RU74818U1 - MODEL SMOKE GENERATOR - Google Patents

Abstract

1. A model smoke generator containing a housing, a nozzle, a charge of a smoke-generating composition placed in the housing cavity with an igniter from a fire-conduit cord passing through the nozzle, and with an end protruding beyond its slice, characterized in that the nozzle and front ends of the housing have the form of mating surfaces - nests with a protruding end of the cord and a protrusion with a recess under the cord, respectively, while at least part of the recess under the cord is made in charge. 2. The model smoke generator according to claim 1, characterized in that the length of the end of the fire-conduit protruding from the nozzle is 0.5-1.0 times the depth of the socket of the nozzle end of the housing. The model smoke generator according to claim 1, characterized in that it is equipped with an electrothermal start-up device made in the form of a fitting with a heating element made of a material with high electrical resistance and a shape of the seating surface identical to the front end of the housing. The model smoke generator according to claim 3, characterized in that the fitting of the electrothermal start-up device is made with additional lateral perforation with the possibility of installing and starting the generator from an additional fire-resistant cord. A model smoke generator according to claims 1 and 2, characterized in that it is equipped with a lid that covers the front end of the housing with the possibility of installing an expelling charge in its cavity with launch from a fire-resistant cord. 6. The model smoke generator according to claim 1, characterized in that an aerosol extinguishing composition is used as the smoke-generating composition of the charge. A model smoke generator according to claims 1 and 6, characterized in that the aerosol extinguishing composition has a pasty state. Model smoke generator

Description

The utility model relates to the toy industry, namely to smoke-generating devices for models of rocket-space and military equipment, and can also be used in technical forms of creativity and children's educational games as a source of a working fluid.

Smoke generators (GD) are known and widely used in the form of smoke bombs [6, 7], hand and barrel grenades [4], tracers [7], etc. for setting smoke curtains, target designation, designating the flight path and creating visual effects on the set films. Common design elements of such generators are a housing with a charge of a smoke-forming composition and an igniter placed in its cavity, a nozzle assembly for the exit of smoke and a device for starting.

The main disadvantage of analog products should be their significant dimensions, masses and operating times, due to the requirements for masking and covering large surfaces with smoke, the absence of restrictions on the surface temperatures of the bodies, toxicity of outgoing gases, and restrictions on shock loads due to the low strength characteristics of pyrotechnic smoke compositions. So, the minimum dimensions of the black smoke bombs [6] are 32.5 mm in diameter and 140 mm in length, the burning times are up to 2 ... 4 minutes.

These shortcomings make the direct use of well-known DGs in games, models and other objects of children's technical creativity unacceptable, the main requirements for which, in addition to the entertainment provided by smoke emission during the operation of the generator, include its safety, and the psychologically acceptable time for imitating the operation of a sample of military equipment - up to 5 ... 15 seconds - and an affordable price.

Closest to the claimed DG in terms of functionality and design is a model rocket engine (MRJ), selected as a prototype. MRD is designed to create a driving force, designate a flight path and disclose a system for saving models of rockets and rocket-planes in technical forms of creativity and sport [3, 8]. A typical MRJ contains a paper case in which a nozzle, an igniter, a fuel charge, a tracer-moderator, and an expulsion charge of a model rescue system are mounted in series. After the end of the march (acceleration) mode of operation of the engine, lasting from 0.5 to 4 seconds for various types of engines, the engine runs for the next 4 ... 7 seconds

in tracer mode, emitting a stream of smoke from the nozzle, i.e. working in a similar mode with the DG. The formal disadvantage of the prototype is its excessive functions for the main engine, the use of high-energy compounds, increased internal pressure and the danger of thermal shock from an expiring high-temperature jet of combustion products.

The aim of the development is to create a safe model DG for developing children's games and technical creativity of young people, simulating the launch, operation of models of aircraft, rocket and military equipment using smoke and noise effects, and also allowing the use of DG as a low-potential source of compressed gas energy for ejection, throwing, moving toys.

The goal in a model DG containing a housing, a nozzle, a charge of a smoke-generating composition placed in the housing cavity with an igniter from a fire-conduit cord passing through the nozzle and with an end protruding beyond its cut is achieved by the fact that the nozzle and front ends of the housing have the form of mating surfaces - nests with the protruding end of the cord and the protrusion with a recess under the cord, respectively, while at least part of the recess under the cord from the front end is made in charge.

Using a unified landing surface allows you to significantly expand the game and developing capabilities of the main engine .. In addition to the possibility of building up several main engines in the axial direction by sequentially connecting (and starting) each other, which increases the total time of smoke formation, the possibility of using the main engine as a moderator for starting the engine with a similar landing surface), simulating the launch of “heavy”, slowly taking off models of launch vehicles, smoke marking of a dangerous launch zone, etc., which AET Entertainment sporting competitions in amateur rocketry.

