RU196333U1 - LOCALIZING DEVICE FOR RESEARCH OF FAST PROCESSING HYDRODYNAMIC PROCESSES - Google Patents

Abstract

The utility model relates to the field of blasting technology and the study of fast-flowing hydrodynamic processes, in particular to the study of the physical and mechanical properties of materials under intense dynamic loads created by loading devices using explosives. In these studies, localizing devices and explosive chambers are used to protect the environment and equipment from the effects of explosion products and fragments. The technical result is to increase the information content of the obtained research results in one experiment. The device contains an external sealed explosion-proof chamber, the central part of the body of which and the bottom are equipped with anti-splinter protection, and a measuring assembly is placed in the cavity, made in the form of a set of capsules separated from each other, arranged in several rows along the camera axis and mounted on a common frame installed in it central part. In each capsule, the loading device used by the shock wave generator and the test sample are sequentially placed, the lid and bottom of the capsule being made with the possibility of destruction during dynamic loading of the test sample, and the capsule is equipped with measuring and technological equipment, and the capsules of one row are placed on a common axis facing each other in pairs and in pairs from the installation side of the loading devices, the capsules of the same row being equipped with either individual filters for connection with gas filling system or with a vacuum system, and shock wave generators are combined into a single system of simultaneous detonation. 2 C.p. f-ly, 1 ill.

Description

The utility model relates to the field of blasting techniques and the study of fast-flowing hydrodynamic processes, in particular, to researching the physical and mechanical properties of materials under intense dynamic loads created by loading devices using explosives. In these studies, localizing devices and explosive chambers are used to protect the environment and equipment from the effects of explosion products and fragments.

The objective of the field of technology is the creation of a device of a wide range of applications, providing research on the physical and mechanical properties of materials under intense dynamic loads created by loading devices using explosives.

The well-known "Localizing device for radiographic studies of explosive processes", RF patent No. 2455614 C1, IPC F42D 5/04 (published 10.07.2012). The specified device contains an explosive chamber, the casing of which consists of a central part and two convex bottoms, reinforced inside with anti-splinter elements and fastened together by annular flanges using studs. The studs are evenly distributed in pairs along the radius of the flanges with an interval for the passage of the flow of radiographic radiation. In this case, the central part is made in the form of a hollow puff cylindrical insert with flanges hermetically connected to the flanges of the bottoms by means of pressure rings.

The disadvantages of the device are the significant attenuation and scattering by the multilayer wall of the central insert of the chamber of the x-ray flux propagating from the source through the sample to the recording system, which reduces the quality of the recorded image of the investigated explosive processes.

Closest to the invention, the technical solution (prototype) is a device for conducting studies of the physical and mechanical properties of materials under intense dynamic loads created by loading devices using explosives (patent RU 2548462, “Localizing device for investigating fast-flowing hydrodynamic processes”, IPC: F42D 5 / 04, published on April 20, 2015). The device contains an external sealed explosion-proof chamber, inside of which a measuring assembly is placed, including a capsule, in which a loading device containing an explosive charge operated by a shock wave generator is sequentially placed, and the test sample, cap and capsule bottom are made with the possibility of destruction during dynamic loading of the test sample, and the capsule is connected by a pipeline to a gas filling or evacuation system and is equipped with measuring and technological equipment. In the outer chamber, pressure and temperature sensors are placed, and in the study of radioactive materials - detectors for measuring radioactivity. Hermetic junctions for the blasting line and corresponding measuring sensors are installed in the bottoms.

The disadvantage of this device is the impossibility in one experiment to study several materials, to vary the parameters of the shock load or to change the composition of the environment (gas, vacuum, etc.), which increases the cost and complexity of research.

The technical result is to increase the information content of the obtained research results in one experiment.

The specified technical result is achieved due to the fact that in the localizing device for studying fast-flowing hydrodynamic processes, containing an external sealed explosion-proof chamber, inside of which there is a measuring assembly, including a capsule, in which the loading device used by the shock wave generator, and the test sample, the lid are sequentially placed and the bottom of the capsule is made with the possibility of destruction under dynamic loading of the test sample, and the capsule is connected by a tube a gadget with a gas filling or evacuation system and equipped with measuring and technological equipment, the new thing is that the measuring assembly is made in the form of a set of capsules separated from each other, arranged in several rows along the axis of the localizing device and mounted on a common frame installed in the central part of the sealed explosion-proof chamber, while the bottom of the chamber, as well as its central part, is equipped with splinter protection, capsules of the same row are placed in pairs on the common axis, and capsules in D face each other by the installation of the loading device, wherein the capsules are provided with a single row of individual filters for connection to the gas filling system or from the vacuum system, and shock wave generators are combined into a single system of simultaneous detonation.

Splinter protection of the central part can be made in the form of a package of metal mesh, and the bottoms can also be in the form of a set of steel disks.

Capsules can be equipped with explosive loading devices that differ in amplitude and duration of the loading pulse, as well as filled with gas at a certain pressure or evacuated.

The implementation of the measuring assembly in the form of a set of capsules separated from each other, arranged in several rows along the axis of the containment device and mounted on a common frame installed in the central part of the sealed explosion-proof chamber, makes it possible to increase the information content of the experiment by increasing the number of samples to be studied, to ensure a choice a large number of applications of various samples, levels of dynamic loads and a change in the environment in the cavities of the capsules, which also increases the collection of statistical data with fewer trials (reduction of physical and material costs).

