RU145751U1 - SHOCK TEST STAND - Google Patents

Abstract

1. The stand for impact testing, including the base on which the shock pulse forming device, its damping device, including flexible inflatable membranes equipped with gas pressure control means, as well as a table for the test product mounted with the possibility of movement on vertical rods and connected with the mechanism of its lifting and discharge, characterized in that the pulse shaping device is made in the form of an anvil for placement of the crasher mounted on the extinguishing device in the form of an inertial block based on a number of elastic shells, the first part of which is located on the periphery of the block, and the second in its central zone, while all shells are in communication with a source of compressed gas, and the first part also with the outer space through a quick valve exhaust controlled by an accelerometer mounted on a block. 2. The stand according to claim 1, characterized in that the inertial block consists of an upper steel plate connected with a concrete massif, while the block is equipped with through holes, the number of which is equal to the number of all elastic shells placed in these holes and enclosed between the upper covers and supports in in the form of cylinders partially placed in these holes and resting on a base with respect to which the block is installed with a gap. 3. The stand according to claim 1, characterized in that the base is equipped with stops restricting the upward movement of the inertial block. 4. The stand according to claim 1, characterized in that the gas pressure in the shells located in the central zone is less than the pressure in the shells located on the periphery. 5. Stand according to claim 1, ex.

Description

The utility model relates to test equipment and, in particular, to stands for impact tests.

A known design of the stand for impact testing, containing a base with vertical guides on which is placed a table for installing the test product, as well as a device for lifting and dumping the table. In addition, the stand contains a shock pulse shaper located between the table and the base, which includes a pneumatic elastic element made in the form of an inflatable elastic shell. The latter contains a set of elastic gaskets located inside it, and an elastic gasket mounted on the shock-absorbing surface of the shell. A hollow punch carrying a shell is fixed on the base. The inner cavity of the shell can be communicated with the cavity of the punch through a throttling element. Gas is supplied to the shell through a pipeline from a pressure source. An opening [SU No. 1486833] can be made in the shell under the gasket.

The stand works as follows.

In the initial position, the table with the tested product is raised along the guides above the shock pulse shaper to a height to achieve it when the predetermined collision speed falls. The internal cavity of the shell and punch are filled with compressed gas. The table, moving under the influence of gravity down the guides, accelerates to a predetermined collision speed, at which it comes into contact with the elastic gasket of the pulse shaper. At this stage of interaction, the elastic pad performs the function of a “cushion” that smoothes the leading edge of the shock pulse. When the deformation of the gasket reaches a significant value, the direct interaction of the table with the shell and the elastic gaskets installed in it begins, as a result of which the formation of parameters of the shock pulse occurs. In this case, the leading edge is formed at the stage of compression of the shock pulse shaper. In the process of compression of the shell, a significant relative decrease in the volume of its internal cavity occurs, which leads to a sharp increase in the gas pressure in it, which, in turn, affects the shape of the shock pulse. To reduce pressure surges in the shell, a punch cavity is used, communicating with the shell cavity through a throttling element. The presence of a throttling element allows you to control the law of change of gas pressure in the shell. The stiffness of the shaper as a whole is determined by the parallel connection of the pneumatic elastic element and a set of elastic gaskets.

The main disadvantage of the described stand is the structural complexity of its main node - the shock pulse shaper, which affects the accuracy of the reproduction of the parameters of the latter. Almost the entire design of the shaper is a combination of various kinds of elastic systems. This includes, first of all, an inflatable elastic shell equipped with a throttle connecting it to the punch. In addition, the shaper has an elastic gasket, as well as a set of elastic gaskets located inside the shell. If we take into account the specific, sharply increasing nature of the shock load perceived by the shaper, which in this case is a multi-oscillatory system, then the appearance of spurious vibrations of individual elastic systems that are a consequence of wave processes that occur inside the elastic shell during the propagation of the shock wave and affect thus, on the integral characteristic of the reproduced shock pulse, i.e. on its accuracy. In general, the disadvantages of the prototype are the result of combining two antagonistic functions in the shaper, on the one hand, receiving a shock pulse with strictly specified parameters, and, on the other hand, the perception and suppression of the kinetic energy of the falling table. Traditionally, this contradiction is resolved by separating these functions. So, to reproduce a shock pulse, crashers of various shapes and sizes are used, made of various materials, for example, metal, plastic, wood, which have strictly normalized stiffness, which allows the reproduction of a shock pulse with precisely specified parameters. For the perception and suppression of kinetic energy, the so-called inertial blocks of a special design are used, which have a significant mass.

