CS270094B1 - Potential Ramp Connection of Program-Controlled Portable Polarograph - Google Patents

Abstract

The circuit is applicable for generating a potential ramp of a polarograph for powering a microelectrode system in a semi-automatic or automatic mode of operation with the possibility of program control from a computer. The purpose of the solution is easy, fast, accurate and reproducible control of the sample analysis process, processing of measurement results and their archiving, the possibility of program preparation of the operating mode, its reproduction and transfer to other workplaces. This is achieved by solving the problems of the polarograph voltage ramp as a programmable variably controllable feedback system with easy control of the auto mode and connection to a control computer. The solution can also be used in systems using phase control of thyristors for generating linear control voltages within set limits, e.g. a light sensor.

Description

The invention relates to the connection of the potential ramp circuits of a program-controlled portable polarograph.

Modern electroanalytical methods have recently become increasingly important, especially in connection with new ecological, agri-food, biotechnology and industrial programs, see R. Kalvoda: Electroanalytical Methods in Chemical and Environmental Analysis, Plenum Press, New York, 1987. Polarographic and related voltammetric methods with a renewed Hg-electrode contribute significantly to this, especially in new portable modifications. They allow to determine even very small concentrations of products or intermediates, but also pollutants, such as heavy metals, herbicides, etc. Previously produced polarographic sets with mercury drop electrode work with a limited range of parameters of working polarographic modes, including options very wide range, setting the course of the potential ramp, program control of the measurement process in semi-automatic mode, all in connection with the quantity of measurements, speed and accuracy of measurement, recording and processing of program-connected results while meeting high requirements for accuracy and miniaturization, for Wide use, see AM Bond: Poljarografičeskije metody v analitičeskoj chimii, Moscow, 1983. In connection with the preparation for the production of new mini-, semimicro- and microelectrode systems, as well as entire portable polarographic systems, necessary and useful to extend the parameters of classical polarographic modes while using automation. The reason is the need to increase the sensitivity of the measurement, which is still lower for small electrodes under normal conditions, as well as the need to improve the reproducibility of the whole measuring cycle - due to the greater influence of adsorptive impurities than before.

The present invention contributes to solving this problem. Its object is to connect the potential ramp of a program-controlled portable polarograph, the essence of which lies in the fact that its output is the second output of the integrator block, whose first output is connected to the second input of the coupling control block and at the same time the second input of the integrator block is connected to the output at the same time the first input of the integrator block is connected to the output of the range block and the second bus input is connected to the third bus output of the control circuit block and its first input is connected to the first output of the calibration block whose input is connected to the first output of the coupling control block is connected to the second input of the setting block, the first input of which is connected to the sum block output, the second input of which is connected to the auto-tuning block output and its first input is connected to the second output of the control circuit block and at the same time the second input of the comparator block is connected to the second output the binding control block, the first input of which is connected to the output of the adjustment block signal whose input is connected to the output of the selection block, the first bus input of which is connected to the first bus output of the control circuit block and its second bus input is connected to the first bus output of the reference block, the bus input of which is connected to the sixth bus output of the control block circuits and its second bus output is connected to the first bus input of the comparator block, the bus output of which is connected to the second bus input of the reversing block, the first bus output of which is connected to the first bus input of the autoconfiguration block, the second bus input of which is connected to the fourth bus. the output of the control circuit block, the fifth output of which is connected to the first input of the reverse block, the second output of which is connected to the input of the control circuit block.

The connection of the voltage ramp circuits according to the invention allows us to generate the scan speed of the voltage ramp, i. the rate of change of the polarization voltage in a wide range of values from tens of volts per second to units of millivolts per second, allows to stop and restart the scan, precisely holds in the set stop positions ramps, which can be selected programmatically. The ramp is set to the stop position by changing the hardness

CS 270094 B1 feedback so that after the setting signal disappears, its set value remains time-stable and the feedback takes over the function of holding the ramp at this level. The connection also allows us to operate in the autoreverse, when the ramp voltage increases and decreases alternately from one set stop position to another at the speed of the selected scan, or when using auto-tuning, the speeds for setting are increased or decreased. In semi-automatic operation, we can then set that when switching to the default selected stop position, the ramp is set to this position without further ado. Another great advantage is the possibility of controlling and simulating these modes using a program from a control computer connected to the polarograph bus, where the operator only exchanges the measured samples and presses the appropriate button. The results are stored in the computer's memory.

