RU2524388C1 - Method of producing gas-generating element for low-temperature gas generator - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: method includes preparing a solution of a binding agent in an intermediate solvent, preparing components, mixing the mass, preparing granules with size of 1-1.6 mm from the mass, moulding a weighted portion of the prepared granules with vibration compaction in process equipment or housing of a gas generator, hardening the element in two steps with evacuation at the second step and pressing out the element. The method is characterised by that hardening at the first step is carried out by blowing air or an inert gas whose temperature is 5-10 degrees below the boiling point of the intermediate solvent, with constant flow rate through filters with given gas permeability, mounted on free surfaces of the element, and the body of the element.

EFFECT: invention enables to control the process of forming gas permeability in the body of a gas-generating element in the hardening process in order to improve reproducibility of the parameters thereof while maintaining porosity and strength of the gas-generating element, and temperature of the generated gas during operation of the gas generator at the prototype level.

2 dwg, 1 tbl

Description

The invention relates to applied chemistry, and in particular to a method for manufacturing a gas generating element (HGE) (charge) from solid fuel (gas generating composition) for a low temperature solid fuel gas generator (TTGG). Such gas generators can be used for emergency and special lifting systems for sunken objects, in means of remote emergency blocking of oil and gas pipelines, in means of ejection and spraying of special liquids to neutralize accidental releases of hazardous gases and substances to chemicals, etc. production, emergency actuation of various pneumatic devices, for gas and powder fire extinguishing means, in autonomous sources of gaseous cold oxygen to ensure people's breathing in emergency and extreme situations and in many other areas.

The most promising for such applications are solid fuel gas generators generating cold (with ambient temperature) gases: oxygen, nitrogen, various mixtures of nitrogen, carbon dioxide and vaporous water. A feature of this class of gas generators is that they are all based on the same method of producing cold gases, based on the filtration mode of combustion of porous gas-permeable HGEs made of gas-generating compositions in them (RF patents Nos. 2108282, 2250800, 2302993, 2384589).

One of the main characteristics of these HGEs is porosity (P) and gas permeability, characterized by a gas permeability coefficient (K _g ). These characteristics must have certain values required for each specific low-temperature TSHG, characterized by certain gas-generating composition, filter and equipment design elements, and ensuring its normal functioning.

The scatter of the specified characteristics of the HGE is mainly due to technological factors in the manufacture and significantly affect the scatter of the main indicators of TSHG.

Thus, a decrease in the values of porosity and gas permeability of HGE relative to the required values leads to a decrease in the flow rate of TTGG gas, an increase in its operating time, and an increase in pressure in the head of the combustion chamber, especially in the initial period of operation. The latter circumstance in extreme cases can lead to the transition of filtration combustion to volumetric combustion, accompanied by a pressure jump in the head of the combustion chamber and the possible destruction of the gas generator body.

An increase in the values of the indicated characteristics of the HGE relative to the required values leads to an increase in the consumption of TTGG gas, a decrease in its operating time, an increase in the temperature of the emitted gas, a decrease in the reliability of the ignition of the HGE with a possible failure to activate the gas generator and a decrease in the stability of the filtration mode of combustion of the HGE with the possible unauthorized termination of the TSHG.

In general, variations in the porosity and gas permeability of HGEs lead to a deterioration in the operational characteristics of TSHHs, an increase in their weight and size parameters, a decrease in the reliability and safety of their work, and, consequently, a narrowing of their scope and range of devices based on them.

A known method of manufacturing a porous gas-permeable HGE described in the description of the patent of the Russian Federation No. 2302993 (publ. July 20, 2007), including the preparation of components, mixing the mass, preparation of the mass of granules, molding of granular mass with vibration compaction in technological equipment or the body of the gas generator.

The advantage of this method is that it provides acceptable reproducibility of the average volume of porosity of the produced HGEs, is simple in the implementation of technological processes, does not require unique equipment and the involvement of highly qualified specialists, and is quite safe. The disadvantage of this method is the low reproducibility of the gas permeability of the produced HGE: the value of K _g made in one batch of HGE can vary by 2-3 times. This circumstance, due to the above reasons, makes it difficult and in many cases makes it impossible to use TSHG with such HGE in the fields of application described above.

