EA018107B1 - Test piece placement stand bed when performing the test at roofing fragment and its base affected by igniter, wind and additional heat radiation - Google Patents

Abstract

The present invention relates to the mount designs for roofing building construction fire tests affected from outside by igniter, wind and heat radiation and it is aimed at providing a capability of model engineering of variants of a roof height and angle and variations of changing of a roof angle in relation to the direction of the air and heat radiation flow to a test piece. A stand bed according to the invention includes a platform with a test piece and calibration unit holders, a frame rigidly connected to supporting poles, at that the platform for a test piece is flexibly connected with the frame in a following manner: with the aim of changing of a roof height the platform is connected with the frame through the platform mid line with the help of a carriage and a mechanism for its displacement on vertical plane, and with the aim of providing a platform angle change for a test piece in relation to the frame with the capability of angle detent at its intermediate values positions the platform for a test piece is connected with the frame by means of two pairs of swing mechanisms, at that the poles are fitted with rollers with break device for horizontal displacement of the stand bed.

Description

The invention relates to the design of installations for fire testing of roofing building structures by combined external fire exposure to an igniter, wind and thermal radiation.

The preliminary European standard is known: 11ν 1187-2002 RgiGuegGaygep / ig Veapvrgisyipd νοη Webseypdep beatey Eeyet νοη aivep; Eeyesye Eavvipd (Test methods for roofing by external fire exposure), including amendment A1: 2005, according to which four test methods are established to determine the fire resistance of the roof (roofing and base under it) to fire. These four methods allow you to evaluate the fire characteristics of the roof under the following loads:

according to method 1 - tests with a load from a source of fire;

according to method 2 - tests with a load from a source of fire and wind;

according to method 3 - tests with a load from a source of fire, wind and additional thermal radiation;

according to method 4 - a two-stage test method using a source of fire exposure, air and thermal radiation.

The specified standard describes the methods, the structure of the installation for fire testing of a fragment of the roof and the requirements for its elements, but does not determine the device of their design.

A well-known installation of Polish production for testing a fragment of a roof and its base on the effect of an igniter, wind and additional heat radiation according to method 3 [1p81ikda ohchist 81apot1vko bo yabasha rokgus basyo \\ usy rob \\ p1u \\\ eshe heh \\ pe1ghhpe) ekrohusr rohagslt) 11ν 1187 - SHEUB 3 / 1n5 (y (and (1) 1 ек 5 5 1 а а ас р.. Ή ή ΐ ΐ \ Ό \ \!!!!!! Ат ат ат... - - Cabot, 2005]. The unit is designed for testing and research, various samples of roofing products, to determine classification of roofing by fire and a thermal effect on the test sample.

In a known installation, all of its constituent elements — a stand for placing a sample, an air supply device, a deflector, and a heat radiator — are mounted on one supporting support frame and represent a rigidly connected single structure. In this case, the stand, including the support with holders for the sample and the calibration element, placed on a support frame abutting against the racks, is in the same plane with the air supply device and is limited in the possibility of independent movement relative to the elements of the test setup.

Therefore, a change in the direction and distance (height) of the impact on the test sample located on the stand is possible only simultaneously with the movement of the air supply device and the heat radiator, which limits the possibility of installation in modeling combinations of destructive effects on the sample during testing, as well as in modeling different angles of inclination (slope) of the roof. In addition, the known installation does not provide changes in the height of the stand and the angle of support with the test specimen (the angle of the roof) in relation to the direction of air supply and thermal radiation to the sample.

An object of the invention is to develop a stand design that expands the capabilities of the installation for testing the roof by external fire in modeling combinations of destructive effects on the sample during testing, providing the possibility of modeling variants of combinations of the height and inclination (slope) of the roof and changing the angle of the roof slope relative to the direction air supply and thermal radiation to the sample.

The achievement of the technical task is ensured by the fact that the stand for placing the sample during testing of a fragment of the roof and its base against the effects of an igniter, wind and additional heat radiation, including a platform with holders for the sample and the calibration element, the frame rigidly connected to the racks, according to the invention differs in that the sample platform is movably connected with the frame as follows: in order to change the height of the roof, through the axis of the platform through the carriage and the mechanism of its movement in tikalnoy plane and to ensure changes in the angle of inclination of the sample platform relative to the frame with the possibility of fixing the angle at positions intermediate values it - by means of the swing mechanism, wherein the strut equipped with wheels with a brake device for horizontally moving the stand.

