RU2092821C1 - Gear testing flame-retardant coats - Google Patents

Abstract

FIELD: testing equipment. SUBSTANCE: gear has tested specimen, heating chamber, and temperature sensors. Tested specimen is composite, has the form of member of steel structure and is mounted inside working chamber of muffle furnace with the use of holder attached to internal side of door of chamber by means of lining insert. Gear provides for mode of flame action while testing building structures being designed. EFFECT: improved efficiency of evaluation of flame-retardant coats of building structures. 8 cl, 1 dwg

Description

 The invention relates to techniques for flame retardant materials and structures, and is intended to assess the effectiveness of fire protection of building structures.

Known laboratory installations for determining the effectiveness of fire protection of steel structures [1]
The TsNIISK installation is a small fire chamber, in the upper part of which a heated plate is installed.

 The test sample measuring 200x200 mm in plan view is a plate with flame retardant applied on one side. A heat shield is laid on the other side of the plate. The temperature regime in the heating chamber is created by a system of rod electric heaters. Thermocouples measure the temperature in the heating chamber, on the heated and unheated surface of the sample.

The disadvantages of this installation include: the need to design and manufacture a fire chamber, additional installation of equipment and instruments for creating a standard temperature regime in the furnace; heating a plate with a fire retardant coating is possible only on one side (bottom or top), which leads to discrepancies with the test results of elements of metal structures, the cross-section of which is usually double-sided; the installation of an arbitrary heat shield of the unheated surface of the plate violates the balance of the sample when it is heated; the error in measuring the temperature on the surface of the plate is high (up to 60 ^o C) due to the installation of the thermocouple electrodes perpendicular to its surface.

In the installation of the design of VNIIPO (prototype), the principle of the detachability of the fire chamber with the removal of the sample from the source of thermal radiation was used. This setup evaluates the behavior of flame retardants and materials in the vertical position of a plate sample. The size of the metal plate is 140x88x1 mm. Fireproof paint is applied to one side of the plate. The unpainted side of this plate is fixed to the holder with a heating device. A radiation source is a muffle furnace heated to 950 ^o C. A test chamber with a movable holder on a screw shaft is pulled to it [2]
The disadvantages of this installation: it is necessary to design and install a special firing system for laboratory tests; additional manufacturing of a special fire chamber is required for placement inside its sample plate in the presence of a muffle furnace; additional calibration of the device is necessary to obtain a standard temperature regime in the fire chamber; one-sided plate heating; to simulate two-sided heating requires an additional heating device; the sample plate in the fire chamber is located only in a vertical position; the electrodes of the thermocouple attached to the plate are open in the fire chamber and additional insulation from burnout is required; the manufactured laboratory facility is generally cumbersome and difficult to use.

 The aim of the invention is the approximation of testing samples to full-scale for building structures, improving the accuracy of measurements and reproducibility of tests, simplifying the device and reducing test costs.

This goal is achieved by the fact that in a device for testing fire retardant coatings containing a test sample, a heating chamber and temperature sensors, the test sample is made in the form of a steel structure element and is installed inside the working chamber of a heating furnace; the working plates of the sample are connected to the cantilever core of the holder, which in turn is attached to the inner side of the door of the heating chamber by means of a lining insert; to ensure the condition of two-sided heating of the cross section of the element, the working plates of the test sample are connected by the core of the holder on two opposite sides; for the implementation of the condition of one-sided heating of the cross section of a design sample between the core of the holder and the working plates, heat-insulating gaskets are laid; the test sample is installed in the space of the heating chamber in accordance with the design position of the structural element; control thermocouples are located inside the composite sample in the center of the plate surface, and the adjacent part of the thermocouple electrodes to its working junction is located on the isothermal surface of the plate; to increase the contact area of the sensitive element with the control surface of the plate, the working junction of the thermocouple has a thin metal disk with a high coefficient of thermal conductivity; the temperature regime of the standard test of the building structure for fire resistance was created by the appropriate procedure for switching on the adjustment rheostat of the muffle furnace; the degree of heating of the working (outer) surface of the plate (t _ex , ^o C) of the steel structure sample is determined by the dependence:
t _ex = t _in + 15 • δ + (70 / τ) ² ; (one)
where t _{in is the} temperature on the inner (controlled) surface of the plate, ^o C;
δ is the thickness of the working plate, mm;
t test time from the beginning of the fire on the design sample, min.

