RU171965U1 - PULSE REACTIVE MICRO-MOTOR - Google Patents

Abstract

The utility model relates to auxiliary devices of rocket technology for correcting the trajectory of movement, in particular for gyroscopic stabilization by twisting the main product around the longitudinal axis, and can be used as a gas generator for boosting airbags, rescue aircraft ramps and rafts. The pulse jet micromotor contains a functional solid fuel charge of parallel channel blocks mounted in a combustion chamber with gas ducts communicating with the receiver, which is equipped with an outlet nozzle, and blocked by rigidly connected ignition and outlet diaphragms, while under the ignition diaphragm there is an amplifying pyrotechnic charge initiated by a central electric igniter mounted in a lid equipped with a confuser. It is new that the outlet nozzle is tangentially rotated relative to the longitudinal axis of the combustion chamber, the ignition diaphragm mounted movably relative to the cap confuser, and an amplifying pyrotechnic charge is made in the form of conformal tablets fixed to the end x channel blocks adjacent to each other and inscribed in the cross section of the combustion chamber, while the tablets have an open surface developed by means of radial grooves. The proposed technical solution provided ample opportunity to adapt the compact micromotor in the cramped volumes of the main product, initiated by various standard electric igniters, which makes it universal increased performance.

Description

The utility model relates to auxiliary devices of rocket technology for correcting the trajectory of movement, in particular for gyroscopic stabilization by twisting the main product around the longitudinal axis, and can be used as a gas generator for boosting airbags, rescue aircraft ramps and rafts.

The level of this technical field is characterized by the design of the dynamic generation of solid propellant drafts of gases generated by combustion, which are ejected by the nozzle in a directed flow for targeted use (see I. Gladkov, Yu.P. Ermakov, etc. Pulse-type solid-fuel special-purpose engines. - M .: TsNIIinform, 1990, p. 104).

The specified design is a micromotor of the correction of the trajectory and spin of the aircraft with the aim of its gyroscopic stabilization in autonomous flight.

This direct-flow jet micromotor, oriented at an angle to the direction of movement, contains a solid-fuel channel block placed in a cylindrical housing covered with a heat-protective layer.

At the ends of the casing, a holder of an electric igniter of an amplifying pyrotechnic charge and a nozzle cover are separated from the functional checker by a receiver, where the generated gaseous products of combustion are accumulated, jetted out through a coaxial nozzle.

The channel checker on the outer surface has three longitudinal ridges forming gas ducts with an adjacent housing to the receiver and further to the exhaust nozzle.

The disadvantage of the described micromotor is the relatively long burning time of a single-channel solid fuel checker having an undeveloped surface, with the inertia of its ignition by the thermal energy of a remote amplifying pyrotechnic charge.

The noted drawback is eliminated in the design of a solid fuel jet engine according to the patent RU 2133371 C1, F02K 9/24, 1999, which is selected as the closest analogue to the proposed micromotor due to the technical nature and the number of matching features.

Known pulsed micromotor includes a combustion chamber with a functional charge in the form of a block of channel powder checkers mounted between the ignition and output diaphragms, while under the ignition diaphragm, made in the form of a confuser, mounted on the cover of the combustion chamber, there is an amplifying pyrotechnic charge adjacent directly to the ends of the channel checkers.

An amplifying pyrotechnic charge is initiated from a central electric igniter mounted in the cover of the combustion chamber, on the other end of which exhaust nozzles are mounted.

A monoblock of a multi-cup functional charge is formed by a rigid connection of the ignition and output diaphragms with a shell located in the combustion chamber with a gap forming an annular gas duct to the receiver, where the generated gases are mixed, and the temperature and pressure are equalized.

The receiver communicates with exhaust nozzles at the bottom of the structure.

A continuation of the noted advantages of the known pulsed micromotor are inherent disadvantages.

The axial arrangement of the exhaust nozzles complicates the lateral placement of the micromotor in the dimensions of the main product due to the lack of free volume, which limits the use in aircraft.

The ignition of channel blocks over the entire developed surface is inhibited by the fact that the functional charge is blocked by an amplifying pyrotechnic charge.