The drawing shows an example of the connection of the voltage ramp circuits according to the invention.

The specific embodiment of the circuit shown in the drawing is such that its output is the second output 132 of the integrator block 13, the first output 131 of which is connected to the second input of the binding control block 10 and at the same time the second input of the integrator block 13 is connected to the output 151 of the setting block 15 and at the same time the first input of the integrator block 13 is connected to the output 121 of the range block 12 and at the same time the second bus input of the 12th range block is connected to the third bus output 193 of the control circuit block 19 and its first input is connected to the first output 111 of the calibration block 11 is connected to the first output 121 of the coupling control block 10 and its second output 112 is connected to the second input of the setting block 15, the first input of which is connected to the output 141 of the sum block 1, the second input of which is connected to the output 171 of the auto-tuning block 17 and its the first input is connected to the second output 192 of the control circuit block 19 and at the same time the second input of the comparator block 22 is connected to the second output 102 of the block 12. controlling the coupling, the first input of which is connected to the output 161 of the signal conditioning block 16, the input of which is connected to the output 181 of the Ig block. whose first bus input is connected to the first bus output 191 of the control circuit block 19 and its second bus input is connected to the first output 211 of the reference block 21, whose bus input is connected to the sixth bus output 196 of the control circuit block 19 and its the second bus output 212 is connected to the first bus input of the comparator block 22, the bus output 221 of which is connected to the second bus input of the reverse block 20, the first bus output 201 of which is connected to the first bus input of the auto-tuning block 17, the second bus input of which is connected to a fourth bus output 194 of the control circuit block 19, the fifth output 195 of which is connected to the first input of the block JO. reverse, the second output 202 of which is connected to the input of the control circuit block 19.

The individual blocks mentioned above can be arranged differently.

We always list one of the possible designs

Block 13 of the integrator consists of an integrator with precise integration capacity, block 11 of calibration consists of bipolar voltage stabilizer limiter and voltage divider with possibility to precisely set dividing memory, block 12 of ranges consists of switch with set of selected series resistors and controllable current signal disconnector, control block 10 It consists of a voltage comparator with set gain, the setting block 15 consists of a controlled switch and a series resistor, the sum block 14 consists of a sum member of two signals, the auto-tuning block 17 consists of switches for selecting a logic function, the comparator block 22 consists of two voltage comparators and hysteresis and circuits for evaluation of the comparison window, block 20 of reversal is formed by analog signal converter to digital memory circuits and other logic circuits, block 18 of selection is formed by controlled switch of reference signal channels, block 21 of reference is formed by voltage stabilizers, variable reference circuits voltage and fi ltry, block 19 of control circuits consists of logic circuits, switches and logic for connecting a computer.

