SU944600A1 - Method of automatic control of fractionation process - Google Patents

Description

15Approachment without agreement at the point of discontinuity AS AS, equal to E of the value of the control action (and at least the first derivative) leads to the emergence of auto-oscillation modes; a change in the pressure drop in the column (e.g., dynamic modes) strongly deforms (including qualitatively) the temperature profile, and the optimal profile used as a target remains unchanged, i.e. a quality error is possible. All this leads to increased energy costs.

The purpose of the invention is to reduce energy consumption by improving the quality of regulation.

The goal is achieved by the fact that the flow of coolant and irrigation change, depending on the sum of the logarithms of the ratios of temperature differences measured at different points in the column, maintaining the product of the flow from the input to the flow rate of the coolant constant.

The drawing shows a circuit for implementing the proposed control method.

The method is carried out as follows.

In distillation column 1, several temperature sensors 2 are installed. Bi the differential device 3 calculates the indicator К-р, which as a variable is fed to the regulator 4. The output value from the regulator 4 is fed as a task G to the regulator 5 of the coolant flow rate and the calculating unit 6 generating the control F Torus 7 irrigation flow. The necessary adjustment of the operating modes of the entire column is determined by specifying a single K value. The K value is calculated as the sum of the logarithms of the temperature ratios measured at different points of the column by sensors 2.

K g GGP.

t, .1 t TpM-Tem / where measurement points. temper atyra, moreover, i f i, r #: Cm; m - addendum number

in the amount of; n is the number of terms in

sum, n 1.

The selection of control points for each type of column and the mixture to be divided and can be determined experimentally or by computer simulation on a computer as follows: temperatures are selected in the numerator of the terms, the difference of which increases with increasing flow

heat carrier 1 or a decrease in supply of intercourse) and decreases with a decrease in supply of heat carrier (or an increase in supply of irrigation), in the denominator of the terms, those sherathures are selected, the difference of which decreases with an increase in supply of heat carrier (or increase in irrigation), and increases with a decrease in supply of heat transfer fluid (or increase in irrigation); This uses the value of temperatures at specific points of color, especially invariant ones, so that the least sensitivity is to changes in the composition of the diet.

Computing unit b implements the dependency

$ I (2)

those. This device generates a task for the reflux flow rate controller (f), taking into account the constant Production of the task of the heat carrier flow to set the irrigation flow rate (f-C a const) .1

When disturbances occur (external, such as the composition of the feed or internal, such as a change in pressure drop), the temperature profile along the height of the column changes, and the K value changes accordingly. When it deviates from the set value (puller 4 produces a control in the form of a setpoint to the coolant flow controller, while the setpoint of the irrigation flow controller changes in the opposite direction as many times as the setting of the coolant flow controller has changed.

If possible, power consumption should be stabilized. The change in composition (the amount of volatile substances in the feed) should be in the range of 1020 wt.%. The functions of the blocks 3,4,6 can realize the digital control machine 8. Regulators 4,5,7 realize the standard Pi-law of regulation.

Claims (2)

1. Patent SOL 2684326, cl.203-2, 1951. 2. Authors certificate of the USSR 509280, cl. B 01 D 3/42, 1974.