RU2690513C1 - Method for determining explosion-proof height of nitrocellulose powder layer by means of manometric device - Google Patents

Abstract

FIELD: chemistry.SUBSTANCE: invention relates to provision of explosion safety of vehicles at the stage of development of new grades of nitrocellulose powder. Method for determining the explosion-proof height of a layer of nitrocellulose powder for cylindrical and rectangular apparatus includes conducting tests on a manometric unit in a constant-pressure high-pressure vessel of 37 cm, determination by mathematical processing of obtained pressure-time relationship of parameters of their combustion, having the greatest impact on safe and critical height of powder layers, with subsequent obtaining of dependence of explosion-proof and critical height of powder layer in amount of 150–200 g of combustion parameters using semi-closed cylindrical containers with diameters of 100 and 300 mm or rectangular shape with minimum side of 100 and 300 mm without large-scale full-scale tests.EFFECT: method provides explosion-proof operating conditions of process apparatuses of final phases of production: drying, sacking and sealing by excluding transition of combustion into explosion at accidental fires in them.1 cl, 4 tbl

Description

The invention relates to the field of explosion safety in the production of cellulose nitrate powders (hereinafter referred to as powders) in the final phases of their manufacture.

The main task of ensuring explosion safety in case of accidental ignition in flammable industrial premises of category “B” is to create conditions that exclude the transition of combustion into an explosion (PRT).

One of the ways to exclude PGV in the production of powders at the most dangerous phases of production: drying, bagging and closing is to establish the explosion-proof heights of the layers in technological devices, which are determined from the experimental-theoretical dependencies:

where: H - critical or safe height of the powder layer. The critical height is taken as the minimum layer height at which the PRT occurs, and the safe one is the maximum layer height at which the powder burnout occurs;

d is the diameter or smallest side of the apparatus;

A and B are the coefficients determined for a specific grade of gunpowder based on the results of physical modeling in steel semi-closed containers.

The dependence presented is obtained as a result of a series of consecutive tests to determine the critical and safe heights of layers in semi-closed containers with diameters of 100, 300 and 500 mm and a height of 1000 mm and which is included as an integral part in the sectoral methodology for determining the explosion-proof norms for loading gunpowder in buildings of flammable categories "B" [one].

As can be seen from the above, to determine the critical and safe heights of the layers, a large amount of gunpowder, the production of one-time models and special testing ground conditions will be required. This dependence in the present invention is adopted as one of the prototypes.

The closest accepted for the prototype of the present invention is a method for determining the propensity of powdered explosive materials in an explosion in large volumes, including filling a vertically installed pipe with a diameter of at least 400 mm with an explosive material (VM) and on top a bulk inert material (IM) with a mass, exceeding the mass of 1.5 ... 4 times. Then ignite VM in the lower part of the closed pipe and determine the result of the test. The measurements are repeated, increasing the height of the VM and IM layer, until there is an explosion. For the parameter characterizing the tendency to PGV, take the minimum height of the VM layer, providing the initiation of an explosion. VM consumption for the entire series of tests on this method will be within 240 kg. [2].

The disadvantage of the prototype is that to determine the critical and safe heights of the layers will require significant material costs for the manufacture of a large number of powders, models of vehicles and testing in ground conditions.

At the initial stages of the development of new grades of powders, having in their composition expensive and hazardous fillers from explosives and catalysts for the rate of combustion, the process of developing experimental compositions is carried out in laboratory conditions in very small quantities. It is obvious that for testing to determine the critical and safe heights of the layers according to the above methods, the development in the laboratory of gunpowder in the amount of 150 ... 240 kg is unreal. And for the manufacture of gunpowder in pilot plant conditions, established standards are required under which the PRT is excluded in the event of an emergency. There is a vicious circle, which is possible to break using the method proposed below.

The present invention is to create a laboratory-bench method for determining the explosion-proof layer height for cylindrical and rectangular apparatus.

The problem is solved by establishing the relationship between the parameters of burning powders in high-pressure vessels of constant volume (hereinafter vessels) with critical and safe layers of powder in cylindrical containers of semi-closed type (hereinafter referred to as containers).

During the development of new grades of gunpowder accumulated a large database for critical (N _cr) and safe _(without N) Height of layers. It has been established that when calculating these layers in the dependence H = А⋅e ^{B⋅d, the} value of d can be considered as the diameter or the smallest side of a rectangular apparatus; the main condition determining the explosion safety in an apparatus or a room is: H _i <Н _кр and H _i <Н _without . On the basis of this condition, in the proposed method, the most acceptable from the point of view of explosion safety is the concept and designation - explosion-proof height H _explo , i.e. the maximum height of the powder layer at which the PRT does not occur.

