RU2694824C1 - Pyrotechnics testing device - Google Patents

Abstract

FIELD: test equipment.SUBSTANCE: invention relates to a device for testing pyrotechnic means, comprising a nozzle unit in the form of a double cylindrical housing with pressure sensors, sealing, gas release and ignition assemblies, the latter comprising an element destructed by a fixed pressure, which opens the gas outlet assembly. Device is characterized by the fact that said housing is installed on the support site of the gun carriage by means of a screw attachment using a clamp, wherein the nozzle unit further includes a tracer element installed in the ignition chamber on the side of the sealing assembly, and the installed sensors do not protrude beyond the lower part of the double cylindrical housing.EFFECT: device allows to reproduce and visualize service conditions of ignition of powder when determining ballistic characteristics.6 cl, 2 dwg

Description

A device for testing pyrotechnic devices is intended to conduct research on new types of pyrotechnical devices being developed and on-site modeling of intraballistic processes arising from a shot in the barrel of an artillery gun.

Such devices are often called gauge bombs. The design of such devices usually includes a thick-walled vessel in which there are: a firing unit, a hinge of gunpowder or other combustible material, a gas release unit and one or more pressure sensors. So is known a device for determining the rate of combustion of rocket fuel, including a closed vessel in which the fuel sample holder is located (US Pat. No. 4,430,885, G01N33 / 22, February 14, 1984). The ignition wire is in contact with the fuel. In addition, the device includes a pressure sensor and an exhaust channel with a valve. The burning rate is determined by an electronic circuit using pressure sensor readings. In this case, the coefficient of the slope of the pressure dependence for a fuel having a faster burning will be higher than for a slower burning composition. If two pressure levels Pa and Pb are chosen and the area under the curve between the two pressure points is obtained, these data can be used to compare the relative burning rates of several compositions. The described device is highly specialized and does not include an element of explosive combustion of the pyrotechnic means used.

Also known is a manometric bomb, which consists of a body made of two cylinders with one another inserted into one another, a lid with an igniter spacer, equipped with an insulated electrode and a gas outlet, a lid with a spacer for measuring pressure, obturiruyuschie rings, copper screens that protect the end surfaces of the spacers (US Pat. RU№2236003, G01N33 / 22, 05/27/2003). The obturator rings in cross section have the shape of a triangle with its base to the small diameter of the ring. As a result, an increase in operating reliability up to pressures of 1100 MPa has been achieved. The disadvantage of this bomb is the complexity of manufacturing the fit under the pressure sensor, the lack of reliability of this connection, the height of the channel of the gas outlet unit of the igniter spacer, the lack of clarity when observing the shot. It does not show the design for mounting the bomb itself. A known design manometric bomb, which used the body of a thick-walled cylinder (US Pat. RU№182995, G01N33 / 22, F42B35 / 00, F23R7 / 00, 11.01.2017; US Pat. RU №175736, G01N33 / 22, F42B35 / 00, F23R7 / 00, 03/03/2017). The pressure sensor is installed in the wall of the cylinder. In the first case, the ignition parameters are described depending on the loading density. The latter is changed by using a sleeve with a membrane, which limits the internal volume of the manometric bomb, and when it is destroyed with increasing pressure, the entire volume of the manometric bomb is used. A shut-off valve in the form of a ball is used in the pressure relief channel.

An abrupt change in the volume for burning a powder charge can distort the measured pressure. In the second technical solution, a removable bushing is installed in the discharge channel, made as a part of the barrel and into which a cylinder is inserted with a control surface with a diameter equal to the caliber of the barrel. In both cases, the ignition unit or the ignition plug can be used for a long time.

As a prototype, a device for burning powders or for testing pyrotechnic products or a manometric bomb, including a double cylindrical body with nodes for sealing, ignition, gas release and pressure sensors in the body, was chosen (US Pat. RU 58716, G01N33 / 22, 11.05.2006) . At the same time, the ignition unit contains an element that is destroyed by a fixed pressure, which opens the gas discharge unit. The seal assembly is made using a differential sealing device when the sealing element is compressed by a pressure-movable part. Functionally, this construction can be briefly designated as a nozzle block. Pressure sensors record changes in pressure during the testing of pyrotechnic products in the area of their sensitivity. In this case, the location of the sensors is not localized in a certain part of the body, which would exclude the deformation effect during the testing process.