A known method of manufacturing a porous gas-permeable HGE for TSHH, adopted for the prototype and described in the description of the patent of the Russian Federation No. 2435638 (publ. 10.12.2011), including the preparation of a solution of a binder in an intermediate solvent, the preparation of the components, mixing the mass, preparing granules of size 1 from the mass -1.6 mm, molding with vibration sealing of a sample of prepared granules in technological equipment or a gas generator housing, curing the element in two stages with evacuation in the second stage and pressing out the element.

Its difference from the analogue lies in the fact that in it during the production of HGE, granules of not any, but a certain size (1-1.6 mm) are prepared from the fuel mass. In addition, the curing of HGE in it is carried out in two stages: removing the intermediate solvent in the first stage and curing the product in the second under a small vacuum, and not in one stage in the absence of vacuum.

The prototype method has all the advantages of the above analogue. At the same time, in comparison with it, it provides an increase in the reproducibility of the gas permeability of the produced HGE: the dispersion K _g of the HGE produced by this method in one batch is reduced by 25-30%. However, the prototype method does not significantly increase the reproducibility of gas permeability of HGE to a level acceptable for the use of TSHG based on them in the above applications, and, accordingly, cannot provide a significant increase in the operational characteristics of TSHG, a decrease in their overall dimensions, leads to insufficiently high reliability and safety their work and leads to a narrowing of the range of areas of their application and the range of devices based on them.

The objective of the invention is to provide a method of manufacturing a gas generating element for a low temperature gas generator with improved performance, reduced weight and size parameters, contributing to increased safety and reliability of TSHG and thereby expanding the range of applications and the range of devices based on them by controlling the formation of gas permeability in the body of the gas generating element in the curing operation in terms of improving the reproduction Mosti its parameters while maintaining the temperature of the generated gas TTGG, porosity and strength on GGE prototype level.

The problem is solved by the proposed method of manufacturing a gas generating element for a low temperature gas generator, including preparing a binder solution in an intermediate solvent, preparing the components, mixing the mass, preparing granules 1-1.6 mm in size from the mass, molding with the vibration compaction of a sample of prepared granules in technological equipment or the gas generator body curing the element in two stages with evacuation in the second stage and extruding the element. The peculiarity lies in the fact that curing in the first stage is carried out by blowing with air or an inert gas having a temperature 5-10 degrees lower than the boiling point of the intermediate solvent, with a constant flow rate through filters with a given gas permeability installed on the free surfaces of the element and the body of the element.

The applicant is not known from the prior art the technical solution of the task in which the proposed combination of features would take place.

The proposed method includes the following processes: preparing a solution of the required concentration of a binder suitable for use in low-temperature gas generators (for example, sodium salt of polyvinyltetrazole or, for example, liquid glass (a mixture of potassium and sodium silicates), or, for example, phenol-formaldehyde resin) in the corresponding intermediate (technological ) a solvent (e.g. water or ethyl alcohol or acetone); preparation of components, including drying, grinding and separation of the required fractions of powder components on sieves; mass mixing in accordance with the percentage of components in the composition; preparation from the mass of granules with a size of 1-1.6 mm; molding with vibration sealing of a sample of prepared granules in technological equipment or in a gas generator housing; HGE curing is carried out in two stages, the temperature regime of each of which depends on the type of gas-generating composition, the type of binder in it, on the mass and size of the HGE and is selected empirically for each type of HGE. In practice, when developing specific structures of TTGG and HGE to them, the temperature and time regimes of hardening of HGE can vary in accordance with the properties of the components used.

In the first stage, the process is carried out according to the scheme shown in figure 1. Through the filter 1 with a given gas permeability, mounted on the free end surface 2 of the element 3, located in the technological equipment (or TTGG case) 4, air or inert gas 5 is heated under pressure at a constant flow rate, heated to a temperature of 5-10 degrees below the boiling point intermediate solvent.

Under the action of a pressure drop, air or inert gas 5 propagates through open pores between the granules through the body of the element 3, then through the free surface 6 and a filter 7 mounted on it with a similar gas permeability filter 1 and further into the atmosphere.