In addition, the limited free volume of the confuser, rigidly fixed to the cover of the combustion chamber, does not allow the use of electric igniters of different capacities.

The technical problem, the solution of which the present utility model is aimed at, is the expansion of the technological capabilities of a high-speed pulse jet micromotor of universal application.

The required technical result is achieved by the fact that in a known pulsed jet micromotor containing a functional solid fuel charge of parallel channel blocks mounted in a combustion chamber with gas ducts communicating with a receiver, which is equipped with an exhaust nozzle, and covered by rigidly connected ignition and output diaphragms, while under the ignition the diaphragm is an amplifying pyrotechnic charge initiated by a central electric igniter mounted in a lid equipped with a confuser, according to According to the authors, the exhaust nozzle is tangentially rotated relative to the longitudinal axis of the combustion chamber, the ignition diaphragm is mounted movably relative to the lid confuser, and the amplifying pyrotechnic charge is made in the form of conformal tablets mounted on the ends of the channel blocks adjacent to each other and inscribed in the cross section of the combustion chamber, tablets have an open surface developed by means of radial flutes.

Distinctive features of the proposed technical solution provided ample opportunities for adaptation of a compact micromotor in the cramped volumes of the main product, initiated by various standard electric igniters, which creates versatility with increased speed.

The tangential placement of the exhaust nozzle relative to the combustion chamber creates a structural miniaturization of the jet micromotor, suitable for placement in the dimensions of the aircraft in order to correct the flight path of the apparatus or its gyroscopic longitudinal stabilization.

The installation of the ignition diaphragm in the cover of the combustion chamber with the possibility of longitudinal relative displacements is necessary to balance the pressure of the initiating pulse of hot gases from the electric igniter, which allows the use of different standard types of initiators to create a calibrated back-up on the diaphragm and, therefore, a given gas-dynamic regime of flow around the flame over the entire developed solid-fuel ignition surface charge.

The threaded connection of the ignition diaphragm with the cover of the combustion chamber allows you to choose the optimal geometric location of the fuel monoblock in it and relative to the receiver.

The installation of the ignition diaphragm in the cover of the combustion chamber with the possibility of relative longitudinal movements provides balancing by changing the volume between them, adequate to the power of the replaceable electric igniter, thereby expanding the range of standard initiators used.

The fastening of the channel checkers adjacent to each other and inscribed in the cross section of the combustion chamber in a monoblock by means of end diaphragms connected by threaded couplers leaves the burning surface of the functional charge open, which increases the speed of the device for its intended purpose.

The support of the checkers of the functional charge on the tie brackets of the end diaphragms forms an autonomous fuel monoblock, in which unauthorized radial displacement of the checkers due to the circumferential forces of rotation of the micromotor in flight is prevented.

Pressing a conformal amplifying charge directly to the end of the channel checkers increases the speed by reducing the fire chain and increases the functional reliability of the pulsed micromotor.

Performing on the open surface of the tablets an intensifying charge of radial corrugations, develops a contact surface with the igniter force and distributes flame flows to the periphery of the functional charge in a distributed manner to enhance the fire pulse of instantaneous ignition of it over the entire combustion surface, which increases the dynamics of gas generation.

Therefore, each essential feature is necessary, and their combination is sufficient to achieve a novelty of quality that is not inherent in the signs of disunity, that is, the technical problem posed in the invention is not solved by the sum of the effects, but by a new super-effect of the sum of the attributes.

The essence of the proposed utility model is illustrated by the drawing, which has a purely illustrative purpose and does not limit the scope of the claims of the totality of the features of the formula.

The drawing shows:

in FIG. 1 - General view of the proposed device;

in FIG. 2 is a section along AA in FIG. 1;

in FIG. 3 is a top view of a checker functional charge;

in FIG. 4 is a section along BB in FIG. 3.

The pulsed jet micromotor contains (Fig. 1) a solid fuel block of channel checkers 1, at the ends fixed by the ignition and outlet diaphragms 2 and 3, respectively, which are rigidly connected to each other by means of threaded couplers 4 (Fig. 2).

Channel checkers 1, adjacent to each other, are inscribed in the cross section of the combustion chamber 5 and radially rely on the couplers 4 from arbitrary movement.

