SU590599A1 - Device for checking physical-mechanical parameters of interaction between objects - Google Patents

Description

The invention relates to controlling parameters of a physicomechanical interaction of a solid and can be used to determine the physicomechanical properties of various samples of a solid made in the form of appropriate models, as well as in devices for orientation in magnetic fields.

A device is known for monitoring the parameters of the physicomechanical interaction of ferromagnetic objects, which contains the source of the magnetic field and the unit supplying the objects to this field by the target ballistic function, the trajectory of the objects are determined by the parameters of their physicomechanical interaction 1.

However, the accuracy of controlling the parameters of the physicomechanical interaction with such a device is insufficient, since the trajectory of movement is roughly fixed by the location of the nodes for receiving moving objects,

It is also known a device for monitoring the parameters of the physicomechanical interaction of objects, comprising a hollow body filled with liquid, a hollow float capsule immersed in it, and an indicator of orientation of its axes 2 rigidly connected with the capsule.

This device is closest to the invention in its technical essence and the effect achieved.

However, the accuracy of control of an ethnm device is also insufficient, since it lacks the means for dpnamic centering of its units relative to each other.

The purpose of the invention is to improve the accuracy of the control.

For this, the proposed device is equipped with two toroidal inductors, between which a body is fixed, freely povdegpenny on a vertical rigid thread, and the indicator axes of the axes are made in the form of a polyhedral mirror, rigidly connected with the capsule, the receiver of the reflected light beam from it.

FIG. 1 schematically shows the proposed device; in fig. 2 - orientation indicator of the model axes.

The device is made of non-magnetic alloys.

Claims (2)

It contains a hollow body 1, illuminated on a vertical rigid thread 2 and filled with liquid 3, for example, liquid gallium, in which the float capsule 4 is immersed in the floor, indicator 5 of its axes that is rigidly attached to the capsule, fixed on the capsule of the controlled model 6 (object) , for example, from ferromagnetic material, inductors 7 and 8 of toroidal shape. The axis orientation indicator 5 is made in the form of a multi-faceted mirror 9, screens 10 and 11 (a receiver of reflected light from an object), laser beams 12 (not shown). The device works as follows. In the non-working state, arresting of the magnetic model 6 is achieved by solidifying liquid gallium (mp. 30 ° C), in which capsule 4 with the magnetic model is immersed. Heating of liquid gallium is achieved by passing a direct current through the coils. Thereafter, the magnetic model 6 is centered by the fields of the inductors 7 and 8, which are excited by an adjustable current. In the gravity field, orientation is carried out by suspending the threads 2 of the housing 1. When external physical fields, such as magnetic fluxes, are applied to the device, forces are created that rotate or translate the object of control in the device. The arising moments and forces are recorded by the movement of laser rays reflected from the object on the screens. Claims of Invention A device for monitoring the parameters of the physicomechanical interaction of objects, comprising a hollow body. a liquid filled, hollow float capsule immersed in it and indicator of orientation of its axes rigidly connected with the capsule, characterized in that, in order to increase the control accuracy, it is equipped with two toroidal inductors, between which the case is fixed, freely suspended on a vertical rigid string, and the axis orientation indicator is made in the form of a multi-faceted mirror rigidly connected with the capsule, and a receiver of a reflected light beam from it. Sources of information, taken into account during the examination 1. USSR author's certificate number 247581, cl. G01 N 27/80, 1967. 2. Bromberg, P.V., et al. Gyroscopic Systems, Part P1, M., “Higher Scale, 1971, p. 260