The flow of purged air or inert gas during the curing process is evenly distributed over the cross section of the element by passing it through these filters 1 and 7 to improve the uniformity of pore sizes and their distribution over the cross section of the manufactured element. The set value of the gas permeability of the filters 1 and 7 is chosen equal to the desired value of the gas permeability of the element. Static and dynamic forces act on granules located in the pore walls from the side of jets of air or inert gas moving along the pores. At the same time, granules in the places of narrowing of the pores experience the greatest force. Due to the indicated forces, uncured granules in these places are deformed or displaced relative to each other, thus creating a constant passage area over the pore length. At the same time, pore sizes are formed in each section of the element that integrally ensures the gas permeability of the element corresponding to a given flow rate of air or inert gas through this element.

Due to the heat transfer from the heated air or inert gas, the granules are heated and an intermediate solvent gradually evaporates from them. Solvent vapors are picked up by air 5 or inert gas flowing through the pores and with it are carried out through the surface 6 and filter 7 to the outside of the element into the atmosphere (if necessary, through the solvent trap). After evaporation of the solvent, the curing process of the binder begins in the granules themselves and at the contacts between the adjacent granules. In this process, a sufficiently rigid matrix is formed in the element from granules bonded together, providing a certain initial strength of the element and the invariance of the size and distribution over the cross section of the formed pores after the cessation of air or inert gas purging through the element body.

The curing process in the first stage can also be carried out according to the scheme shown in figure 2. In fact, the process according to this scheme is similar to the process according to the scheme in figure 1. Its main difference is that hot air or inert gas is not supplied under pressure through filter 1, surface 2, element body 3 and filter 7, but rather, it and the solvent vapor present in it are pumped out at a constant flow rate through filter 7, body element, surface 1 and filter 2. At the same time, air or an inert gas heated to the above temperature 5-10 degrees below the boiling point of the intermediate solvent is supplied from the side of filter 7.

In the second stage, the final cure of the product is carried out at a temperature of curing the binder under a small vacuum (residual pressure less than 0.9 atm), followed by extrusion of the HGE in the case of using technological equipment.

To illustrate the feasibility of the proposed method in the Table presents examples of the main indicators made by this method of gas generating elements with a diameter of 60 mm and a length of 100 mm, including with the going beyond the scope of the proposed method, and indicators of the prototype. In the manufacture of HGE according to the claimed method, the same gas-generating composition was used (based on sodium azide, lithium fluoride and sodium salt of polyvinyltetrazole), the intermediate technological solvent was water and technological processes (except for the curing process) that were used in the manufacture of HGE by the prototype method. The curing process in the first stage was carried out by blowing heated air through the HGE body with a constant flow rate of 0.5 l / s. The values of the characteristics given in columns 1-5 of the Table are valid for curing both according to scheme 1 and scheme 2, as well as when using both air and inert gas (nitrogen, CO ₂ ).

Table Characteristic Test result Prototype Going beyond The inventive method Going beyond one 2 3 four 5 GGE gas permeability coefficient, K _g · 10 ¹⁰ , m ² 10-12 15-17 16-18 16-18 0.5-2 3-20 Porosity of HGE, P,% 45.3-45.6 45.4-45.7 45.3-45.6 45.2-45.5 45.4-45.6 45.2-45.6 Strength (σ _SJ) GGE, kgf / cm ² 19-23 20-24 19-24 20-23 6-11 13-26 Δt _1st , h 7 3 3 3 1,5 5 Δt _{2nd Class,} B 5 5 5 5 5 5 Tests in TTGG: - P _max , kgf / cm ² 32.4-35.7 30.4-35.6 30.3-34.5 31.2-34.9 97.6-130.5 30.3-79.8 - ΔG / G _cp ,% ± 23 ± 14 ± 13 ± 15 ± 52 ± 56 - Δτ / τ _cf ± 22 ± 14 ± 13 ± 14 ± 51 ± 55 - gas temperature, ° C 39-50 40-55 40-54 42-55 37-110 39-55 Notes: - Δt _1st , Δt _2st , - time spent on the process, respectively, in the first and second stages of curing; - P _max , G _cp , T _cf , ΔG / G _cp , Δτ / T _cp - respectively, the maximum pressure in the head of the gas generator, the average gas flow from the gas generator, the average operating time of the gas generator, the relative dispersion of the gas flow from the gas generator, the relative dispersion of the operating time gas generator when testing a batch of HGE.