In addition to the carriage moving mechanism providing height adjustment, the proposed stand contains two pairs of turnbuckle-type turning mechanisms having pairwise different lengths with the possibility of changing it for each mechanism, moreover, a shorter pair of turnbuckles provides height adjustment from the floor of the lower edge of the tested roof sample, and a couple lanyards of greater length provides adjustment of the height of the upper edge of the test specimen, as a result of which the angle of inclination of the roof changes during testing.

A test installation for testing a fragment of a roof and its foundation according to method 3 on the effect of an ignitor, wind and additional thermal radiation consists of a test bench that provides installation of the test sample; air supply devices; a deflector to prevent air flow under the roof; heat emitter to achieve uniform

- 1 018107 distribution of heat flux to the surface of the sample. In this installation, a device for supplying air and a heat radiator are combined into a single design, and the stand is made on a separate frame and is an independent design. Due to this, by means of a stand that provides the installation of the test sample during testing, it is possible to change not only the angle of inclination of the roof slope, but also the height of the sample relative to the heat radiator.

Figure 1 shows the design of the stand; figure 2 is a front view; figure 3 - design of the mechanism for moving the carriage and its connection with the platform.

The main structural element of the stand is the platform 1 for the specimen, which, by means of turning mechanisms 5 of the lanyard type for changing the angle of the roof slope, is movably connected with the frame 2. The turning mechanisms 5 are made in the form of two pairs of lanyards and have pairwise different lengths. A pair of shorter mechanisms 5 is fixed between the support post 3 and the lower edge of the platform 1, and a pair of longer lanyards is fixed between the points in the middle of the platform 1 and frame 2. Each of the lanyards is a structure of two screws 16, on which the opposite thread is applied. The screws are screwed into one of their ends in a specially designed elongated sleeve 15 with threaded holes, the other end of the screw is made in the form of a ring, which is worn on an axis on a platform or frame. Those. the screws are made sliding on the thread relative to the coupling body, which makes it possible to change their length. Due to the different changes in the length of the short and long pairs of turnbuckles screws, different mobility is provided in the vertical plane of both edges of the platform, respectively, of the lower and upper edges of the test specimen mounted on the platform, and thus the possibility of adjusting the angle of the roof slope, which means changing the angle of inclination of the platform from the sample in relation to the external fire exposure, the direction of air and thermal radiation to the sample.

The frame 2 is supported by supporting posts 3, which, in turn, are equipped with wheels 4 with a brake device for horizontal movement on the floor surface with the possibility of fixation. One of the support posts 3 comprises a holder with a carriage 8 with an axis 13 of a platform 1 movably connected to it, with respect to which the angle of inclination of the platform with the sample changes. On the rack 3, with the possibility of vertical movement relative to the rack, a carriage 8 is mounted on the holder with the protrusions of the bracket 9, between which an engagement clutch 10 with an internal thread is placed. The coupling 10 is threadedly connected to the screw 11 with a screw 12 mounted on top of it. The bracket 9 with protrusions connected to the carriage, the coupling 10, the screw 11 and the screw 12 represent a vertical movement mechanism of the carriage 8, this movement through the axis 13 on the carriage holder it is transmitted to the platform 1, due to which the height adjustment of the platform 1 is ensured. On the working surface of the platform 1, holders 6 of the test sample are fixed, including guides for its movement on the surface of the support 1, as well as the gauges 7 element, which is also placed on the support during calibration and testing procedures.

The proposed stand provides the ability to mount the test sample up to 3000x1200 mm in size at an angle to the horizon of 5 to 30 °, while the lower edge (edge) of the sample is located above the floor at a distance of (0.75 ± 0.25) m, i.e. with the possibility of adjustment by means of a carriage movement mechanism from 0.5 to 1.0 m. Holders 6 with guides are located on the surface of the platform 1, taking into account the requirement to ensure testing of the roof so that the material from the surface of the simulated roof sample can freely drain and collapse under fire exposure.

Samples of the tested roof are made rectangular in size 400x1000 mm. They are made by applying building material to a standard base plate, which is used as combustible building materials without a fireproof coating (particleboard with a bulk density (680 ± 50) kg / m ³ and a thickness of (19 ± 2) mm or expanded polystyrene plates (E8P ) with a bulk density (20 ± 5) kg / m ³ and a thickness (50 ± 10) mm);

non-combustible building materials (fiberglass-reinforced calcium silicate boards with a bulk density in the dry state (640 ± 70) kg / m ³ and a thickness of (10 ± 2) mm or mineral fiber boards with a bulk density in the dry state (150 ± 20) kg / m ³ and thickness (50 ± 10) mm). Samples may also be tested on non-standard bearing plates.

