RU168472U1 - SHOCK TEST STAND - Google Patents

Abstract

The invention relates to the field of mechanical engineering, in particular to test equipment related to impact test benches. The stand contains a control unit for its elements, a base on which, relying on a pneumatic cushion, an inertial unit carrying an anvil for placing the crasher and connected by means of guide rods to the shock table designed to install the test product and equipped with a device for lifting it. At least four pneumatic cylinders are introduced between the shock table and the inertial block along the perimeter of the latter, equipped with quick exhaust valves in the gas supply system. The inertial unit has a rectangular shape in plan and at its corners horizontal movable supports are placed that can interact through force sensors with the shock table, which, in turn, act on the pneumatic cylinders using the bench control system through a system for supplying them with compressed gas. Effect: increasing the accuracy of reproduction of a shock pulse. 4 s.p. f-ly; 2 ill.

Description

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

A known test bench design described in RU145751. It includes a base 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 an inertial block) consisting of a square-shaped steel plate connected to a reinforced concrete massif. The inertial block is equipped with a number of through holes, four of which are located at the periphery of the block in its corners, two other holes are made in its central zone. In all the openings are the same type of inflatable elastic shell forming a pneumatic pillow. They are enclosed between removable covers and supports in the form of cylinders, partially placed in holes and resting on the bottom of the base, and between the bottom of the block and the bottom of the box there is a gap in size, slightly exceeding the stroke of the block under the influence of shock load. An anvil is installed on the steel plate, on which in the process of testing there is a device for generating a shock pulse in the form of a cracher. The anvil is placed on the vertical line of the center of gravity of the inertial block, in which there are two additional (except for the six named) holes for vertical rods serving as guides for the shock table mounted with the ability to move, carrying the test product. The mechanism of lifting and dumping the table is a conventional rope winch mounted above the stand. In addition to the peripheral and central shells, the pneumatic circuit of the inertial unit includes a source of compressed air in the form of a compressor kinematically connected to an electric motor. The compressor through the receiver and pressure regulators through pipelines connected with the shells, forming two separate pneumatic systems - peripheral and central. Both pneumatic systems are equipped with sensors for measuring pressure. A quick exhaust valve, for example, type VXFA22AAA, electrically controlled by an accelerometer mounted on the surface of a steel plate of an inertial unit, is built into the pneumatic system covering the peripheral shells.

The main disadvantage of the described stand is the practical impossibility of achieving the horizontal position of the shock table when it interacts with the cracher located on the anvil of the inertial block. Even with precise guide rods and their verticality with respect to the shock table, there is no guarantee that the table remains level when it falls. As practice has shown, the cause of the skew of the table is the instability of the friction forces in the guide rods and their pliability, which ultimately leads to a violation of the accuracy of interaction with the crash. This circumstance causes errors that affect the accuracy of reproduction of the shock pulse. Another disadvantage is the need for accurate placement of the test product, or rather its center of gravity, in the center of the shock table symmetrically with respect to the guides. Slight displacement of the product also affects the accuracy of the reproduction of the shock pulse.

Thus, the objective of the utility model is to increase the accuracy of reproduction of a shock pulse.

The task is achieved due to the fact that in the stand for impact testing, containing the control unit of its elements, the base on which is mounted, relying on a pneumatic pillow, an inertial unit carrying an anvil for placement of the crasher and connected by means of guide rods to the shock table designed at least four pneumatic cylinders are inserted between the shock table and the inertial block along the perimeter of the latter for installing the test article and its lifting device. The latter are equipped with compressed gas and quick exhaust valves in their supply system. At the same time, the inertial block has a rectangular shape in plan and horizontally movable supports are placed at its corners, which can interact through force sensors with the shock table, which, in turn, act on the pneumatic cylinders through the system for controlling them gas. The task is also facilitated by the fact that the shock table is in the form of an inertial block, and the device for lifting it is made of at least four pneumatic cylinders and custom screw stops that limit the lifting of the table and are located at its corners. The air bag is connected to a source of compressed gas. Pneumatic cylinders are located at the corners of the inertial block. The inertial unit is additionally connected to the base using shock absorbers.

The technical result consists in the fact that a technical system was introduced in the stand for shock testing, which ensures the horizontal position of the shock table when it interacts with the crasher, which significantly increases the accuracy of the reproduction of the shock pulse.

In the drawings (Figs. 1 and 2), attached to the description, images of fragments of a general view of a stand for impact tests are given.

