RU2275614C1 - Outdoor fixed fire-escape and roof rail strength test device and test method - Google Patents

Abstract

FIELD: investigating strength properties of solid materials by application of mechanical stress, particularly to provide fire safety.

SUBSTANCE: device comprises cable with hook connected to the first device end and adapted to connect the cable to one member of structure to be tested. Device also has body on which hauling drum is mounted. The hauling drum is adapted to wind the cable and is provided with transmission mechanism to provide drum rotation. The device comprises two cable guiding rollers installed at different heights and rotated in opposite directions and link pivotally secured to body base by motionless end thereof. Swinging roller, which changes its position in dependence of cable tightening force change, is hinged to movable end of the link. The swinging roller center may perform reciprocal movement along arc of a circle having radius less than distance between circle center and straight line connecting centers of cable guiding rollers. Dynamometer is connected to the link.

EFFECT: extended range of structure loading regimes, increased accuracy of force determination without preliminary device regulation.

4 cl, 6 dwg

Description

This invention relates to techniques that ensure fire safety, and in particular to means for testing the strength of fire ladders installed permanently outside residential, industrial or public buildings, as well as roof fencing of buildings used to ensure the safety of roof work.

The prior art bench for testing the stringers of fire ladders for strength, disclosed in AS SU 127058 A, published on 02/08/1960. The specified stand is intended primarily for testing portable fire escapees and includes a frame equipped with trolleys with rollers through which a tension cable passes, wound on a winch drum. Carts can be extended to the required length. When testing the ladder, after being installed in an inclined position above the frame, it is connected by cables to the hanging rollers through which a tension cable passes, connected to a dynamometer. The specified stand implements the corresponding method of strength tests.

The disadvantage of this stand is the limited scope of its application. In particular, its design does not allow it to be used for testing outdoor stationary fire escape ladders and roof railings. In addition, the device described above, due to its design features, has a relatively small range of the forces exerted by its loading mechanism applied to the test objects, which can be monitored by a dynamometer.

A little closer in essence of the technical solution to the claimed invention is a device for testing stairs, disclosed in A.S. SU 679843 A, published on 08/15/1979, IPC7 G 01 M 5/00. The specified device contains a trolley, sections, loads, a yoke, a hand winch, a connecting element with a block and an eye bolt. In this case, the trolley is made in the form of a platform on wheels and is equipped with a handle. Sections are rigidly fixed on the platform of the cart. The loads are made in the form of plate blocks, equipped with ears, with which they are attached to the load beam with fingers. The fingers have ends fixing them. The specified device implements the corresponding method of strength tests.

However, the device described above has the same disadvantages as the stand according to SU 127058 A. Firstly, as indicated in the description of A.S. SU 679843 A, the device disclosed in it is used exclusively for horizontally located or standing at an angle of 75 ° ladders, which virtually excludes its ability to be used for testing outdoor stationary fire ladders installed to the ground at an angle of about 90 ° and roof fencing. In addition, the device described above, due to its design features, also has a relatively small range of the forces realized by its loading mechanism (not more than 200 kg) applied to the test objects.

As a prototype of the claimed group of inventions can be taken "Device for testing staircases of fire outdoor stationary and roof fencing", as well as its corresponding test methods, disclosed in the description of utility model RU 36733 U1, published March 20, 2004, IPC G 01 N 3 / 00. The specified device contains slings for attaching to the test structure, a basket in which a car camera is placed with the possibility of filling with air, a water tank is placed on the car camera, equipped with a wedge clamp with the possibility of fastening slings at the top, and the water tank contains a ruler graduated in kilograms by weight of water filling the tank, overflow nozzle with the ability to move along the measuring ruler and an opening for supplying and draining water. This device implements appropriate test methods.

However, the disadvantage of this device is the complexity of its design. Since the composition of this device includes such working "elements" as air and water, it is necessary to constantly take measures to ensure the tightness of the respective containers and maintain the required level of water, which evaporates over a certain period of time. Thus, to ensure the required test accuracy, it is necessary to constantly monitor the technical condition of this device.

The technical result from the implementation of the proposed technical solution is to provide a wide range of the forces applied to the test device by the loading mechanism of the claimed device, which can be reliably measured by means of an appropriate measuring device without resorting to preliminary adjustment of the device.