CS 270094 Bl

The function of the specific circuit connection of the voltage ramp according to the invention is to generate a voltage ramp depending on the set scan speed from the set initial position of the ramp to the end position. Allows the ramp voltage to stop at a selected point in time and restart. The ramp voltage is set to the home position using the adjustment function. The circuits allow work in autoreverse and auto-tuning mode. Due to the accuracy and stability of the parameters, the whole system is solved by feedback. The control computer program connected to the system bus can be used to control and set individual functions and modes. The ramp generator itself forms an integrator block 13, which integrates the current signal coming from the range block 12, which selects the rate of increase of the ramp voltage so that a series resistor is added to the voltage signal from the calibration block 11. In the range block 12 is also in the path a disconnector is included in the current signal, which controls the stop of the ramp increase in the block 13 of the integrator, which at this time operates as an analog memory. The range block 12 is controlled by the signals b of the control signal block 19, the calibration block 11 is fed from the coupling control block 10, which consists of a comparator with set gain, which compares the reference signal with the integrator signal of the integrator block 13. the comparator and the action variable are given by the positive or negative saturation of the output of the comparator, which is then fed to the calibration block 11, which turns the undefined value of the saturation voltage into an exact reference signal for the integrator of the integrator block 13 by means of limiting circuits and precise adjustment of the division ratio. In this phase, the integrator integrates a constant input current of the direction given by the direction of the control deviation on the input converter of the link control block 10. Feedback has no sensitivity at this time, ie. that a change in the control deviation does not cause a change in the action variable at the output of the comparator, and it can be said that the feedback is disconnected due to the replacement of the source of the action variable by a source of constant value. Another situation occurs if the voltage on the integrator reaches close to the regeneration voltage - there will already be a small control deviation and the comparator gain will be applied. The action variable will be proportional to the deviation and will keep the output voltage of the integrator at the set reference level. The feedback here acquires great sensitivity and its character can be declared to be trailing. Quick setting of the ramp voltage at the integrator output to the initial position is ensured by the setting block 15, which, on the command from the sum block 14, closes the current signal controllable for the integrator block 13 by maximum feedback. The reference voltage for the coupling control block 10 comes from the signal conditioning block 16, where it is. the selection of the set reference levels in block 21 of reference takes place for block 16 of signal conditioning in block 18 of selection, where the respective selected reference channel is closed by a command from block 19 of control circuits. The automatic switching of the reference levels for the operation in the autoreversion is provided by the comparator block 22 together with the reversal block 20, which it performs by a signal via the control circuit block 19, if this is allowed by the call signal from the control circuit block 19. The comparator block 22 uses two comparators with hysteresis to distinguish whether the feedback is in the open state (smooth and linear increase of the ramp voltage) or has a trailing character (maintaining the ramp voltage at the selected reference value), change from the state of disconnection to the towing character, which is indicated by the comparator window, gives a command to block 20 to reverse the reference change. The comparator block 22 also generates signals distinguishing the direction of ramp voltage increase to the reference stop value, these signals via the reverse block 20, where modified, control the auto-tuning function in the auto-tuning block 17 for the selected direction signals from the control circuit block 19. The resulting setting signal to the setting block 15 is taken as the sum of the setting signals from the auto-setting block 17 and from the control circuit block 19. The references for the comparators of the comparator block 22 are fed from the reference block 21 and the feedback signal being compared comes from the feedback control block 10.

CS 270094 Bl

The circuit according to the invention allows us to generate scan speed ramps of the polarograph ranging in the range of units up to tens of volts per second. Allows you to stop and restart the voltage scan. It shows accurate and fast adjustment of the ramp voltage to the initial position and remaining in this position. Allows operation in car reverse and auto adjustment mode. It guarantees good reproducibility and easy control of the ramp. It allows program control using a computer connectable to the system bus, it speeds up and refines the measurement and processing of results while increasing productivity. The program method of working with a polarograph is suitable for a large number of measurements, where the emphasis is on accuracy and speed and reproducibility of measurements and processing of results and their archiving, allows us to accurately and quickly set the appropriate parameters of the mode * polarograph operation for the selected type of measurement. reduced influence of the human factor on a possible error.

Claims (1)

OBJECT OF THE INVENTION Connection of the potential ramp of a program-controlled portable polarograph, the output of which is the second output of the integrator block, whose first output is connected to the second input of the binding control block and at the same time the second input of the integrator block is connected to the output characterized in that the second bus input of the range block (12) is connected to the third bus output (193) of the control circuit block (19) and its first input is connected to the first output (111) of the calibration block (11), the input of which is connected to the first output (101) of the link control block (10) and its second output (112) is connected to the second input of the setting block (15), the first input of which is connected to the output (141) of the sum block (14) the input is connected to the output (171) of the auto-tuning block (17) and its first input is connected to the second output (192) of the control circuit block (19) and at the same time the second input of the comparator block (22) is connected to the second output pu (102) of the link control block (10), the first input of which is connected to the output (161) of the signal conditioning block (16), the input of which is connected to the output (181) of the selection block (18) whose first bus input is connected to of the first bus output (191) of the control circuit block (19) and its second bus input is connected to the first bus output (211) of the reference block (21), the bus input of which is connected to the sixth bus output (196) of the control circuit block (19) and its second bus output (212) is connected to the first bus input of the comparator block (22), the bus output (221) of which is connected to the second bus input of the reverse block (20), the first bus output (201) of which is connected to the first bus input of the auto-tuning block (17), the second bus input of which is connected to the fourth bus output (194) of the control circuit block (19), the fifth output of which is connected to the first input of the reversing block (20), the second output (202) of which is connected to the the input of the control block (19) circuits.