SU710051A1 - Device for simulating thermal conductivity coefficient - Google Patents

Description

The invention relates to the field of analog computing and is intended to solve the inverse problem of thermal conductivity in bodies whose thermal characteristics depend on temperature. A device for determining the heat transfer coefficient is known. It contains functional converters a multiplication unit, an adder, a nonlinearity block and a current stabilizer 1. The closest in technical essence to the one under consideration is a device made on a resistor grid and functional converters 2. A disadvantage of the known devices is low speed. The aim of the invention is to expand the functionality of the device and increase its speed. The goal is achieved by the fact that in the device containing a resistive grid, the node point of which is connected to the output of the controlled current source, the comparison unit, the output of which is connected to the input of the integrator, the output of which is connected to the control input of the first functional converter, whose output is connected with the node point of the resistor grid, the voltage divider and the second functional converter, the output of which is connected to the first in: the unit of the comparison unit, the differentiation element and the unit are added the initial parameters, the output of which is connected to the input of the second function of the converter, one output of the differentiating element is connected to the node point of the resistor grid, another output of the differentiating element is connected to the first input of the voltage divider, the second input of which is connected to the output of the first functional converter, and the output of the voltage divider is connected to the input of the controlled current source, the second input of the unit being connected to the node point of the resistor grid. The drawing shows a functional diagram of the device. It contains a resistor grid 1, a differentiating element 2, a controlled current source 3, a divider. -) voltage 4, a functional transducer 5, an integrator 6, a block of equation 7, a functional transducer 8, a block for setting initial parameters 9.

The device works as follows.

The signal from the nodal point of the resistor grid 1 is fed to the input of the comparison block 7, to the second input of which from the initial parameter setting block 9 through the functional converter 8 a voltage proportional to the temperature at the corresponding point of the simulated body is applied, rfa functional converter 8 performs the conversion corresponding to algorithm from the output of the comparator unit 7, the error signal is fed to the input of the integrator 6, the output signal. WHICH controls the element to be controlled functional A converter 5, through which the signal from the nodal point of the resistor grid is fed to one of the inputs of voltage divider 4, to the second input of which voltage is supplied from the nodal point of the resistor grid through a differentiating element, 2. ria functional converter 5 performs signal conversion based on dependency, which is formed during converter operation control by integrator 5 b From the output of voltage divider 4, the voltage is fed to the input of the controlled current source 3. The voltage of the node point of the resistor grid all time follows voltage, formed in block 9,

The device under consideration, due to the presence of new elements and the connections between them, allows us to expand the capabilities of analog computing technology in solving inverse heat conduction problems, as well as reduce the laboriousness and time to solve these problems.

Claims (2)

1. Author's certificate No. 279185, cl. G About G 7/48, 1969. 2. Certificate of authorship on application no. 2478982 / 18-24, cl. G About G 7/48, 1977.