The specified technical result is achieved due to the fact that the structure of the device for testing the strength of external stationary fire ladders and roof fencing, containing a cable with a hook at the end for attaching the cable to one of the elements of the test structure, the housing on which the traction drum of the device for winding is mounted on cable, equipped with gear and lever mechanisms to ensure rotation of the drum, two installed at different heights relative to the base of the housing and rotating in opposite the directions of the roller guide rails, additionally introduced pivotally attached with its fixed end to the base of the wings of the scenes, and a pivoting roller adjusting the tension force of the cable pivotally mounted on the movable end of the link, mounted with its center to translate in an arc along a circle whose radius is less than the distance from the center of the circle to the straight line, on which the centers of the guide rollers of the rollers lie, and the dynamometer connected to the rocker of the swinging roller.

In a preferred embodiment of the proposed device, the swinging roller is set so that, with a cable tension corresponding to the upper measurement limit of the dynamometer, the swinging roller is placed in a position in which a straight line passing through its center and the center of the circle, the arc of which is the trajectory of the center of the swinging roller, perpendicular to the straight line on which the centers of the guide rollers of the cable lie, and with a cable tension force corresponding to half of the upper limit of the dynamometer measurements, ka ayuschiysya roller is placed in a position where its center is located on the same level as the height of the center of the lower cable guide roller relative to the base housing.

The proposed device implements two corresponding test methods.

The first proposed test method for the strength of outdoor stationary fire escape is as follows. A sequential test is carried out on the strength of the fastening to the supporting structure of each individual step of the tested external stationary fire escape and the beam of its fastening to the wall of the building.

In this case, the test of the strength of fastening to the supporting structure of each step of the ladder consists in securing the cable of the test device by means of a hook located on its end and a removable device to ensure the vertical direction of the load on the test step, creating due to the tension of the cable load on the test step with the force value P ₁ = 180 ± 18 kg, then keeping this load for 2 minutes and removing the load.

The test of the strength of fastening to the supporting structure of each of the beams for attaching the stairs to the wall of the building consists in securing the cable of the test device by means of a hook located on its end and a removable device to ensure the vertical direction of the load on the step closest to the test beam close to the bowstring, creating due to tension load cable on the test beam, the value of the force P ₂ which is set in accordance with the formula

P ₂ = [(H · K ₂ ) / (K ₂ · X)] · K ₃ ,

where H is the height of the stairs,

X - the total number of beams with which the staircase is attached to the wall,

K ₁ - coefficient numerically equal to the height in meters of the section of the stairs occupied by one person (firefighter), taken equal to 2.5,

K ₂ - the maximum weight of one person (firefighter), taken equal to 120 kg,

K ₃ - safety factor, taken equal to 1.5, subsequent holding this load for 2 minutes and removing the load.

Based on the results of testing the steps and beams of the staircase fastening to the building wall, a visual inspection of each of the tested steps and stair beams is carried out, and if cracks are found on one of the tested staircase elements, weld rupture in the places of attaching this staircase element to its supporting structure or building wall and / or permanent deformations, the tested stationary fire escape is recognized as not meeting the fire safety requirements and must be repaired if the indicated mechanical violations exist, experienced by a stationary fire escape found to comply with fire safety requirements and is suitable for practical use.

The second proposed method for testing the strength of roof fencing is as follows. A sequential strength test of the fastening to the supporting structure of each individual railing of the roof fence is carried out.

The test of the strength of fastening to the load-bearing structure of each of the roof railing railings consists in securing the cable of the test device by means of a hook located at its end to the bottom of the railings to be tested, creating a load on the railings with the force value P ₃ = 100 ± 20 kg, due to the cable tension maintaining this load for 2 minutes and removing the load.

Based on the test results, the roof railing periline conducts a visual inspection of each of the rails tested, and if cracks are found on one of the railing rails, the weld seams in the places of its attachment to the load-bearing structure of the roof railing and / or residual deformations, the roof railing under test is recognized as not meeting fire requirements safety and to be repaired, if the indicated mechanical violations are absent, the tested roof guard is recognized as meeting fire safety requirements and suitable for practical use.

The essence of the proposed invention is illustrated by the following drawings.

1 shows a top view of a test device.

Figure 2 shows a schematic side view of the test device.

Figure 3 shows a diagram of testing using a removable device to ensure the vertical direction of the load on the test step of the ladder (front view).

Figure 4 shows a diagram of tests using a removable device to ensure the vertical direction of the load on the test step of the ladder (side view).

Figure 5 shows a diagram of testing using a removable device to ensure the vertical direction of the load on the test beam stairs (front view).