The stand contains a control unit 1, conditionally summarizing the stand infrastructure, including a compressor station, electro-pneumatic equipment (valve distributors, etc.), while the drawings provide images of those stand elements and the connections between them that are sufficient to explain the stand design and principle his works. The base of the stand is a plate 2, on which there is a pneumatic cushion, made in the form of a set of elastic shells 3 connected with a compressor. An inertial unit 4, bearing an anvil 5, is used to support the pneumatic cushion. Between the inertial block 4 and the base 2, an additional connection is introduced in the form of shock absorbers 7. A shock table 8 is installed over the block 4 at a certain distance, on which the test item 9 is installed during testing. The inertial block 4 is connected to the shock table 8 using four guide rods 10 located at the corners of the block. Next to each of the rods 10 are mounted pneumatic cylinders 11, the rods and bodies of which are connected to the shock table 8 and block 4. Here, on each corner of the block 4, there are mounted horizontal supports 12, bearing force sensors 13 on their contact surface. Reciprocating The supports 12 are moved using pneumatic cylinders 14 connected to the inertia block 4. The lower cavity of each of the pneumatic cylinders 11 is simultaneously connected to the compressed gas source of block 1, as well as to the quick exhaust valve 15, for example, type VXFA22AAA . Impact acceleration is measured by an accelerometer 16 mounted on the table 8. The stand at each corner is equipped with a pair of interacting stops 17 and 18, the first of which is connected to the shock table 8, and the second to the screw of the screw mechanism 19, mounted on the inertial block 4 from the outside.

Works stand for impact tests as follows.

Block 1 is included in the work, and therefore all of the aforementioned infrastructure equipment of the stand. Previously, with the help of the screw mechanism 19, the estimated height of the impact table 8 is set by the stop 18, on which the test product 9 is pre-mounted. The stops 18 are set to the “horizon”. Then, compressed gas is supplied to the pneumatic cylinders 11 and the shock table 8 rises up to the contact of its stop 17 with the emphasis 18. The pneumatic cylinder 14 of the support 12 is brought under the table 8 and after that the pressure in the pneumatic cylinders 11 is relieved, redistributing the weight of the table 8 from the rods of the pneumatic cylinders 11 to the supports 12 Each force sensor 13 located on the supports and interacting with the lower part of the table 8, fixes its part of the weight of the table with the product and with a difference in readings on the individual supports 12, i.e. the uneven distribution of weight, mainly of the product, gives the appropriate command to block 1, by which compressed gas is supplied to each of the pneumatic cylinders 11 with a pressure that balances its share of the weight of the shock table with the product. Naturally, the pressure of the compressed gas in the pneumatic cylinders will be different. However, this makes it possible to achieve a strict horizontal table 8 and to exclude its skew at the stage of falling and interacting with the crash, which significantly increases the accuracy of reproduction of the shock pulse. After the process of "leveling" of the table is completed, the cylinder rod 14 is retracted, the supports 12 release the table 8 and a command is sent from block 1 to reset the table. In this case, with the help of quick-release valves, the piston cavity of the cylinders 11 is connected to the atmosphere, and the table 8, without changing its horizontal position, freely falls on the crasher 6. The kinetic energy of the falling table is extinguished by the large mass of the inertial unit 4, the buildup by the shock absorbers 7. Pillows 3 reduce the impact of the inertial block on the foundation and workshop equipment.

Claims (5)

1. Impact test bench, comprising a control unit for its elements, a base on which is mounted, relying on a pneumatic cushion, an inertial unit carrying an anvil for placement of the crasher and connected by means of guide rods to the shock table intended for installation of the test product and equipped with a device its lifting, characterized in that between the shock table and the inertial block along the perimeter of the latter, at least four pneumatic cylinders are introduced, provided in their support system compressed gas by quick exhaust valves, while the inertia block has a rectangular shape in plan and horizontal supports movable in the horizontal direction are placed at its corners, which can interact through force sensors with the shock table, which, in turn, act with the aid of the bench control system to pneumatic cylinders through a system for providing them with compressed gas. 2. The stand according to claim 1, characterized in that the shock table has the shape of an inertial block in plan, and the device for limiting its lifting is made of at least four adjustable mechanical stops located at the corners of the table. 3. The stand according to claim 1, characterized in that the air bag is connected to a source of compressed gas. 4. The stand according to claim 1, characterized in that the pneumatic cylinders are located at the corners of the inertial block. 5. The stand according to claim 1, characterized in that the inertial block is additionally connected to the base with the help of shock absorbers.

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