In order to determine the possibility of using combustion parameters obtained in high-pressure vessels of constant volume, in order to establish the dependence of _Hcr and H _without diameter on semi-closed vessels, studies have been conducted on a manometric unit consisting of a 37 cm ³ high-pressure vessel, pressure sensor T-6000, Neiva-10000 signal amplifier, computer and printer. The tests were carried out on the most dangerous powders from the point of view of their tendency to transition to combustion in an explosion in tanks with diameters of 100 and 300 mm, i.e. having the smallest heights of critical (explosive) layers in tanks with diameters of 100 and 300 mm. These containers were semi-closed cylindrical vessels made of metal with a welded bottom, which had diameters of 100 and 300 mm, height 1000 mm, wall thickness 2.5 mm. It should be noted that the results of tests to determine the critical and safe heights of the layers of gunpowder in these tanks are taken from reports of previous work.

As a result of manometric tests, dependences of pressure on burning time (pressure-time) for 11 brands of powders with various geometrical sizes were obtained. Further, as a result of mathematical processing of the pressure-time dependence and data on explosion-proof layers, the combustion parameters were obtained, which have the greatest impact on _Hc and H _without :

(dP / dt) _max - the maximum value of the first derivative of pressure over time (pressure build-up rate);

kPa / s; G _max - the maximum value of the function of gas;

1 / kPa⋅s; τ is the estimated value of the ignition delay time, ms;

I _k - full impulse of pressure of powder, kPa ^⋅ s.

Based on the above work for tanks with diameters of 100 and 300 mm, the dependences of the safe and critical heights of the powder layers on these burning parameters are obtained:

It should be emphasized that the testing of the proposed laboratory-bench method required gunpowder in the amount of 150 ... 200 g, which can be manufactured in laboratory conditions.

To verify the reliability of the application of the dependences H _cr and E _without in semi-closed containers on the burning parameters in constant volume vessels (formulas 2 ... 5), field tests were carried out to determine H _cr and H _without in containers with diameters of 100 mm and 300 mm for new types of powders 4 / 1 IPC, 4/1 MPKO-K and 24/7 software-D and regular WU _fl .

For comparison, Table 1 shows the values of _Ncr and H _without , obtained under polygon conditions in tanks with diameters of 100 and 300 mm (experimental), and the values of _Ncr and H _without , obtained by mathematical processing of the parameters of combustion in high-pressure vessels of volume and previously obtained values of explosion-proof heights for a layer of powders (calculated).

Based on the results of the work presented in Table 1, the deviations of the calculated values of the critical and safe heights of the powder layers 4/1 IPC, 4/1 MPCO-K and 24/7 PO-D and VU _fl from their experimental values are calculated. These deviations are presented in table 2.

Analysis of the results presented in Table 2 shows that the deviations of the calculated values from the experimental values do not exceed 4%. This fact confirms once again the possibility of applying formulas 2 ... 5 for determining the critical and safe heights of the layers of gunpowder.

As an example of the application of the developed method, work was carried out to determine the dependence of the explosion-proof height of the layer of sports and hunting powder Snarar 410 on the diameter or the smallest linear size of the model of the apparatus. For this, manometric tests were carried out to determine the parameters of combustion in a high-pressure vessel of constant volume. The test results are presented in table 3.

Critical and safe heights in models of devices with diameters of 100 mm and 300 mm, calculated according to the formulas 2 ... 5, are presented in table 4.

After mathematical processing of the data in Table 4 and dependence 1, the least squares method yielded values for the coefficient A equal to 126.98, for B - 1.81. Then the dependence of the explosion-proof height of the layer of gunpowder Sunar 410 on the diameter or the smallest side of the apparatus will look like:

Using this dependence, it is possible to calculate the explosion-proof layer height for newly developed cellulose nitrate powders and, consequently, the explosion-proof loading of technological devices.

Thus, a laboratory-bench method for determining the explosion-proof height of a layer of cellulose nitrate powders using combustion parameters in constant volume vessels has been developed to establish the explosion-proof loads of devices of the final production phases: drying, bagging and closing. The method allows at the development stage to determine the explosion-proof heights of the layers using small quantities of gunpowder. At the same time, material costs for the manufacture of gunpowder and device models, including testing, are significantly reduced.

LITERATURE

1. The method of “Determining the area of an easy-reset structure (LSK)” and load norms for buildings and structures of category “B”, MOP USSR, 1990.

2. Patent No. 2037814 of July 19, 1995. Method for determining the propensity of powdered explosive materials to go into an explosion in large volumes.

Claims (1)

The method for determining the explosion-proof height of a layer of nitrate cellulose powders for cylindrical and rectangular apparatus, including testing a manometric installation in a high-pressure vessel of constant volume 37 cm ³ , determining, by mathematical processing, the pressure-time dependencies of their combustion parameters that have the greatest effect on the safe and the critical height of the layers of gunpowder, followed by obtaining the dependence of the explosion-proof and critical height of the layer of gunpowder in the amount 150-200 e g from combustion parameters using a semi-cylindrical containers with a diameter of 100 mm and 300 mm or a rectangular shape with the smallest side measuring 100 mm and 300 mm without a large-scale field test.