где a коэффициент температуропроводности сухого материала футеровки, кв•см/ч;
τ время огневых испытаний, ч.The thickness of the sample plate is selected according to the working drawing of the steel structure, within (1 ^o C10) mm. The heat-insulating liner of the door of the heating chamber is cut from a refractory lightweight material, the thickness of the lining is determined by the dependence:

where a is the coefficient of thermal diffusivity of the dry lining material, sq • cm / h;
τ time of fire tests, h

 By attaching the holder to the door of the heating chamber, the design position of the sample in space is ensured: horizontal, vertical or inclined and the corresponding heating of the structure: from above, from below, from the side.

 To reduce the measurement error of the actual degree of heating of the controlled (unheated) surface of the sample due to heat from the ends of the plate, the thermocouple is located in the center of the surface of the working plate at a distance from its edge (end) of at least 5 • d, where d is the plate thickness, mm.

 To reduce the influence of heat removal by the temperature meter on the actual degree of heating of the plate surface, the control thermocouple is located inside the composite sample, while the sensing element and thermocouple electrodes with a length of at least 50 • d (where d is the diameter of the electrode, mm) are located on the isothermal surface of the plate, t. e. parallel to the isotherms of heating the cross section of the sample.

A thin disk for increasing the contact of the thermocouple sensing element with the surface of the plate can be made, for example, of a copper plate; the thickness of the disk is not more than 5 • d _e , the smallest side of a rectangular cross-section (circle diameter) is not less than 20 • d _e , where d _{e is the} diameter of the thermocouple electrode.

The temperature test of the steel structure for fire resistance, regulated by the standard, can be obtained in a heating furnace by pre-heating it with an unloaded chamber to 550 ± 50 ^o C.

 The drawing shows the proposed device, views from the side and top.

 The device is designed to assess the fire protection limit of intumescent paints.

 The device has a heating furnace, a sample holder of a steel structure, devices for measuring and controlling temperature.

 The sample holder has a core 1, surrounded on all sides by an insulation layer of asbestos sheets 2, working plates of sample 3 with a fireproof coating 4, stop angles 5, the door of the fire chamber 6 with handles 7 and lining 8, control thermocouples 9 with a thin copper disk on the working joint 10.

 The working plates were fastened to the sample holder by twisting of nichrome wire 11 with a diameter of at least 1 mm.

 Control thermocouples are located inside the composite sample, between the core of the holder 1 and the working plates 3.

 The working junction of the thermocouple 9 and adjacent electrodes with a diameter of 0.6 mm are located in the isothermal zone, parallel to the isotherms of heating the plate. The length of the thermocouple electrodes in the isothermal zone is 50 mm.

The thickness of the thin copper disk 10 to the working junction of the thermocouple is accepted within (0.3 ^o C0.4) mm, the side of the rectangular section of the disk is 12 mm.

A muffle furnace 12 is adopted as a fire chamber. Dimensions of the working chamber, mm: width 190, height 120, depth 300. The maximum allowable temperature of short-term heating of the furnace is 110 ^o C.

Порядок сборки предложенного устройства следующий: на сердечник 1 держателя устанавливают теплоизоляционные прокладки заданной толщины листы асбеста 2 с контрольными термопарами 9 в центре обогреваемой поверхности, прикрепляют рабочие пластины 3 к сердечнику 1 с помощью скруток 11 из нихромовой проволоки; прикрепляют к сердечнику 1 упорные уголки 5, пропускают электроды термопар через паз в сердечнике держателя и соосно расположенное отверстие в дверце камеры 6 и ее футеровки 8; прикрепляют сердечник 1 упорным уголком к футеровочному вкладышу 8 дверцы; прикрепляют дверцу 6 камеры к футеровочному вкладышу 8, подключают термопары 9 к измерительным приборам (на приведенном чертеже приборы не показаны); производят дополнительную теплоизоляцию торцов сердечника держателя и рабочих пластин 3, затем держатель устанавливают в предварительно разогретую камеру печи 12.The thickness of the lining 8 of the door of the fire chamber 6 when the coefficient of thermal diffusivity of lightweight material a = 7.22 sq. Cm / h and the test duration t 1 h is taken to be

The assembly procedure of the proposed device is as follows: heat-insulating gaskets of a given thickness are installed on the core 1 of the holder asbestos sheets 2 with control thermocouples 9 in the center of the heated surface, the working plates 3 are attached to the core 1 using twists 11 of nichrome wire; attach stop angles 5 to the core 1, pass the thermocouple electrodes through a groove in the core of the holder and a coaxially located hole in the door of the chamber 6 and its lining 8; attach the core 1 with a stop angle to the door liner 8; attach the chamber door 6 to the liner insert 8, connect the thermocouples 9 to the measuring devices (the devices are not shown in the drawing); make additional thermal insulation of the ends of the core of the holder and the working plates 3, then the holder is installed in a preheated chamber of the furnace 12.