After installation of the installation or when changes occur that affect the performance of the installation for testing, calibration of the stand and the entire installation is carried out. To do this, a roofing sample similar to the test is placed in the sample holder 6, then the current air velocity in the direction of the air flow is established with the installation and test setup working.

When calibrating, a sample is usually used, which consists of a conventional chipboard plate with a thickness of (19 ± 2) mm and a bulk density (680 ± 50) kg / m ³ , which has undergone conditioning under normal climatic conditions.

In this case, the sample should be even and have dimensions (400x1000) mm. When calibrated by price

- 2 018107 of the sweeping axis of the sample, the following markings are applied: 80: 100 mm above the lower edge; 8500: 600 mm above the bottom edge; 8850: 950 mm above the bottom edge.

The calibration element must be non-combustible and consists of a smooth, even slab of calcium silicate with a thickness of (12 ± 2) mm, size (1.2x2.0) m and bulk density (870 ± 100) kg / m ³ .

The calibration element is installed on the platform 1 by means of holders 7. Rotating the screw 12 (carriage movement mechanism) sets the height of the platform 1 and the horizon level in the longitudinal and transverse directions, and by changing the position of the couplings 15 of the turnbuckles 5, the platform 1 is given the necessary angle of inclination corresponding to the angle of the roof slope.

Before setting the specimen in the test position (using the guide holders 6), the air flow and heat flow must be adjusted. The sample located on the bench is then brought into the test position. The test begins when the test surface of the sample is in the correct position relative to the heat radiator and the air supply device. In this case, the surface of the sample to be tested shall have the same clearance and height as the surface of the calibration element.

After 2 minutes 30 seconds after the sample has been correctly positioned, the sources of fire are set on fire at the same time and after 30 seconds they are placed on the sample.

Sources of fire are laid in such a way that their center has an interval of 100 to 500 mm from the bottom edge of the sample and is symmetrical to its axis at a distance of 370 mm from each other. Sources of fire exposure are fixed with pieces of wire fixed at the edges of the sample.

The test ends and completely extinguishes the fire as soon as the following phenomena occur:

a) the spread of fire on the underside due to the passage of fire;

b) the test duration was 30 minutes;

c) there is a risk of danger to the testers or imminent danger to the test equipment.

In the installation of the prototype, changing the angle of the stand, the device for supplying air and a heat radiator is possible only at the same time and is interconnected, since all the constituent elements are mounted on one supporting frame and represent a single design. The proposed bench for testing a fragment of the roof and its base against the effects of an igniter, wind and additional thermal radiation according to method 3 provides all changes in the angles and heights of the bench, regardless of other components of the installation for fire tests - a device for supplying air and a heat radiator. Accordingly, expanding the capabilities of the installation for testing the roof in modeling combinations of damaging effects on the sample during testing, providing the possibility of modeling options for combinations of the height of the stand and the slope (slope) of the roof and changing the angle of the slope of the roof relative to the direction of air supply and thermal radiation to the sample is achieved.

Claims (4)

CLAIM 1. A stand for placing a sample when testing a fragment of the roof and its base for the effects of an igniter, wind and additional thermal radiation, including a platform with holders for the sample and a calibration element, a frame rigidly connected to the racks, characterized in that the axis is inserted parallel to the platform in parallel the frame, the platform is mounted on the frame with the possibility of changing its height by means of the carriage associated with the axis of the carriage and the mechanism of its movement in the vertical direction, as well as with the possibility of changing the angle of inclination it platform for the sample relative to the frame and lock it in its positions of intermediate values by a swing mechanism, wherein the strut equipped with wheels with a brake device for horizontally moving the stand. 2. The stand according to claim 1, characterized in that it contains two pairs of turnbuckle-type turning mechanisms having pairwise different lengths with the possibility of changing it for each mechanism, moreover, a shorter pair of turnbuckles provides height adjustment from the floor of the lower edge of the test roof sample, and a pair Lanyards of greater length provide adjustment of the height of the upper edge of the test sample. 3. The stand according to claim 1, characterized in that it allows the installation of the test sample up to 3000x1200 mm in size on the surface of the support at an angle to the horizon from 5 to 30 °, while the lower edge of the sample is adjustable above the floor at a distance of 0 , 5 to 1.0 m. 4. The stand according to claim 1, characterized in that the holders of the test sample, as well as the holders of the calibration element include guides for moving both the test sample and the calibration element on the surface of the platform for testing roofs so that the material from the surface of the sample of the simulated roof could freely flow and collapse under fire.