A feature of the fuel channel checkers 1 is that reinforcing tablets 6 of the heat-sensitive pyrotechnic composition (see Fig. 4) are pressed on the upper side of the ignition diaphragm 2 on the upper side of the drawing, which repeat the transverse profile of the channel checkers 1, i.e., conformal.

The open end face of the reinforcing tablets 6 is equipped with radial flutes 7 (Figs. 3 and 4), developing their ignition surface and along which the force of fire is directed to the periphery of the checkers 1, activating their burning across the entire surface.

The ignition diaphragm 2 (Fig. 1) is threadedly movably connected to the cover 8 of the combustion chamber 5, forming a free volume in the form of a confuser 9, directed to the periphery of the fuel blocks 1.

In the lid 8, a central electric igniter 10 is fixed.

The combustion chamber 5 is equipped with a tangentially located exhaust nozzle 11, which is in communication with the bottom receiver 12.

In official circulation, the nozzle 11 is blocked by a burning membrane 13.

On the combustion chamber 5, a support flange 13 is made for mounting the pulse micromotor in the main product.

The proposed pulsed jet micromotor operates as follows.

An electric igniter 10 is triggered from an external control signal, the fire force of which through the confuser 9 and the windows of the ignition diaphragm 2 is distributed to the amplification tablets 6.

Sensitive to thermal energy, the pyrotechnic composition of the tablets 6 ignites and actively burns, igniting the adjacent channel pieces 1, which burn over the entire developed surface, ignited by the force of the initiator flame 10, penetrating through their axial channel, the confuser 9 and the windows of the diaphragm 2.

In addition to the thermal energy of the force of the flame from the electric igniter 10, hot combustion products along the end of the pellets 6 are distributed along the radial corrugations to the periphery, where the pieces 1 are ignited from the outside, stabilizing their burning rate.

When burning checkers 1 over a developed surface, a large number of gaseous products are generated, which through the output diaphragm 3 enter the receiver 12, where they are mixed, equalizing pressure and temperature. The increased gas pressure in the receiver 12 dampens the pulsation of the jet supply of generated gases from the combustion chamber 5 and increases the burning rate of the functional charge in it.

In this case, the specific gas flow through the nozzle 11 sharply increases, which, when the membrane 13 is burned, commutes with the working capacity of the pressurization (airbag, liferaft or air raft).

In the case of using the proposed device as steering micromotors, the jet from the nozzle 11 generates a thrust impulse directed normally to the trajectory of the aircraft on which it is mounted, which creates a torque for gyroscopic longitudinal stabilization of the flight.

A pulsed jet micromotor of the proposed design with a fuel mass of 30-35 g provides a thrust impulse in the range of 5-6 kgf⋅s for a working time of 0.1-0.2 s.

Thus, the diverse technical use of the gas generating device for various purposes is achieved while achieving novelty of quality.

Full-scale and bench tests of prototypes of the proposed design of a pulsed micromotor confirmed its functional reliability and stability of technical parameters with a wide range of gas-dynamic characteristics regulation, which expands technological capabilities for practical use for various purposes and allows recommending the design for serial production for delivery to customers.

A comparative analysis of the proposed technical solution with the identified analogues of the prior art, from which the utility model does not explicitly follow for a specialist in pulsed gas generators, showed that it is unknown, and taking into account the possibility of industrial serial production of jet micromotors in the current production, we can conclude that the conditions patentability.

Claims (1)

A pulsed jet micromotor containing a functional solid-fuel charge from parallel channel blocks mounted in a combustion chamber with gas ducts communicating with a receiver that is equipped with an exhaust nozzle and closed by rigidly connected ignition and output diaphragms, while an amplifying pyrotechnic charge initiated by a central electric igniter is located under the ignition diaphragm fixed in a cap provided with a confuser, characterized in that the outlet nozzle is tangentially rotated relative to In addition to the longitudinal axis of the combustion chamber, the ignition diaphragm is mounted movably relative to the cap confuser, and the amplifying pyrotechnic charge is made in the form of conformal pellets mounted on the ends of the channel blocks adjacent to each other and inscribed in the cross section of the combustion chamber, while the tablets have an open developed by means of radial reefs surface.

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