SU1585711A1 - Apparatus for testing shells for stability - Google Patents

Abstract

The invention relates to a testing technique, namely to testing the shells for strength and stability under the action of axial compressive forces. The aim of the invention is to increase the information content by ensuring that tests are carried out both before the moment of buckling and after buckling. Before loading, the shell 2 is rigidly connected to the base 1 and the loading plate 3, the vertical supports 5 are brought in contact with the loading plate. The second vertical racks have below the racks 5 on the magnitude of the deformation step ε. By means of the energizer 11, the crackers 7 are moved in the horizontal direction to a position in which the ends of the uprights 5 interact with the next step of the biscuits 7. Then, by means of the energizer 4, the shell is loaded until a predetermined strain value ε occurs in it. At each step of loading, the dependence of the deformation of the shells on the loading force is determined. 2 silt, 1 z. P. f-ly.

Description

The invention relates to a testing technique, namely to testing the shells for strength and stability under the action of axial compressive forces.

The purpose of the invention is to increase information by ensuring that tests are carried out both before the moment of buckling and after buckling.

Figure 1 shows the proposed device, a general view; 2 is a view A of FIG. 1.

The device contains a base 1, on which is fixed test shell

2, the load plate 3, fixed on the end of the shell opposite to the end face, which is fixed on the base, loading the energizer 4, located between the base 1 and the load plate

3, vertical stands 5 and 6, designed to interact with their ends with the loading plate 3 and crackers 7 and 8, located in the horizontal openings of the sleeves 9 and 10, mounted on the base 1, the surface of the crackers having a perpendicular axis racks 5 and 6, which are placed in the vertical grooves of the collars 9 and 10. Crackers 7 and 8 are connected to additional force drivers 11, the opposite ends of which are connected to the base.

Based on 1, at least two pairs of clips 9 and 10 are fastened, and clips 9 and 10 are diametrically opposed to each other, respectively, and clips 9 are offset relative to clips 10 by 90 ° around the circumference.

Racks 5 and 6 are provided at their ends with contact sensors 12 designed to stop the force gain when the shell deformation reaches a predetermined value.

The device works as follows.

Before loading, the shell 2 is fixed on the base 1, the legs 5 are brought in before contact with the load plate 3, which is rigidly fixed on the test shell. The racks can be supplied, for example, by varying their length. The pillars 6 at this moment are installed with a gap in relation to the loading plate 3, the value of which is equal to the height of the rusk 8. Then turn on the silo wagon 11 connected to the rusk 7, and move the rusks 7 in the direction

the pendicular axis of application of the load to a position in which the ends of the uprights 5 interact with the following support surfaces of dryers 7, while the ends of the uprights 5 are located below the ends of the uprights 6 by a deformation step e.

Then, energizer 4 is turned on and the load is increased until a predetermined amount of deformation occurs in the shell. The moment of stopping the gain is fixed by means of contact sensors 12 located on the upper ends of the legs 6 upon contact with the load plate 3. The shell is fixed in deformed state without removing the load. At each step, the dependence of the deformation of the shell on the loading force is determined.

The process of loading the shell is carried out both before the moment of loss of stability of the shell, and after the loss of stability until the moment of destruction. Thus, it is possible with any predetermined step to determine the dependence of the deformation of the shell on the force and thereby more accurately determine the magnitude of the critical force at which loss of stability occurs, and the behavior of the shell after loss of stability, i.e. allows to study the process of shell wave formation.

Claims (2)

1. Device: test for stability of the shell under axial compression, containing a base for mounting the test shell on it, designed to interact with the opposite end of the shell load plate, power drivers and strain gauges and load, characterized in that informativeness by providing tests both before and after loss of stability, the device is equipped with vertical racks of breadcrumbs and means of transportation placed between the base and the plate A direction in the direction perpendicular to the axis of the struts, one end of the struts was supported in the loading plate, the other on the first step of the cracker, and the loading plate intended for rigid connection with the shell. 2. The device according to Claim 1, which is equipped with contact sensors mounted on the ends of the racks that interact with the load plate. ///// ( viewA FIG. 2