 In the case of two-sided heating of the design sample, heat-insulating gaskets 2 are not installed on the core. Otherwise, the assembly order of the sample is the same.

 In a variant test, a fire retardant coating is applied to several working plates of the same size in plan. To replace the working plates of the sample, the twists 11 are cut, new plates 3 with a protective coating are installed, a flame retardant is applied to the ends of the working plates 3 and the core of the holder 1.

 For the criterion characterizing the effectiveness of the fire retardant coating, the time is taken, after which the surface of the building structure protected by it is heated to the maximum temperature (fire protection limit, min).

 During the development of the project and the production of prototypes for testing, the main disadvantages of the above plants for assessing the effectiveness of flame retardant coatings were eliminated.

 Cost savings for the design and manufacture of the test device are obtained due to the fact that a typical muffle furnace is used as a fire chamber. The standard temperature in the working chamber is created by an electric muffle heater.

 The design of the test sample allows heating on one side and on both sides. In this case, it is possible to study the behavior of the fire retardant coating at the ends and in the middle part of the sample.

To protect against thermal damage and increase durability, working junctions and thermocouple electrodes located in the fire chamber are installed inside the composite sample. The thickness of the plates of the composite sample is accepted within (2 ^° C10) mm, the dimensions in the plan are from 50x50 to 150x150 mm. Samples in the main chamber can be installed both horizontally and vertically.

 In general, the proposed device is compact, gives reliable results, easy to manufacture and operate.

 Tests have shown the reliability of the heating device and the possibility of its use to determine the effectiveness of the fire retardant coating.

Claims (9)

1. A device for testing fire retardant coatings, including a sample holder, a test sample, a heating chamber with a temperature controller and temperature sensors, characterized in that the sample holder is made in the form of a cantilever core and is attached to the inside of the door of the heating chamber using a liner, and the test sample made of prefabricated plates of steel structure elements, which are connected to the core of the holder on two opposite sides and are installed in space on the working chamber in accordance with the design position of the structural element, while the working junctions of the control thermocouples are located inside the composite sample in the center of the plate surface, and the part of the thermocouple electrodes adjacent to the working junction is located on the isothermal surface of the sample, the working junction of each thermocouple is equipped with a high-coefficient metal disk thermal conductivity, and the degree of heating of the heated surface of the sample plate in the chamber t _{eκ is} set in accordance with the dependence
t _eκ = t _in + 15 • δ + (70τ) $\genfrac{}{}{0ex}{}{\text{2}}{\text{3}}$
where t _{in is the} temperature on the controlled inner surface of the plate, ^o С;
δ is the thickness of the steel plate, mm;
τ is the test time from the beginning of the fire effect on the design sample, min.  2. The device according to p. 1, characterized in that the plate thickness of the sample element is selected in the range of 1-10 mm 3. The device according to claim 1, characterized in that the lining liner is made of refractory material with a thickness of not less than

where a is the thermal diffusivity of dry material, cm ² / h;
τ is the time of the fire test, h  4. The device according to claim 1, characterized in that for the implementation of the conditions of one-sided heating of a sample of the structure between the core of the holder and the tested samples, thermal insulation pads are laid.  5. The device according to claim 1, characterized in that the core of the holder is installed in the lining of the chamber door at a predetermined design position of the sample in the space of the angle of inclination.  6. The device according to claim 1, characterized in that the thermocouples are located in the center of the surface of the sample plate at a distance of at least five thicknesses from its ribs.  7. The device according to claim 1, characterized in that the thermocouple is placed inside the composite sample, between the core of the holder and the sample plate, and the thermocouple electrodes with a length of at least five ten diameters of the electrodes are placed on the isothermal surface of the plate. 8. The apparatus according to claim 1, characterized in that the thickness of a thin disc of metal with high thermal conductivity is selected 0,5d not more than _e, the side of square cross-section which is at least 20d _e where _e d thermoelectrode diameter.  9. The device according to claim 1, characterized in that the working plates of the sample are attached to the holder by twisting from a nichrome wire with a diameter of 1-2 mm.