Fig.6 shows a diagram of testing using a removable device to ensure the vertical direction of the load on the test beam of the stairs (side view).

The proposed device is technically implemented as follows.

In the housing 1, a traction drum 2 is installed for winding the cable 3 fixed on it with a hook 4 at the end. The specified hook 4 is intended for fastening the cable to one of the elements of the test fire escape or roof fencing. Traction drum 2 is equipped with gear 5 and lever 6 mechanisms to ensure its rotation. In the inner cavity of the housing 1, two guide rollers 3 of the roller 7 are rotated in opposite directions and are located at different heights relative to the base of the housing 1. The centers of the guide cable 3 of the roller 7 are fixed relative to the base of the housing 1. At the base of the housing 1, the link is pivotally fixed with its fixed end 8, and on its movable end the swinging roller 9 is pivotally fixed, which makes it possible to measure the tension force of the cable 3. The swinging roller 9 rotates in the same direction as the lower guides cable 3 roller 7. In this case, the swinging roller is installed at such a distance from the fixing point of the fixed end of the link 8 that its center translates along an arc of a circle whose radius is less than the distance from the center of the circle to the straight line on which the centers of the cable guide 3 rollers lie 7 (see figure 2). The connecting rod 8 is connected to the stem of the dynamometer 10.

In a preferred embodiment of the device according to the invention, the swing roller 9 is set so that with a cable tension of 3 corresponding to the upper measurement limit of the dynamometer 10 (for a typical design of the proposed device, the upper measurement limit is 500 kg), the swing roller 9 occupies a position in which a straight, passing through its center and the center of the circle, the arc of which is the trajectory of the center of the swinging roller 9, is perpendicular to the straight line on which lie the centers of the guide ropes 3, rollers 7, and when the tension of the cable 3, corresponding to half of the upper limit of measurement of the dynamometer 10, the swinging roller 9 occupies a position in which its center is located at the same level with the center of the lower guide cable 3 of the roller 7 relative to the base of the housing 1. Two extreme possible position of the wings 8 and, respectively, fixed on its movable end of the swinging roller 9 are shown by the dotted line in figure 2.

The proposed device operates as follows and at the same time implements the following two test methods.

Before starting the test, the test device is installed on the ground approximately under the tested external stationary fire escape. To increase the holding force of adhesion of the test device to the ground, it can be fixed, for example, using special crutches driven into the ground. The cable 3 is fixed using hook 4 on one of the elements of the tested structure, for example, on step 11 of the tested ladder. In addition to the hook 4, a removable device is also attached to the end of the cable 3 to ensure the vertical direction of the load 12.

After that, by means of lever 6 and gear 5 of the device mechanisms, the traction drum 2 is rotated, thereby winding the cable 3 on it and creating a force applied to the test step 11 of the ladder. The cable 3, pulling, exerts a force on the swinging roller 9, directed approximately perpendicular to the straight line, on which lie the centers of the guide cable 3 of the rollers 7. Moreover, since the movable end of the link 8 and the swinging roller 9 mounted on it can only move along an arc of a circle, the center of which lies in the place of fixing the fixed end of the wings 8 to the base of the housing 1 (see figure 2), its movement will be carried out only due to the projection of the tension force of the cable 3 on a straight line, approximately coinciding with the straight line, on the cat The centers of the cable guide 3 of the rollers 7 lie.

Moreover, upon reaching the tension of the cable 3, which corresponds to half of the upper measurement limit of the dynamometer 10 (for a typical design of the proposed device, this value is 250 kg), the swinging roller 9 will occupy a position at which its center will be located at the same level in height with the center of the lower the guide cable 3 of the roller 7 relative to the base of the housing 1. And upon reaching the pulling force of the cable 3, corresponding to the upper measurement limit of the dynamometer 10 (as mentioned above, for a typical design of the proposed about the device, the upper limit of measurements is 500 kg), the swinging roller 9 will occupy a position in which the straight line passing through its center and the center of the circle, the arc of which is the path of the center of the swinging roller 9, is perpendicular to the straight line on which the centers of the guide cables 3 of the rollers 7 lie A similar design feature of the proposed device makes it possible to effectively use virtually the entire range of loads specified in accordance with the test program as the measuring range of dynamometer 10 (see figure 2).

Moving in the angular direction, the link 8 acts on the stem of the dynamometer 10, thereby changing its readings. The scale of the dynamometer 10 is graduated in accordance with the tension of the cable. Thus, using the dynamometer 10, it is easy to track the magnitude of the load applied to one or another element of the test structure.

