RU58716U1 - POWDER BURNING PLANT - Google Patents

Abstract

The gunpowder burning facility is designed to calibrate spherical craters and test cracker devices. The essence of the PM lies in the fact that the installation comprises a housing with pressure sensors made of two cylinders with an interference fit inserted one into the other, a cover additionally equipped with a sealing device containing a rod with a cap, on which a nut, a cylindrical sleeve and a sealing ring consisting of rings of elastic material placed in three steel rings, an ignition cap with an igniter spacer, made in the form of a cylinder with an axial hole, inserted with an interference fit into the body and sn bzhennoy venting device comprising erodible element obtyuriruyuschee ring seated in annular grooves on end surfaces of the housing and the igniting spacers, and an appliance. EFFECT: reproducing the conditions of the preparatory, first and second periods of an artillery shot in the pressure range of more than 1000 MPa in the volume of the internal cavity of the installation sufficient to accommodate cracker devices.

Description

A utility model (hereinafter referred to as PM) relates to the field of measurement technology.

PM can be used in the field of measurement technology as a physical model of artillery fire

Known devices for burning gunpowder - manometric bombs (hereinafter referred to as MB), which are closed vessels with a small unchanged volume, equipped with a device for measuring and recording the pressure of powder gases and the nature of its change over time. They are used to study the characteristics of gunpowder and explosives and the phenomena accompanying the preliminary period of an artillery shot. The content of this period is the combustion of gunpowder in a confined space

In the book of AI Holbinder, “Laboratory work on the course: the theory of explosives”. Rosvuzizdat 1963, 142, p. 42. a manometric bomb is presented, containing a thick-walled tube-body with two covers. Obturation of both covers is carried out using flat steel and rubber rings. An insulated electric input is mounted in one of the covers, a thin wire is attached to the inner end of the electrical input, the second end of which is connected to the bomb body via a pin screwed into the cover. To glow the wire causing the igniter to burn, voltage is applied to the insulated electric input and the bomb body. A pressure sensor is mounted in the second cover. The assembly sequence of this MB: a cover with a pressure measuring sensor, rubber and steel rings are screwed into the housing on one side; in the internal cavity of the housing place a sample of gunpowder, a cover with a sample of igniter, a glow wire, rubber and steel rings are screwed into the body on the other hand; MB is installed in the clamps; tighten both covers with a wrench; connect the wires of the sensor and the igniter; carry out a burning sample of gunpowder.

A disadvantage of the known MB is that its body and the cover seal assembly operate to a pressure of not more than 500 MPa.

From the description of the patent No. 2236003 (filing date 2003.05.27, registration number 2003115774/28), high pressure MB is known for operation up to pressures of 1100 MPa, including for studying the nature of the increase in pressure of powder gases and establishing its maximum value. MB contains a housing made of two cylinders with a certain interference fit one into

on the other, steel obturating rings are located on both sides of the casing, which are pressed to the casing by a pressure spacer and an igniter spacer with covers. The obturating rings in cross section have the shape of a triangle with its base to the small diameter of the ring. A portion of gunpowder is placed in the internal cavity of the MB. A portion of the igniter is located between the electrical inputs, one of which is isolated from the housing. An incandescent wire is located between the electrical inputs, which is in contact with the igniter hitch. To release gases after the combustion of gunpowder, the ignition spacer is equipped with a gas discharge device, which consists of a steel ball, a screw that presses the ball to the saddle, and a gate with a steel cable, which are designed to remotely affect the gas exhaust device. To protect the end surfaces of the spacers from the effects of the combustion products of gunpowder, copper screens are provided.

Known designs MB have a small volume of the internal cavity and reproduce the phenomena accompanying an artillery shot only in its preliminary period.

The crack method for measuring maximum pressure is the main one in ballistic tests in artillery practice.

The problem that the proposed installation for the combustion of gunpowder (hereinafter referred to as the installation) solves: creating a structure intended for dynamic calibration of spherical craters and testing of cracker devices under conditions as close as possible to an artillery shot. The technical result achieved by the proposed design is to reproduce, with given parameters, the conditions of the preliminary, first and second periods of an artillery shot in an amount sufficient to accommodate cracker devices, work in the pressure range up to 1000 MPa.

The graphic materials in FIG. 1 and FIG. 2 are presented to this description. Figure 1 shows the design of the proposed installation, where 1 is the nut of the sealing device; 2 - cover; 3 - a cylindrical sleeve of the sealing device; 4 - ring, part of the obturating ring of the sealing device; 5 - rubber ring, part of the obturating ring of the sealing device; 6 - ring, part of the obturating ring of the sealing device (2 pcs.); 7 - rod with a cap sealing device; 8 - hole for installing a pressure sensor (2 pcs.); 9 - case; 10 - (second) obturating ring; 11 - igniter spacer; 12 - conical sleeve of the device for the release of gases; 13 - ring gasket; 14 - a nut for installation of fasteners; 15 - igniter cap; 16 - insulated wires,

carrying out electric input; 17 is a destructible element of a gas exhaust device; 18 - electric igniter.

