SU763716A1 - Impact test arrangement - Google Patents

Description

one

The invention relates to a test apparatus, in particular, to stands for testing products for shock loads.

Impact test benches are known, comprising a platform for securing the tested product, a device for lifting and dumping the platform, a device for forming | Q

load impulse when striking a platform against it and a device to prevent repeated shocks 1.

Such stands are complex in design and have a limited supply of energy and rot to disperse the platform.

The closest to the invention according to the technical essence and the achieved effect is a shock test stand containing a platform for securing the test product, a platform acceleration drive and brake cylinders filled with fluid with pistons and rods connected to platform 2. The actuator 25 is designed as a cylinder with a piston connected to the platform. One of the cavities is supplied with gas to accelerate the platform, and the other is used as a load driver 30

(due to the compression of gas in it when the piston is moving). There is no possibility of adjusting the shape of the load, which does not allow to reproduce the specified load with sufficient accuracy. Another disadvantage of the stand is the complexity of its design, due to the presence of brake cylinders, which are used only to prevent repeated shocks.

The aim of the invention is to simplify the design and improve the accuracy of reproduction of a given load.

The goal is achieved due to the fact that the stand is equipped with controllable electro-hydraulic valves installed on the fluid discharge from the cylinders and a control system for adjusting the voltage of the electric field in the valves, and electric fluids are used in the cylinders.

The stand is shown schematically in the drawing.

The stand contains a platform 1 for fixing the test product 2, a drive for accelerating the platform 1, made in the form of a cylinder 3 with a piston

4, rigidly connected to platform 1. Rods 5 connected to pistons 6 installed in brake cylinders 7 are also rigidly connected to platform 1. The latter are filled with electrofusion fluid 8. Controlled electro-hydraulic valves are installed at the discharge of fluid 8 from cylinders 7 . Each of them contains a housing 9 and plates 10, between which the fluid 8 passes. The plates 10 are connected to the rectifier 11, which is connected to the control system, which is used in this case by the computer 12. The presence of the computer 12 and the rectifier 11 adjust the intensity of the electric field between the valve plates 10, thereby changing the fluid's viscosity 8.

The stand works as follows

The memory of the computer 12 is loaded with the parameters of the load pulse, for example, in the form of an array of numbers corresponding to the acceleration values of the platform at specified times. A predetermined pressure is applied to cylinder 3. The valves are closed at this time, i.e. plates 10 are energized, making it impossible for fluid 8 to leak through the valves. This voltage is then released, fluid 8 is able to flow out of cylinders 7, and pistons 6 with rods

5, platform 1 and product 2 begin to accelerate under the action of pressure in cylinder 3. The signal from the accelerometer installed on platform 1 (not shown) enters the computer 12, where it is compared, with parameters of a given load. As a result of this comparison, a control signal is produced, which is fed to the rectifier 11, changes the voltage on the plates 10, which

causes a change in the voltage of the electric field between them and the viscosity of the fluid 8 in the housing 9. As a result, the movement of the platform 1 with the product 2 is accelerated or braked to reach the specified load parameters.

Thus, in the proposed stand, brake cylinders simultaneously perform the functions of forming

Q load and prevent repeated shots. This simplifies its construction. In addition, the use of an electrically viscous fluid with a controllable valve makes it possible to reproduce acceleration pulses of the most varied forms, accurately simulating operational loads.

Claims (2)

1. USSR Author's Certificate No. 523319, cl. G 01 M 7/00, 1974. 2. Authors certificate of the USSR 560153, cl. G 01 M 7/00, 1975. / ////// L / / W /// y