Further improvements develop the basic idea of creating a DG.

It is proposed in the model DG to limit the length of the end of the fire-conduit protruding from the nozzle to 0.5 - 1.0 of the socket depth of the nozzle end of the body, which provides mechanical protection for the walls of the socket and simplifies sealing during storage by sealing the end of the body with a waterproof film.

It is proposed to equip the main engine with an electrothermal start-up device, made in the form of a fitting with a heating element made of a material with high electrical resistance, mounted in the housing socket. The prototyping of the launch device showed the feasibility of equipping the main engine with simple and cheap disposable devices that are connected to the power supply before starting using the Crocodile type electric clamps known in rocket modeling.

To enable the launching in the field of one or several main diesel engines in a different sequence, it is proposed that the electrothermal start-up fitting of the device be performed with side perforation, which makes it possible to install and start the generator from an additional fire-conducting cord, ignited, for example, by a match.

It is proposed to equip the main building with a lid covering the front end of the housing with the possibility of installing an additional knockout charge in its cavity with launch from a fire-conducting cord. This allows you to create models of aircraft, missiles, rotors, etc., throwing small knock-out charges with limited safe speeds and altitudes. In addition, the simplest scheme of the energy center for throwing is also implemented, which contains the front cover of the main engine with an expelling charge, which mates directly with the starter.

It is proposed to use an aerosol extinguishing composition (AOS) as the smoke-generating composition of the charge. AOC is a fuel composition containing an oxidizing agent, fuel, binder and processing aids, i.e. essentially represents a typical fuel or pyrotechnic composition that produces solid-phase aerosols during combustion, mixtures of non-combustible gaseous substances (nitrogen, carbon dioxide, water vapor, etc.) and condensed compounds, mainly alkaline and / or alkaline-earth metals (oxides, hydroxides, carbonates, bicarbonates, chlorides, etc.) in the form of micron-sized solid particles with high fire extinguishing ability. In addition to effective flame inhibition, AOS forms a finely dispersed, spectacularly effective plume of thick smoke during combustion. The AOS combustion products are non-toxic, do not harm the environment, do not destroy the ozone layer of the atmosphere [2] and are fundamentally safer than smoke compositions.

To ensure the mechanical safety of model hydraulic assemblies, it is proposed to use paste-like AOS, for example, [5]. Such AOS and their charges, due to their viscous-fluid physical state, do not form cracks, do not exfoliate from the walls during the deformation of the bodies, are safe in the event of a drop in HD, lumbago, hammer blows, detonating impulse, heat loads and manifestations of childish pranks. Experience in the design and operation of rocket engines on pasty formulations [1] shows that compensation for thermal expansion is fully ensured by the use of housings made of materials that have linear expansion coefficients comparable to paste, in particular paper. The synergy of pasty AOS, combining fire extinguishing and smoke-forming properties, mechanical and explosion-proof charges, allows us to talk about a qualitatively new level of safety of model DGs, their entertainment and gaming capabilities.

It is proposed to supply the main engine with ejectors - axial or, with the appropriate design of the nozzle bridle of the main engine, - of the radial type. In contrast to the known solution [8] for use

ejector to enhance traction, the ejector of the main engine allows you to weaken the thermal power and acoustic effects of the expiring jets.

A gas turbine with a heat-conducting element and a housing installed along the charge axis and made in the form of a cone expanding toward the nozzle end face is proposed, the top half of which is equal to the arcsine of the ratio of the linear burning velocity of the composition to the local burning velocity of the composition along the charge axis. Intensified heating of the composition adjacent to an element made of copper or aluminum sharply - up to 3 ... 4 times - increases its local burning rate, and along the element acting as a “leader of combustion”, a conical surface of combustion is formed. The essence of the utility model is illustrated in the drawings, where are schematically shown:

figure 1 - General view of the model DG;

figure 2 is an embodiment of a cone-shaped gas cylinder with a charge equipped with a “combustion leader”;

figure 3 is a variant of the layout of the main engine with a radial ejector;

figure 4 is a variant of the layout of the main engine with an axial ejector.

The main engine shown in Fig. 1 contains a housing 1, a charge 2 of AOS, a nozzle assembly consisting of axial 3 and radial nozzles 4 covered by a breakthrough membrane 5, an igniter 6 in the form of a fire-conduit cord passing through the nozzle 3 outward. The housing 1 from the side of the rear end forms a socket, the inner seating surface P of which is identical to the outer landing surface P of the front end. A fitting 7 of an electric heating starting device with electric wires 8 is mounted in the socket, and a front cover 9 with an expelling charge 10 of pressed black powder is mounted on the front end.