The objective of the proposed utility model is to construct a device for testing pyrotechnic tools such as a manometric bomb, which allows to burn and investigate the indicated means up to a pressure of about 1000 MPa without leakage of powder gases, technological in operation and visualizing the trajectory of the emission of gases.

An additional problem is the reproduction of the service conditions for ignition of gunpowder when determining the ballistic characteristics.

The technical result is the proposed design, which provides the fixation of process parameters and its visualization, thereby expanding the technical capabilities of the device for testing pyrotechnic means.

The solution of this problem is achieved by the fact that in a device for testing pyrotechnic devices containing a nozzle block in the form of a double cylindrical body with pressure sensors, sealing units, gas release and ignition, in which the latter includes a element that can be destroyed by fixed pressure, opens the gas release unit; block nozzle device on the pad carriage by means of a screw fastening using a clamp and a lock nut, in addition to the nozzle block den tracer element mounted in the ignition chamber from the seal assembly and installed sensors do not protrude beyond the bottom of the double cylindrical body.

Moreover, batteries, control and remote control batteries are installed under the base platform in the case.

Additionally, pressure sensors record changes in pressure during the testing of pyrotechnic devices in the area of their sensitivity and transmit data over the wireless channel.

At the same time, two pressure sensors are simultaneously used to control the indicated pressure in the device chamber.

In addition, the device ensures the achievement and release of pressure in the working chamber in a given range with the required interval and for which it is completed with diaphragms for each pressure interval.

In addition, the device provides ignition of the tracer from the powder charge.

Introduction to the design of the device of new blocks and elements, as well as the characteristic implementation of the already existing basic units of the device and the special placement of their elements allows to significantly increase the operating efficiency of the proposed device by ensuring high reliability of the parameters of the shot and at the same time ensure ease of operation. The design of the nozzle block uses two differential sealing devices using rubber rings (G.V. Makarov Sealing devices, Leningrad, Mashinostroenie, Leningradskoye department, 1973, p.23-31). One seal with a diaphragm destroyed by a shot provides free flow of pore gases and for visualization of the tracer burning, and another differential seal has a slot for installing the tracer.

The monitoring system provides the ability to monitor the health and operating time of the tracer. The process is controlled automatically, remotely, manually or from a remote control. And the ability to simulate the conditions of a shot inside the bore is determined by the size of the powder charge and the design of the diaphragm.

The claimed invention is illustrated by drawings, in which:

- on figa shows a General view of the proposed device;

- figb shows the mounting nozzle unit of the device;

- figure 2 shows a section of the nozzle block.

The device contains (Fig. 1a and b) a nozzle block 1 and a three-carriage carriage 2. The coulters 3 in the amount of three pieces are fixed in the beds and serve to fix the gun carriage when installed on the ground. The frame of the mast in the center is connected by a stand with a support platform, on which the collar 4 is located. The nozzle block is fixed to the carriage by installing it into this collar 4 and its locking with nut 5 and key 6 (FIG. 1a). The lock nut, in turn, is locked with the help of the comb 7. The key and the comb are fixed to the nozzle block by means of bolts 8 and 9, respectively, which are locked with wire 10. The mast rack, on which the nozzle block is installed, has a closed cavity in the bottom to accommodate auxiliary batteries, control and management of the test process.

The nozzle block (Fig. 2) consists of a block 11 body into which a mushroom-shaped rod 13 is inserted from the side of the pipe collar with a tracer nut 25 screwed into it (selected depending on the tracer being tested) and the rubber o-ring 15 installed and metal o-rings 15 and 16, respectively, with the sleeve 12. After the rod is installed, the nut 18 is screwed into the block body, then the nut 17. Next, the bushes for pressure sensors 21 and 23 respectively are installed through the copper sealing rings 24, and then the screw is screwed in and 22.

From the side of the threaded part of the housing, the mushroom-shaped rod 26 is assembled with the ring 27, the diaphragm 20 (selected depending on the required working pressure), the nut 27 and the nut 19. Elements 26, 27, 28, part 20, wire 30 with an igniter 29 constitute knot of ignition and release of gases.

The proposed device works as follows. Seals are used for pressure sensors and elements that cover the cylindrical body of the nozzle block on both sides.