Figure 2 presents the test results of the installation in the form of a table.

The problem is solved by performing a housing of two metal cylinders with an interference fit inserted into one another and with two covers: a cover on which a sealing device is fixed with a nut, which also contains a metal rod with a cap on which the specified nut, a cylindrical sleeve and a sealing ring made of details: rings made of elastic material, for example, rubber, placed in three metal rings with identical cross sections in the form of a right triangle, with two rings and have the same diameter, from an igniter cap with an igniter spacer, made in the form of a cylindrical sleeve with an axial hole having a cylindrical and conical surface, fitted with an interference fit into the housing and placing the conical sleeve of the gas exhaust device in it with a large base into the installation cavity with a destructible element of the device gas outlet, which is made in the form of a cylinder with a shoulder and through longitudinal holes for placement of electric input wires, placed in its axial e hole on the side of the internal cavity of the installation by placing in the annular grooves on the mating end surface of the igniter spacer and the side surface of the body of the steel obturating ring having an isosceles triangle in cross section with its base to a small diameter of the ring. The cross sections of the annular grooves are in the shape of a rectangular triangle. The holes for the piezoelectric quartz sensors are made in the side walls of the housing radially and symmetrically with respect to the axis of the installation housing,

The installation comprises a housing 9 made of two cylinders with a certain interference fit, inserted one into the other. On one side of the housing 9 there is a sealing ring 10, an ignition spacer 11, a cover 15. The locking ring 10 is in cross section the shape of an isosceles triangle with its base to a small diameter of the ring and is placed in ring grooves having a cross section in the form of a rectangular triangle, made on the mating the side surface of the housing 9 and the end surface of the ignition spacer 11. It is preloaded by the ignition spacer 11 and the cover 15 inserted with a certain interference. Ignite The linen spacer 11 is made in the form of a cylinder with an axial hole having cylindrical and conical surfaces and is equipped with a gas discharge device with parts: a conical sleeve 12 placed by a large base in the internal cavity and a destructible element 17 made in the form

containing a flange of the cylinder with longitudinal holes placed in the axial hole of the conical sleeve 12 from the side of the internal cavity of the installation. On the other side of the casing 9, a sealing device is mounted, fixed by a nut 1 on the cover 2. The sealing device contains the following parts: a rod with a cap 7, a cylindrical sleeve 3 and a nut 1, for preliminary compression of the obturating ring consisting of a ring of elastic material 5, for example made of rubber placed in three steel rings 4, 6 having identical cross sections in the shape of a right-angled triangle. The elastic ring 5 has external and internal chamfers on which the rings 4, 6 are placed. This embodiment of the obturating ring protects the rubber from squeezing. The caps 2 and 15 are made in the form of cylinders with axial holes and a persistent thread. In the lateral surface of the housing 9, holes 8 are made radially and symmetrically with respect to the axis of the housing to accommodate piezoelectric sensors. A portion of gunpowder in a cap with an igniter hitch and an electric igniter 18 is placed in the internal cavity of the installation. As an electric igniter, ignitors of the MB-2H, MB-5, EV-15 type, or similar, can be used. The electric lead to the electric igniter 18 is carried out using two insulated wires 16 connected to the corresponding device through the longitudinal holes of the gas element 17 being destroyed and through the axial holes of a certain diameter of the electric spacer 11 and the cover 15. Between the end contacting surfaces of the conical sleeve 12 of the gas and the ignition unit spacers 11 installed an annular gasket 13, for example, of aluminum, to prevent welding of these steel surfaces rhnostey when leaving the installation of hot gases. Installation details are made of steel (except for the elastic ring of the sealing device). The installation contains fasteners, one of which is a nut 14. The installation can be placed on a gun carriage.

Before testing, the cover 2 of the installation, with a sealing device fixed on it, consisting of parts 1, 3, 4, 5, 6, 7 is unscrewed from the housing 9. Due to the significant weight of the cover 2 with the sealing device, they can move along the guides included in the composition of the fasteners. To provide electric input to the electric igniter 18 from the corresponding device, for example, the remote control, lay wires 16 through the longitudinal holes of the destructible element 17 and the axial holes of the ignition spacers 11 and the cover 15. The cylindrical part of the destructible element 17 is attached to the inner surface of the conical sleeve 12 of the gas exhaust device with a mastic mastic . In the internal cavity of the housing 9 place a sample of gunpowder in a cap with an ignition sample and

by electric igniter 18. Then, a magazine with crash devices is installed in the area of the piezoelectric quartz pressure sensors, the ignition cover 2 is screwed in and tightened with a wrench, with the sealing device secured and pre-tightened by nut 1.

