SU149632A1 - Method for electrical simulation of non-stationary motion of bodies in a liquid - Google Patents

Description

Methods for electrical simulation of non-stationary are known: the movement of bodies in a liquid. These methods do not provide the possibility of determining with sufficient accuracy the added masses.

The proposed method does not have these disadvantages.

This is achieved by cutting the profile under study from a sheet of low-gain electrically conductive paper, along which electrodes are installed, and the boundary conditions on the circuit are carried out by alternating resistors connected to the feed channels, the value of which is adjusted in accordance with the profile movement pattern in the liquid.

In this case, a cut in the shape of the profile under study is made in a sheet of low-resistance electrically conductive paper. The contour line along which it is required to carry out a given boundary condition is drawn at a certain distance from the edge of the model and is divided into equal sections, after which the area bounded by this curve and the edge of the model along which the electrodes are located is cut into separate strips insulated from each other. friend a sheet of ordinary paper. The electrodes are fixed on a Plexiglas plank, which is pressed against electrically conductive paper with screws. If the profile has two lines of symmetry, then the power channels are connected only to one of the buses, and the second bus is located along the edge of the model. In this case, the fulfillment of the following condition: φ const, where φ is the potential velocity. Df distribution

functions determined by the conditions of the problem, allows you to calculate

No. 149632- 2 relative distribution of current forces in individual feed channels:

/..:.L. -. /,

 : - R, dp

where is the specific surface resistance of the paper, / is the number of sections of the contour line.

Since a variable resistance is included in each power channel of the model, which is 3-4 times more than the specific surface resistance of the model, and the largest potential drop in the model does not exceed 0.1% of the voltage between the buses, it is possible to calculate the current in individual channels consider the model as a node and assume that all channels are connected in parallel.

Thus, it can be assumed that the current strength in each channel is determined only by the voltage between the buses (U) and the channel resistance ();

/ - i K.

and in order to obtain a given distribution of currents, it is sufficient to include the corresponding resistances in the channels.

Channel resistances are adjusted using a bridge circuit to measure potentials. A branch containing a reohord and resistance shops is connected to the tires (one for one-way mode and two for two-sided), and the resistances of the stores are chosen so that the potential drop on the reichord corresponds to the potential distribution in the model and the potential of any point can be measured .

Tests of the proposed method gave positive results. Thus, the proposed method allowed determining the attached masses for the frames with an accuracy of 1-2%.

Subject matter

A method of electrical simulation of unsteady motion of bodies in a liquid, characterized in that, in order to determine the attached masses, the profile under study is cut out of a sheet of low-resistance electrically conductive paper along which electrodes are installed, and the boundary conditions on the contour are performed by high-impedance variable resistances connected to the feed channels, the value of which is adjusted in accordance with the nature of the engine profile in the liquid.