First, the device is installed as follows:

It is necessary to install the carriage 2 (Fig. 1a) on a flat ground, in the supports install the openers 3, use the appropriate tool to drive the openers into the ground, after stopping the openers in the supports of the carriage; Next, the nozzle unit 1 should be installed in the clamp 4 on the mast stand and secured with a retainer nut 5 and a key 6; after which you need to lock the locking nut 5 with a comb 7, for which fix the comb to the body of the carriage by means of bolts 8; fasten the key 6 to the nozzle unit 1 by means of bolts 8; wire 10 secure the bolts 8 and 9. After this installation, the installation is ready for testing.

When testing the installation, the nut 18 and the mushroom-shaped rod 13 are assembled with a differential seal consisting of a rubber sealing ring 14, metal sealing rings 15 and 16, a sleeve 12. Then the nut 19 and the mushroom-shaped rod 26 are disassembled with the ring 27 , diaphragm 20, nut 28. After installation, the tracer is installed in the tracer nut 25 and the tracer nut is installed in the mushroom-shaped rod 13. Then the installation is charged. For this purpose, a powder charge is laid in the installation chamber, the value of which is selected depending on the required pressure. Then, an electric igniter 29 is installed, a wire 30, from which a diaphragm 20 is assembled through a hole in a mushroom-shaped rod 26 assembled with a ring 27 selected depending on the required pressure, a nut 28 that fits into the block body and then presses a portion of the diaphragm 20 with a nut 19. After the mushroom-shaped rod 13 is assembled with differential seal and tracer 25 into the block body and pressed by nut 18, in accordance with fig. 2. The nuts 17 and 18 are tightened to the specified torque.

When voltage is applied to the electric igniter 29, the powder charge ignites. Burning powder charge causes an increase in pressure in the installation chamber. When the required pressure is reached, the diaphragm collar is cut off and the cut-off part of the diaphragm flies out together with the powder gases from the installation together with the mushroom rod 26, ring 27 and nut 28. The powder gases flowing through the hole in the diaphragm simulate the process of pressure change in the artillery barrel. In the process of burning powder charge ignition of the test tracer occurs. The measurement of the pressure of powder gases in the process of burning powder is made by pressure sensors 31 and 32 and is recorded by the apparatus. Pressure sensors may be less than two. The presence of at least two certified sensors allows averaging of pressure values. Thereby it is possible to increase the reliability of measurements. Transmission of sensor readings can be performed wirelessly. Changing the parameters that occur when burning powder in the installation chamber is made by changing the mass of the powder charge, the brand of powder, and the size of the diaphragm.

The device is designed for pressures up to 1000 MPa (10,000 kgf / cm²) pressure.

The proposed product ensures the attainment and release of pressure in the working chamber in the range from 400 MPa (4000 kgf / cm²) to 800 MPa (8000 kgf / cm²) with an interval of 100 MPa (1000 kgf / cm²), and is completed with diaphragms for each pressure interval.

Design documentation has been developed for the described device. The prototype is made and tested. Tests confirmed compliance with the requirements laid down in the task for the device.

Claims (6)

1. A device for testing pyrotechnic devices, including a nozzle block in the form of a double cylindrical body with pressure sensors, sealing units, gas release and ignition, while the latter contains an element destroyed by fixed pressure, which opens the gas outlet unit, characterized in that on the bearing pad of the carriage by means of screw fastening using a collar, while the tracer element installed in the ignition chamber is additionally inserted in the nozzle block from the side of the seal assembly, and the installed sensors do not protrude beyond the lower part of the double cylindrical body. 2. The device according to claim 1, characterized in that the batteries, control and remote control batteries are installed in the body of the support platform. 3. The device according to claim 1, characterized in that the pressure sensors record the pressure changes in the process of testing pyrotechnic means in the area of their sensitivity and transmit data over the wireless channel. 4. The device according to claim 1, characterized in that two pressure sensors are simultaneously used to control the specified pressure in the device chamber. 5. The device according to p. 1, characterized in that the device provides for the achievement and release of pressure in the working chamber in a given range with the required interval and is completed with diaphragms for each pressure interval. 6. The device according to p. 1, characterized in that the device provides for the ignition of the tracer from the powder charge.

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