When voltage is applied to the electric igniter 18, for example, from the remote control, the gunpowder ignites. The increasing pressure of the powder gases acts on the end surface of the cap of the rod 7 of the sealing device, causing a deformation in the cross section of the pre-pressed elastic ring 5 of the sealing device placed in the metal rings 4, 6. The deformation of the elastic ring 5 increases with increasing pressure of the powder gases, providing a reliable seal. At the other end of the installation, the obturation is provided by the obturating ring 10, preloaded by the ignition spacer 11, installed with a certain interference fit, and the igniter cover 15. The pressure acts on the inner surface of the obturator ring 10. pushing it into the grooves. Obturation is also provided by the shape of the (conical) sleeve 12 of the gas exhaust device and the placement of the sleeve 12 with a large base in the internal cavity of the installation with a destructible element 17, which acts as a plug at the initial stage of the installation. The combustion of gunpowder occurs in a closed unchanged volume of the installation with increasing pressure of the powder gases. The content of the preliminary period of an artillery shot is the burning of gunpowder in a confined space. In the installation, thus, the preliminary period of the artillery shot is reproduced.

It is known that the magnitude of the maximum pressure, the time of its achievement can be controlled by the mass of the powder, the geometric shape of the powder elements, but this is not the subject of this description.

The first or main period of an artillery shot begins from the moment the projectile begins to move in the barrel bore until the burning of gunpowder ends. The content of this period is the burning of gunpowder in a changing volume, the achievement of the maximum pressure of the powder gases, followed by a decrease in the pressure of the powder gases.

In the installation, when a certain pressure is reached, which cuts off the collar from the destructible element 17, the outflow of powder gases through the axial holes of the parts 12, 11, 15 begins, that is, a change in the volume in which the combustion of the powder continues. The magnitude of the flow rate is set by the diameter of the axial bore of the conical sleeve 12 of the gas outlet. The thickness of the shoulder having a certain mechanical strength sets the value of the specified pressure. The pressure of the powder gases in the installation

with a selected weight of the powder increases, despite the outflow of gas, to the complete combustion of the powder. It is known that the combustion rate of gunpowder in a certain volume is the higher, the greater the pressure at which combustion occurs. That is, by changing the mechanical strength of the destructible element 17 with the same weight of gunpowder in the installation, the pressure rise rate and the maximum pressure value are changed. This is confirmed by the results of the combustion of gunpowder in the installation, shown in rows 1 through 4 of the table in figure 2. In the installation, the combustion of gunpowder takes place in a variable volume with an increase in the pressure of the powder gases and the achievement of the maximum pressure of the powder gases. Thus, the installation reproduces the first period of an artillery shot.

The second period of the artillery shot begins from the moment the combustion of the powder charge ends until the projectile leaves the bore. This period is considered the period of adiabatic expansion of gases.

In the installation, after the complete combustion of the powder charge, the outflow of powder gases continues, and according to the general theory of the outflow, this process is considered as adiabatic. Change the speed of this process by changing the diameter of the axial bore of the conical sleeve 12 of the gas exhaust device. Thus, the installation reproduces the second period of the artillery shot

The installation allows you to burn gunpowder, to reproduce conditions as close as possible to an artillery shot, to create pressures up to 1000 MPa in a volume sufficient to accommodate the tested crash instruments, which is confirmed by the test results shown in the table in figure 2. The measurement of maximum pressures during ballistic tests in artillery practice is carried out using crash instruments and piezoelectric quartz sensors. In real conditions, the crasher and the crasher devices are exposed during the shot not only to the pressure of the powder gases, but also to a powerful temperature shock. Therefore, the values of the measured pressures in the proposed installation are more reliable than the results obtained by other methods other than firing. The proposed installation provides high reliability and manufacturability to pressures up to 1000 MPa. Operation of the installation will allow the use of less expensive methods for calibrating spherical craters and testing crash devices than firing from artillery systems.

Claims (1)

The installation for burning powder contains a housing made of two interference cylinders inserted one into the other, a cover, an ignition cover, an ignition spacer with a gas exhaust device, an electric inlet, two obturating rings, one of which is made with a cross section in the shape of a triangle with its base to a small diameter of the ring, characterized in that the cover is additionally equipped with a sealing device containing a rod with a cap, on which a nut, a cylindrical sleeve, an obturating ring are placed non-made of a ring of elastic material placed in three steel rings with the same cross sections in the form of a rectangular triangle, the two rings having the same diameter, the igniter spacer is made in the form of a cylinder with an axial hole having a cylindrical and conical surface, and is inserted with an interference fit into the housing , the device for the release of gases is made in the form of a conical sleeve, placed a large base in the internal cavity of the installation, and destructible element made in the form of containing bu rtik cylinder with longitudinal holes placed in the axial hole of the conical sleeve from the side in the internal cavity of the installation, the second obturating ring is placed in annular grooves made on the side surface of the housing and on the end surface of the igniter spacer and having a cross section in the form of a rectangular triangle, in the housing are made openings for placement of pressure sensors.