The fact that the center of the swinging roller 9 makes translational motion along an arc of a circle whose radius is less than the distance from the center of the circle to the straight line on which the centers of the guide cable 3 of the rollers 7 lie is significant from the position that, if the swinging roller 9 is properly fixed, in any position, reliable mechanical contact will be ensured for the working surface of the swinging roller 9 with the cable 3 creating a force on the structures under test (cable 3 will not be stretched between the roller cable guides 7 without bending it over the working surface of the swinging roller 9), and therefore, it will be possible to reliably measure the loads realized by the device in its entire working range of loads.

The test process itself consists in a sequential test of the strength of the fastening to the supporting structure (for an external stationary fire escape - this is its bowstring) of each individual step of the test ladder and the beam of its fastening to the building wall, as well as the roof railing of the roof guard. Moreover, the test for the strength of attachment to the supporting structure of each of the steps of the ladder is that

- fix the cable 3 of the test device by means of a hook 4 located at its end and a removable device to ensure the vertical direction of the load 12 to the test stage 11,

- create due to the tension of the cable 3 loads on the test stage 11 with a force value of P ₁ = 180 ± 18 kg,

- withstand this load for 2 minutes,

- relieve the load.

Then proceed to the test of the next stage.

The strength test of the fastening to the supporting structure of each of the beams of the staircase to the wall of the building is that

- fix the cable 3 of the test device by means of a hook 4 located at its end and a removable device to ensure the vertical direction of the load 12 on the closest step 11 to the test beam 13, close to the bowstring,

- create due to the tension of the cable 3 loads on the test beam 13, the magnitude of the force P ₂ which is set in accordance with the formula

P ₂ = [(H · K ₂ ) / (K ₁ · X)] · K ₃ ,

where H is the height of the stairs,

X - the total number of beams with which the staircase is attached to the wall,

K ₁ - coefficient numerically equal to the height in meters of the section of the stairs occupied by one person (firefighter), taken equal to 2.5,

K ₂ - the maximum weight of one person (firefighter), taken equal to 120 kg,

K ₃ - safety factor, taken equal to 1.5,

- withstand this load for 2 minutes,

- relieve the load.

Then proceed to the test of the next beam.

After these stages of the test, a visual inspection of each of the test steps of the staircase and the beams of its fastening to the wall of the building is carried out, and if cracks are found on one of the tested staircase elements, weld rupture in the places of fastening of this staircase element to its supporting structure or building wall and / or permanent deformations, the tested stationary fire escape is recognized as not meeting the fire safety requirements and must be repaired, if the indicated mechanical failures are absent, the test aemaya stationary fire escape found to comply with fire safety requirements and is suitable for practical use.

The test of the strength of fastening to the supporting structure of each of the railing of the roof fence is that

- fix the cable 3 of the test device by means of a hook located at its end and to the bottom of the tested railing (not shown),

- create due to the tension of the cable 3 loads on the tested railing with a force value of P ₃ = 100 ± 20 kg,

- withstand this load for 2 minutes,

- relieve the load.

Then proceed to the test of the next railing.

At the end of the described test stage, a visual inspection of each of the tested roof rails is carried out, and if cracks are found on one of the roof rails tested, welds rupture in the places of its attachment to the supporting structure of the roof fence and / or residual deformations, the tested roof fence is recognized as not meeting the requirements fire safety and to be repaired, if the indicated mechanical violations are absent, the tested roof guard is recognized as meeting the fire safety requirements Suitable for practical use.

The test plan for the roof railing periline can be easily reproduced on the basis of the information set forth in the above description section, and therefore is not shown in the drawings.

In some cases, the actual load exerted on the external stationary fire escape can be several times higher than the loads realized during the implementation of the above test method. For example, several firefighters (rescuers of the Ministry of Emergencies) can be on the stairs at once and a seriously injured person will be evacuated by them. In this case, the load exerted on the step or on the beam securing the stairs to the wall can reach about 500 kg. In order to ensure the possibility of using the proposed device for such tests, it is technically implemented so that its power mechanism implements test loads in the range from 0 to 500 kg inclusive. In the indicated range of the realized loads, the possibility of their reliable measurement using a dynamometer is provided.

All the above numerical values of the loads on the elements of the tested structures and the associated coefficients are given on the basis of empirical studies, taking into account the real weight of the average firefighter dressed in full protective ammunition, in order to bring the above methodology in accordance with fire safety standards, in particular, airbag 245 -97 "Outdoor fixed fire stairs and roof fencing."