Examples 2-4 of the proposed method showed optimal results. All of them show a significantly higher reproducibility of gas permeability of HGE produced by the proposed method, compared with HGE produced by the prototype method: the dispersion of K _g in these examples is 8.5 times lower than the dispersion of this indicator of the HGE of the prototype. At the same time, other main indicators of HGE: porosity and strength remain at the level of HGE made according to the prototype. In addition, in the manufacture of HGE according to the proposed method, the process time in the first stage of curing is reduced 1.7 times while the time of the second stage remains constant. This allows you to increase productivity and reduce energy consumption in the production of HGE.

Due to the obtained effect of improving the reproducibility of gas permeability of HGE, the characteristics of TSHH are significantly increased compared to the use of HGE manufactured by the prototype method: the maximum pressure in the head of the gas generator decreases by about 2 times, the gas flow spread is reduced by a factor of 3.7-4 and working hours of the gas generator. The temperature of the generated TSHG gas remains in the same range as with the use of HGE made according to the prototype. In general, this makes it possible to reduce the weight and size parameters of TTGG, increase the safety and reliability of their work, and thereby expand the scope of their application and the range of devices based on them and solve the problem.

Going beyond the scope of the proposed method leads to a significant deterioration of the main indicators of the manufacturing process and the characteristics of the manufactured HGE. So a decrease of 10 degrees relative to the claimed temperature level of air or inert gas blown through the body of the HGE (example 1) leads to a significant increase (2.3 times) in the process time at the first stage of curing. This circumstance sharply reduces the production capacity of HGE in serial production. An increase in the temperature of the air or inert gas blown through the body of the HGE to the boiling point of the intermediate solvent (Example 5) leads to a significant decrease in the level of gas permeability of the HGE and a significant increase in its dispersion. At the same time, the maximum pressure in the head part of TSHH increases significantly and the scatter of its main characteristics increases with all the negative consequences of these effects indicated above.

It is the combination of the features distinctive from the prototype of the proposed solution with the remaining essential features that made it possible to achieve the above technical result, which cannot be obtained when implementing the invention according to the prototype, and to solve the problem.

The inventive method does not cause difficulties in its implementation in the manufacture of gas generating elements with improved reproducibility of gas permeability. Used a set of actions of the method, the conditions for the implementation of the actions are quite simple and do not require significant energy and material costs. The equipment used in the implementation of the proposed method is manufactured by the industry and is quite affordable. For example, these are the usual and standard vacuum oven cabinets that are widely used in practice, providing a relatively low temperature of the working chamber (up to 150 ° C), sieves with various cell sizes, small-sized ball mills, mixers, vibrating tables and compressors with an electric drive from a conventional 220 V mains, flow meters , gas flow regulators and inert gas cylinders.

The proposed method is experimentally tested in the manufacture of gas generating elements with improved reproducibility of gas permeability. The experiments confirmed the feasibility of the method.

HGEs made in accordance with the claimed method and having various gas generating compositions for producing cold nitrogen, oxygen, and gas mixtures in accordance with the present need were used in testing low-temperature TSHGs. The tests carried out confirmed the efficiency and effectiveness of the HGE.

Claims (1)

A method of manufacturing a gas generating element for a low-temperature gas generator, including preparing a binder solution in an intermediate solvent, preparing the components, mixing the mass, preparing granules 1-1.6 mm in size from the mass, molding with the vibration compaction of a sample of prepared granules in a tooling or gas generator housing, curing the element in two stages with evacuation in the second stage and extrusion of the element, characterized in that the curing in the first stage is carried out by blowing in spirit or inert gas having a temperature of 5-10 degrees below the boiling point of the intermediate solvent with a constant flow rate through filters with a predetermined gas permeability mounted on the free surfaces of the element and the body element.

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