Thus, the objective of the utility model is to simplify the design of the stand and increase the accuracy of reproduction of the shock pulse.

The problem is solved due to the fact that the stand for shock testing includes a base on which a shock pulse forming device is placed, a device for its suppression, containing inflatable elastic shells equipped with gas pressure regulating means, as well as a table for the tested product mounted to be movable on vertical rods and associated with the mechanism of its lifting and dumping. In this case, the pulse shaping device is made in the form of an anvil to place the crasher mounted on the quenching device, made in the form of an inertial block resting on a number of elastic shells, the first part of which is located on the periphery of the block, and the second in its central zone. All shells are in communication with a source of compressed gas, and their first part also with the outer space through a quick exhaust valve controlled by an accelerometer mounted on the block. The inertial block consists of an upper steel plate connected with a concrete massif, and the block is equipped with through holes, the number of which is equal to the number of all elastic shells placed in these holes and enclosed between the upper covers and supports in the form of cylinders partially placed in these holes and supported on the basis in relation to which the block is installed with a gap. The base is equipped with stops restricting the movement of the inertial block up. The gas pressure in the shells located in the central zone is less than the pressure in the shells located on the periphery. The inertial block has a square shape in plan and peripheral shells, in the amount of four, are located at its corners, and two shells are located in the central zone.

The technical essence of the utility model consists in the fact that the pulse shaper and the suppression device are made separately, and the inertial unit is based on a set of inflatable shells located on the periphery and in the center, while the peripheral part of the shells is communicated with the outer space through the quick exhaust valve controlled by the accelerometer, placed on the inertial block.

In the drawings attached to the description, the following images are given:

in FIG. 1 - inertial block (top view) with a pneumatic circuit;

in FIG. 2 - a fragment of a vertical section of the inertial block.

The stand for impact tests includes a base 1, made in the form of a reinforced concrete box with a square open part. In the box there is a shock absorber (hereinafter referred to as the inertial block) 2, consisting of a square steel plate 3 connected with a reinforced concrete mass 4. The inertial block 2 is equipped with a number of through holes, four of which are located on the periphery of the block in its corners, two others holes are made in its central zone. In all the openings are located the same type of inflatable, flexible shell 5. They are enclosed between removable covers 6, indicated in FIG. 1 by dashed lines, and supports 7 in the form of cylinders partially placed in the holes and resting on the bottom of the box, and between the lower part of the block 2 and the bottom of the box there is a gap in size, slightly exceeding the stroke of the block 2 under the action of the shock load. A cylindrical anvil 8 is installed on the steel plate 3, on which, during the tests, a device for generating a shock pulse in the form of a crusher 9 is located. Anvil 8 is placed on the center of gravity of the inertial block 2, in which there are two additional (except for six named) holes for vertical rods 10 serving as guides for a movable table 11 carrying a test article. The mechanisms for lifting and dumping the table 11 are not shown in the drawings. The pneumatic circuit of the inertial unit 2, in addition to the peripheral and central shells 5, includes a source of compressed air in the form of a compressor 12 kinematically connected to the electric motor 13. The compressor 12 is connected to the shells 5 through pipelines 16 through pipelines 16 and forms two independent pneumatic systems - peripheral and central, separated from the receiver by 14 taps 17 and 18, respectively. Both pneumatic systems are equipped with gauges 19 for measuring the pressure in the shells 5. A quick exhaust valve 20, for example, of the VXFA22AAA type, electrically controlled by shock accelerometer 21, mounted on the surface of the steel plate 3 of the inertial unit 2, is integrated in the pneumatic system covering the peripheral shells 5. the walls of the box fixed stops 22, restricting the movement of the block 2 up.

Works stand for impact tests as follows.