The work of the State Duma. When an electric current is supplied through wires 8 to the electric heater of the starting device, the latter ignites the end of the fire-conducting igniter cord 6. As the cord burns, the fire beam passes through the nozzle 3 into the body cavity and ignites the charge 2. The resulting combustion products of the fire-extinguishing aerosol break through the membrane 5 and are pushed out of the socket fitting 7 and expire outward, creating a radial-axial smoke plume. When the leading front of combustion reaches charge 2 of the surface of the axial groove, the fire-resistant cord of the expelling charge 10 and the charge itself are sequentially ignited, pushing the front cover 9 forward.

To perform model throwing without creating a smoke plume, the trigger fitting 7 is mounted directly into the front cover socket 9 with a knockout charge 10, and when using the main gun as a moderator - a simulator of starting the model of a “heavy” launch vehicle, the main gun is mounted in an identical MRD landing socket (not shown in FIG. 1).

In the embodiment shown in FIG. 2, the main engine with a conical housing 11 has a charge installed along the axis of the “combustion leader” 13 made of a material with high thermal conductivity, and the front cover 12 and the socket for installing the launch device fitting that are connected to the housing are made with identical landing surfaces P s equal diameters D and angles "a". The local burning rate of the composition along the “leader of combustion” 13 due to intense heating of the adjacent layer substantially exceeds the linear burning rate, as a result of which a conical surface 14 parallel to the generatrix of the housing 11 is formed along the axis in charge, which ensures maximum thermal protection of the housing.

In Fig.4 shows an embodiment of the DG with a radial ejector 15, and Fig.4 with an ejector 16 of the axial type. The aerosol jets emerging from the nozzles of the housing 1 suck in external air and mix with them, lowering the temperature and speed of the mixture, thereby reducing the thermo-force effect of the jets on surrounding objects.

Based on the stated principles, other decisions similar in concept and constructive design were implemented, aimed at ensuring a higher degree of unification and mass production of main hydraulic engines and confirmed experimentally.

The applicant is a small business. USED SOURCES

1. Avdienko A.A., Balashov A.L., Volkov B.C. and others. Design of propulsion systems for solid and paste-like fuels. -Saratov .: Saratov All-Russian State Aviation Administration of the Missile Forces, 2001.

2. Agafonov V.V., Kopylov V.P. Aerosol fire extinguishing installations. - M .: VNIIPO, 1999.

3. Model rocket engines. Specifications TU 84-795-79.

4. RF patent for PM No. 68117. IPC F 42 V 12/48. Smoke grenade. RU BIMP No. 31-2007.

5. RF patent No. 2075984. IPC A 62 D 1/00. Aerosol-forming extinguishing agent. Bull. 9-97.

6. Platov G.A. Pyrotechnician. The art of making fireworks. - M.: Knizhkin House, Eksmo, 2004. p. 162-169.

7. Shidlovsky A.A. Fundamentals of pyrotechnics. - M.: Mechanical Engineering, 1973. p. 237-254.

8. P. Elstein. The designer of rocket models. Translation from Polish. - M.: Mir, 1978.

Claims (9)

1. A model smoke generator comprising a housing, a nozzle, a charge of a smoke-generating composition placed in the cavity of the housing with an igniter from a fire-conduit cord passing through the nozzle, and with an end protruding beyond its slice, characterized in that the nozzle and front ends of the housing have the form of mating surfaces - nests with a protruding end of the cord and a protrusion with a recess under the cord, respectively, while at least part of the recess under the cord is made in charge. 2. The model smoke generator according to claim 1, characterized in that the length of the end of the fireproof cord protruding from the nozzle is 0.5-1.0 times the depth of the socket of the nozzle end of the housing. 3. The model smoke generator according to claim 1, characterized in that it is equipped with an electrothermal start-up device made in the form of a fitting with a heating element made of a material with high electrical resistance and the shape of the seating surface identical to the front end of the housing. 4. The model smoke generator according to claim 3, characterized in that the fitting of the electrothermal start-up device is made with additional lateral perforation with the possibility of installing and starting the generator from an additional fire-conducting cord. 5. Model smoke generator according to claims 1 and 2, characterized in that it is equipped with a cover that covers the front end of the housing with the possibility of installing an expelling charge in its cavity with launch from a fire-resistant cord. 6. The model smoke generator according to claim 1, characterized in that an aerosol extinguishing composition is used as the smoke-generating composition of the charge. 7. Model smoke generator according to claims 1 and 6, characterized in that the aerosol extinguishing composition has a pasty state. 8. The model smoke generator according to claim 1, characterized in that it is equipped with an ejector. 9. The model smoke generator according to claim 1, characterized in that a heat-conducting element is installed along the charge axis, the casing is made in the form of a cone expanding to the nozzle end face with a vertex half angle equal to the arcsine of the ratio of the linear burning velocity of the composition to the local burning velocity of the composition along the charge axis.