SU1265508A1 - Stand for stability tests of shells at dynamic loading - Google Patents

Abstract

This invention relates to a technique for dynamic testing of casings. The aim of the invention is to expand the range of variation of dynamic load parameters. The stand contains a base 1 for fastening the test shell 2. On the base I, a chamber 3 filled with liquid is installed, with the end of which the body 4 of the device for creating a shock wave is joined. The cavities of the housing 4 and the chamber 3 are separated by a removable package of membranes 8 and 9 clamped between the ends of the housing and the chamber. The shock wave acts on a package of membranes which, due to elastic deformation, create fluid pressure in chamber 3 acting on shell 2. Then the pressure from housing 4 is released, membranes 8 and 9 take their original position and pressure in chamber 3 decreases to their original value. By varying the number of membranes in the bag and their stiffness, it is possible to widely vary the rate of increase in pressure and the duration of its action. 1 il. (L | C O5 heard about 00

Description

The invention relates to testing equipment, namely, stands for testing shells for stability under dynamic loading.

The aim of the invention is to expand the dynamic range of parameter change Coy load ⁵ through the use of the elastic properties of the element separating the cavity of the body casing to create shock waves and fluid fills the chamber.

The drawing shows the proposed stand, general view.

The test bench for dynamic stability loading of shells contains a base 1 for fastening along the contour of the test shell 2, mounted on the base 1, a 15 fluid filled chamber 3, a device for creating a shock wave in the form of a shock tube, housing 4 (low pressure chamber) of which docked with the opposite end 1 of the end face of the chamber 3. The shock tube contains a diaphragm 5, a knife 6 for cutting it and a high-pressure chamber 7. The cavities of the housing 4 and the chamber 3 are separated by a removable membrane package, pinched between the ends of the housing 4 and the chamber 3. The membrane package consists of an elastic membrane 8 and elastic 25 membranes 9. In the proposed stand, a means 10 for relieving pressure from the cavity of the housing 4 is a gap 10 between the housing 4 and chamber 3. To measure the pressure acting on the shell 2 in the chamber 3, pressure sensors 11 are installed. thirty

The stand works as follows.

Compressed air is supplied to the high pressure chamber 7. After the knife 6 cuts the diaphragm 5, the shock wave propagates through the housing 4 and acts 1 on the package of membranes 8 and 9. Part of the pressure is released through the gap 10.

Under the influence of the shock wave, the membrane package elastically deforms, thereby increasing the pressure in the chamber 3, which loads the test shell 2. After reaching the maximum deflection, the membrane package under the action of elastic forces assumes its initial equilibrium position, as a result of which the pressure in the chamber 3 decreases to the initial one.

By changing the number of membranes, their size and rigidity, it is possible to widely vary the rate of increase in pressure and the duration of its impact, thereby expanding the range of changes in the load parameters. As the liquid in chamber 3, both high boiling and low boiling (cryogenic) liquids, such as oxygen and nitrogen, can be used. This allows testing under dynamic loading at low temperatures.

Claims (2)

i The invention relates to a test apparatus, namely, stands for testing shells for stability under dynamic loading. The aim of the invention is to expand the range of variation of dynamic load parameters by using the elastic properties of the element separating the cavities of the body of the device for creating a shock wave and filled with the fluid of the chamber. The drawing shows the proposed stand, a general view. The stand for testing the shells for stability under dynamic loading contains a base 1 for fixing the test shell 2 along the contour, installed; On base 1, a chamber 3 filled with a liquid network, a device for creating a shock wave in the form of a shock tube, housing 4 (low pressure chamber) connected to the opposite end of base 1 of chamber 3. The shock tube contains a diaphragm 5, a knife 6 for cutting it and a high pressure chamber 7. The cavities of the housing 4 and the chamber 3 are separated by a removable membrane package clamped between the ends of the housing 4 and the chamber 3. The membrane package is provided with an elastic membrane 8 and elastic membranes 9. In the proposed stand, a means for pressure relief from the cavity of the housing 4 serves as a gap 10 between the housing 4 and chamber 3. Pressure sensors 11 are installed to measure the pressure acting on the shell 2 in chamber 3. The stand works as follows. Compressed air is supplied to the high pressure chamber 7. After the knife 6 cuts the diaphragm 5, the shock wave propagates through the body 4 and acts (on the package of membranes 8 and 9. Part of the pressure is released through the gap 10. Under the influence of the shock wave, the package of membranes elastically deforms, thereby increasing the pressure in chamber 3 which loads the test shell 2. After the maximum deviation of the membrane package has been reached, under the action of elastic forces, it assumes its initial equilibrium position, as a result of which the pressure in chamber 3 is reduced to the initial one. By varying the number of membranes, their size and rigidity, it is possible to vary over a wide range the rate of increase in pressure and the duration of its action, thereby expanding the range of variation of load parameters. Both high boiling and low boiling (cryogenic) liquids, such as oxygen and nitrogen, can be used as liquid in chamber 3. This allows testing under dynamic loading at low temperatures. Claims for testing of shells for stability under dynamic loading, containing a base for fixing the test shell along the contour, a chamber filled with liquid, a device for creating a shock wave, the body of which is joined to the opposite end of the chamber butt, a dividing element of the body cavity and chambers, and means for relieving pressure from the housing cavity, characterized in that, in order to expand the range of variation of the dynamic load parameters, the element partitioned The housing cavity and the chamber are made in the form of a removable package of membranes clamped between the ends of the case and the chamber.