer”, for example: “Spets BPV-2000”, designed for heating surfaces for the purpose of removing varnishes and paints, welding plastic, cutting and bending various materials (from linoleum to metal), drying products, etc. Theoretically, it can be used to heat a fire-retardant coating directly on an object with subsequent swelling, because the swelling temperature of an intumescent fire-retardant coating is about 300°C, and the technical characteristics of such hair dryers allow reaching temperatures of 600°C.

The physico-chemical properties of the intumescent fire-retardant coating should ensure the protection of metal elements from heat, and therefore the formation of a protective heat-insulating layer of foam coke occurs. The fire retardant coating swells layer by layer and the swollen surface layers, transformed into foam coke, do not allow heat to pass to subsequent layers and, as a result, absolute swelling does not occur; it can only be achieved after 1-2 hours of exposure to the fire retardant coating with a technical hair dryer.

The common features of the technical solution proposed for patenting and the similar technical solution described above, chosen as the closest analogue, prototype are:

- leads and power wires;

- source of radiant heat;

A device that allows you to achieve the temperature necessary for swelling of the intumescent fire retardant coating from the inside, such as an “Induction heater”, for example: “MIKROSHA-2000”, developed and manufactured by the company “NASH ELECTRONICS”, is used in repair shops and workshops. It is designed to heat metal parts: nuts, bolts, and flat iron surfaces under the influence of an alternating magnetic field in an inductor. Devices of this type can be used to heat a metal structure on which an intumescent fire retardant coating has been applied. MIKROSHA-2000 is capable of heating a metal part to 800°C in 30-40 seconds, which could significantly speed up the research process. The key disadvantage is that when exposed to an alternating magnetic field on a metal structure with a mounted fire-retardant coating, the inner side of the coating (the boundary of contact between the coating and the metal element) will warm up to 800°C, the processes of foam coke formation will begin and, as a result of surface tension and pressure from the inside, cracking of the top layers of the coating. These processes will lead to damage to the fire retardant coating without achieving the required result.

The common features of the technical solution proposed for patenting and the similar technical solution described above, chosen as the closest analogue, prototype are:

- leads and power wires;

- control circuit;

- terminals with bolted connection;

- inductor.

The technical result, which cannot be achieved by any of the technical solutions described above, lies in the totality of providing the temperatures necessary and sufficient for absolute swelling and the implementation of the natural mechanism of action of the intumescent coating.

Taking into account the characteristics and analysis of known technical solutions, we can conclude that none of them contains the entire set of essential features, which made it possible to assert that the technical solution proposed for patenting meets the patentability criteria of “novelty” and “inventive step”.

The purpose of the invention is to create optimal conditions for the absolute swelling of an intumescent fire-retardant coating using the method of double-sided thermal and/or induction-thermal heating to the full depth to determine the swelling coefficient with subsequent assessment of the quality of the fire-retardant coating mounted on a metal structure.

This goal is achieved by the fact that inside the “furnace” (compartment for heat accumulation) (12), there is a rod (17) made of an alloy of metals with a relatively low resistivity and the necessary magnetic permeability, to which eddy currents are directed using an induction heater (10). (Foucault currents), promoting heating of the skin layer (surface layer) (19) with subsequent release of energy in the form of radiant heat (18). As an alternative, a thread with a very high resistivity (nichrome thread) can be used, which makes it possible to achieve the temperature necessary for swelling inside the “oven”. This heat is accumulated inside the “oven” with the neck tightly pressed to the fire-retardant coating (14), resulting in the achievement of the temperature necessary for swelling of the intumescent coating. To achieve absolute swelling of the fire retardant layer, an induction heater (11) is installed at the end of the neck; eddy currents (Foucault currents) are directed to the metal body of the structure (15), as a result of which, by heating the skin layer of the metal structure (20), temperature required for swelling of the intumescent coating on the inside of the coating and minimizing the heat removal effect of the metal structure. Based on the results of absolute swelling of the coating, the swelling coefficient is determined.

When implementing the proposed algorithm to ensure the fire safety of objects with intumescent fire-retardant coatings applied (mounted) to metal structures, the work scheme described above is used, adjusted for some “simplification” and reduction in cost of the equipment used.

When implementing the proposed invention, the availability of actual and immediate quality control of the fire retardant coating directly on site, without sampling, with minimal expenditure of resources and time is ensured.

Thus, this invention allows, due to the emergence (synergy) of existing systems that previously existed independently of each other (induction and thermal heating), to reach a new level of fire protection and thus achieve previously impossible results in ensuring the fire safety of an object.

The device proposed for implementing the method of double-sided high-temperature heating of thin-layer paint coatings (fire-retardant intumescent paints) is illustrated by the following description and drawings, where figure 1 shows the design of the device with the principle of its use, figure 2 shows the view of the rod, and figure 3 shows the principle of temperature influence elements of the device onto a fire retardant coating, which contains:

- 220 V power terminals - 1 and 2, which are a plug;

- power wires - 3 and 4;

- control circuit - 5;

- terminals with bolted connection - 6 and 7;

- inductor - 8 and 9;

- inductor turns - 10 and 11;

- oven (heat chamber) - 12;

- foam coke (expanded fire retardant coating) - 13;

- layer of intumescent paint - 14;

- protected metal structure - 15;

- rod fastening bolt - 16;

- rod - 17;

- heat flow - 18;

- hot skin layer of the rod - 19;

- heated part of the metal structure - 20.

Claims (1)

A method for double-sided high-temperature heating of thin-layer paint coatings of fire-retardant intumescent paints, characterized by the fact that in place of an intumescent fire-retardant coating mounted on a metal structure, its intumescent coefficient is measured using a device that includes two heat sources, one of which exerts a temperature effect on the fire-retardant coating from the outside , and the second inside at the point of contact between the metal structure and the fire-retardant coating, characterized in that for the absolute swelling of the intumescent coating, a system of double-sided thermal and/or induction heating is used.