Providing the central part and the bottoms of the chamber with anti-splinter protection allows using the bearing capacity of the cylindrical shell along the length of the central part with a more even distribution of loads along its length and, in total, significantly reducing fragmentation and impulse effects.

Placing the capsules of the same row on the common axis in pairs, and the capsules in pairs facing each other from the side of the installation of loading devices, allows you to use the effect of reducing and redistributing the loads on the camera in the axial direction due to the directional movement of the expanding explosion products from each loading device towards each other ( axial pressure reduction and radial pressure redistribution).

The supply of capsules of the same row with individual filters for connection to a gas filling system or with a vacuum system allows expanding research variations in one experiment.

The combination of shock wave generators into a single simultaneous detonation system allows you to synchronize the impact to ensure the directional movement of the expanding explosion products from each loading device towards each other.

In FIG. shows a diagram of the localizing device, which includes a measuring assembly that explains the claimed utility model, where:

1 - external sealed explosion-proof chamber; 2 - splinter protection; 3 - frame; 4 - suspensions; 5 - capsules; 6 - loading devices; 7 - filters; 8 - pipelines.

An example of a specific implementation of the claimed utility model can be a device for studying the dynamic properties of structural materials (including radioactive and toxic) using explosives as loading devices that create a pressure pulse with an amplitude of up to ~ 50 GPa. In the inner cavity of the cylindrical outer sealed explosion-proof chamber 1, a metal frame 3 is suspended on two suspensions 4, on which an assembly is installed, including eight steel sealed capsules 5, arranged in two rows, with loading devices and filters with pipelines. The capsules are equipped with various samples and different loading devices 6, which create a shock wave action in the sample at pressure levels from ~ 15 GPa to ~ 50 GPa. The capsules are spaced a certain distance from each other in two planes relative to the axis of the explosion-proof chamber. In the upper row are capsules, which, when assembled using a gas filling system, are filled with a gas mixture. Each capsule through a pipe 8 is connected to an individual filter 7, through which the cavity is filled with gas. In the bottom row are capsules with a vacuum medium. A shock wave generator is installed on each capsule, which are combined into a system of simultaneous detonation. Explosion-proof chamber 1 in the central part is equipped with anti-shatter protection, which reduces fragmentation and general shock wave from loading devices on the walls of the explosion-proof chamber in the capsule location zone during the experiment. In addition, the camera bottoms are also equipped with splinter protection. Splinter protection of the central part is made in the form of a package of metal mesh, and the bottoms - in the form of a set of steel disks.

The operation of the claimed device is as follows.

The explosion-proof chamber 1 is pre-installed on the working field (to the ground) of the test site. A sequential assembly of the device with the installation of capsules 5 on the frame 3 and the equipment of loading devices containing explosives. Vacuuming of the cavities of the capsules 5 of the lower row and filling with the gas medium of the cavities of the capsules 5 of the upper row are performed. The device is suspended in the geometric center of the explosion-proof chamber, after which the chamber is hermetically sealed and loading devices containing explosive charges are simultaneously blown up.

In the explosion of explosive charges in the cavity of the explosion-proof chamber 1, dynamic loading of the anti-shatter protection 2 occurs. It is affected by the total pressure pulse of the air shock wave, gaseous and solid (fragments) of the explosive. As a result, the splinter protection is deformed, and damage from fragmentation appears on its surface. In this case, due to the use of anti-fragmentation protection 2, the total effect of the total pressure pulse of the air shock wave is reduced and fragmentation of the explosion-proof chamber 1 is minimized (possibly eliminated).

When the shock waves collide from oppositely directed loading devices of the capsules 5, the load impulse is redistributed to the explosion-proof chamber 1.

The current experimental sample shows the possibility of implementing the claimed utility model. The conducted explosive experiments confirmed the achievement of the claimed technical result. Thus, the claimed utility model provides an increase in the information content of the obtained research results in one experiment, because allows you to conduct an experiment with a device that contains several capsules and at the same time study the dynamic properties of various materials in a wide range of pressures by shock-wave methods using methods based on different physical principles, with the possibility of evacuation or filling of capsule cavities with gas.

Claims (3)

1. The localizing device for the study of fast-flowing hydrodynamic processes, containing an external sealed explosion-proof chamber, inside which is placed a measuring assembly, characterized in that the measuring assembly is made in the form of a set of capsules separated from each other, arranged in several rows along the axis of the localizing device and mounted on a common the frame suspended by two suspensions in the Central part of the sealed explosion-proof chamber, while in each capsule are sequentially placed the loading device used by the shock wave generator, and the test sample, the lid and the bottom of the capsule are made with the possibility of destruction during dynamic loading of the test sample, and the capsules are connected by pipelines to the gas filling or vacuum system and are equipped with measuring and technological equipment, the central part of the body and the bottom of the chamber are equipped anti-fragmentation protection, capsules of one row are placed on the common axis in pairs, while the capsules in a pair are facing each other from the installation side loading devices, and the capsules of one row are equipped with individual filters for connection with either a gas filling system or a vacuum system, and shock wave generators are combined into a single simultaneous detonation system. 2. The device according to p. 1, characterized in that the splinter protection of the central part is made in the form of a package of metal mesh, and the bottoms are also in the form of a set of steel disks. 3. The device according to claim 1, characterized in that the explosive loading devices of the capsules differ in amplitude and duration of the loading pulse.

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