The use of the proposed device and the methods it implements can dramatically increase the level of technical safety for employees of fire departments during firefighting of buildings, as well as rescuers of the Ministry of Emergency Situations or employees of REU, respectively, carrying out work on the roof of buildings in case of an emergency or roof repair, etc.

Claims (4)

1. A device for testing the strength of outdoor fire escape stairs and roof fences, characterized in that it contains a cable with a hook at the end for attaching the cable to one of the elements of the test structure, a housing on which a traction drum is mounted for winding the cable on it, equipped with transmission and lever mechanisms to ensure rotation of the drum, two mounted at different heights relative to the base of the housing and rotating in opposite directions of the guide wire of the roller, pivotally attached swinging roller mounted with its fixed end to the base of the body of the wings, pivotally pivotally mounted on the movable end of the wings and changing its position depending on the tension force of the cable, installed with its center to translate along an arc of a circle whose radius is less than the distance from the center of the circle to the straight line, on which lie the centers of the cable guide rollers, and the dynamometer connected to the wings. 2. The device according to claim 1, characterized in that the swinging roller is mounted so that, with a cable pulling force corresponding to the upper measurement limit of the dynamometer, the swinging roller is placed in a position in which a straight line passing through its center and the center of the circle, the arc of which is the path of the center of the swinging roller, perpendicular to the straight line on which the centers of the guide rollers of the cable lie, and when the tension of the cable is applied to the corresponding half of the upper measuring limit of the dynamometer, the swinging roller is placed in the floor voltage at which its center is located on the same level as the height of the center of the lower cable guide roller relative to the base housing. 3. The method of testing the strength of external stationary fire ladders, which consists in a sequential test of the strength of fastening to the supporting structure of each individual step of the tested external stationary fire ladder and the beam of its fastening to the wall of the building, while testing the strength of fastening to the supporting structure of each of the steps of the ladder consists in securing the cable of the test device by means of a hook located on its end and a removable device to provide a vertical direction Ia load at a test stage, the establishment by the tension load on the cable a test step with the magnitude of force P ₁ = 180 ± 18 kg, subsequently maintaining a given load for 2 min, and the load is removed; Testing the strength of the fastening to the supporting structure of each of the beams for attaching the stairs to the wall of the building consists in securing the cable of the test device by means of a hook located on its end and a removable device to ensure the vertical direction of the load on the step closest to the test beam close to the bowstring, creating due to tension load cable on the test beam, the value of the force P ₂ which is set in accordance with the formula P ₂ = [(H · K ₂ ) / (K ₁ · X)] · K ₃ , where H is the height of the stairs; X - the total number of beams with which the staircase is attached to the wall; K ₁ - coefficient numerically equal to the height in meters of the section of the stairs occupied by one person (firefighter), taken equal to 2.5; K ₂ - the maximum weight of one person (firefighter), taken equal to 120 kg; K ₃ - safety factor, taken equal to 1.5, the subsequent holding of this load for 2 minutes and unloading, moreover, according to the results of testing the steps and beams of the staircase mounting to the building wall, a visual inspection of each of the tested steps and stair beams is carried out and if cracks are found on one of the tested staircase elements, weld seams are broken in the places of the fastening of this staircase element to its supporting structure or building wall and / or permanent deformations, the tested stationary fire escape is recognized as not meeting the fire safety requirements and must be repaired, if the indicated mechanical violations missing, the felt by a stationary fire escape found to comply with fire safety requirements and is suitable for practical use. 4. The method of testing the strength of roof railings, which consists in sequentially testing the strength of the fastening to the supporting structure of each individual railing of the roof railing, testing the strength of the fastening to the supporting structure of each railing of the roof railing is to fasten the cable of the test device through the hook located on its end to the lower part of the test railing, creating due to the tension of the cable load on the test railing with a force value of P ₂ = 100 ± 20 kg, then keeping this load for 2 min, removing the load, and according to the results of testing the roof railing periline, a visual inspection of each of the railing rails is carried out and if cracks are found on one of the railing rails, rupture of welds in the places of its attachment to the supporting structure of the roof railing and / or of residual deformations, the tested roof guard shall be recognized as not meeting the fire safety requirements and to be repaired, if these mechanical violations are absent, I acknowledge the tested roof guard meet the fire safety requirements and suitable for practical use.

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