Table 11, with the tested product attached to it, is connected to the rods 10 by a lifting and dumping device in the upper position. The compressor 12 is driven by an electric motor 13 and the receiver 14 is filled with compressed air. The pressure and quantity of air in the latter must be such as to provide different pressures in the shells 5 of both pneumatic systems. So, in the central pneumatic system, the pressure in both shells 5 should create a force slightly exceeding the weight of the inertial block 2, including the weight of the anvil 8 and the cracker 9. Under the action of this force, the inertial block 2 is pressed against the stops 22. In the peripheral pneumatic system, the air pressure in the four shells 5 should ensure complete suppression of the kinetic energy of the impact of the falling table 11, which will cause some subsidence of the inertial block 2 and its exit from contact with the stops 22. The compressed air pressure in the shells of the central pneumatic system will less air pressure than the peripheral pneumatic membranes. The air pressure in the central pneumatic system is determined by a simple calculation, and in the peripheral pneumatic system by experience. The parameters of the air supplied by taps 17 and 18 from the receiver 14 to both pneumatic systems are controlled by pressure regulators 15 and sensors 19. After filling the shells 5 of both pneumatic systems with compressed air, under the conditions specified above, table 11 is reset and sliding along the rods 10 interacts with the crasher 9, thus reproducing the shock pulse with a given leading edge. Naturally, the kinetic energy of the falling table 11 is transformed into the potential energy of additional compressed air in the shells 5 of both pneumatic systems. To neutralize a significant share of the potential energy of compressed air in the shells 5 of the peripheral pneumatic system, a quick exhaust valve 20 opens on command from the accelerometer 21 and the pressure in these shells drops to atmospheric level. The inertial unit 2 in this case is not exposed to any forces from the side of the shells 5 of the peripheral pneumatic system, i.e. there is no so-called recoil, and therefore, to a large extent, parasitic oscillations accompanying it, affecting the accuracy of reproduction of a shock pulse. Thus, the inertial unit 2, which has lost the return energy, lies on two shells 5 of the central pneumatic system, which slowly raise it to contact with the stops 22. The command for depressurizing the shells 5 of the peripheral pneumatic system through the quick exhaust valve 20 is the moment the acceleration sign changes to the opposite the accelerometer 21, which occurs when the table interacts with the crasher 9, and therefore with the inertial block 2. After the pressure is released in the shells 5, the quick exhaust valve 20 is automatically closed.

To carry out the next test, the shells 5 of the peripheral pneumatic system, by opening the valve 17, are filled with compressed air under pressure, set by the pressure regulator 15, built into this pneumatic system and controlled by the corresponding sensor 19. Table 11 is brought to the upper position by means of a lifting and dumping device. On the anvil 8, another crusher 9 is installed. If necessary, the shells 5 of the central pneumatic system can be pumped.

Claims (5)

1. The stand for impact testing, including the base on which the shock pulse forming device, its damping device, including flexible inflatable membranes equipped with gas pressure control means, as well as a table for the test product mounted with the possibility of movement on vertical rods and connected with the mechanism of its lifting and discharge, characterized in that the pulse shaping device is made in the form of an anvil for placement of the crasher mounted on the extinguishing device in the form of an inertial block based on a number of elastic shells, the first part of which is located on the periphery of the block, and the second in its central zone, while all shells are in communication with a source of compressed gas, and the first part also with the outer space through a quick valve exhaust controlled by an accelerometer mounted on a block. 2. The stand according to claim 1, characterized in that the inertial block consists of an upper steel plate connected to a concrete massif, while the block is equipped with through holes, the number of which is equal to the number of all elastic shells placed in these holes and enclosed between the upper covers and supports in the form of cylinders, partially placed in these holes and resting on the base, in relation to which the unit is installed with a gap. 3. The stand under item 1, characterized in that the base is equipped with stops that limit the movement of the inertial block up. 4. The stand according to claim 1, characterized in that the gas pressure in the shells located in the central zone is less than the pressure in the shells located on the periphery. 5. The stand according to claim 1, characterized in that the inertial block has a square shape in plan and the peripheral shells, in an amount of four, are located at its corners, and two shells are located in the central zone.