RU2459309C1 - Method of measuring ion concentration and apparatus for realising said method - Google Patents

Abstract

FIELD: physics. ^ SUBSTANCE: in the method of measuring ion concentration, involving charge accumulation on the capacitor of an aspiration chamber when ions of the analysed gas settle on its collecting electrode over a given period of time and subsequent measurement thereof by detecting a pulse arising at the output of the input device during discharge of the capacitor of the aspiration chamber on its input resistance, based on whose parameters ion concentration is determined, wherein ion concentration is determined from the integral value of that pulse, the novelty lies in that ion concentration is determined from the integral value of that pulse at the moment in time when the magnitude of the pulse satisfies the expression: n |f(tu) | = |ecm| + |Iin| R, where n is the measured ion concentration, f(t) is a function which determines the shape of the pulse at the input of the processing device with unit ion concentration, ecm is bias voltage of the integrator in the processing device, lin is the input current of the integrator in the processing device, R is the resistance in the time constant of the integrator in the processing device, tu is the time for detecting the integral of the pulse arising at the output of the input device during discharge of the capacitor of the aspiration chamber. In the apparatus for measuring ion concentration, having an aspiration chamber with a high-voltage power supply, series-connected switch, input device, processing device and indicating device, as well as a control device whose first output is connected to the processing device, the second output is connected to the switch which connects the collecting electrode of the aspiration chamber with the input device, the novelty lies in that it further includes a voltage comparator, the output signal trailing edge of which determines the time for measuring voltage across the output of the processing device using the indicating device, the first input of the comparator is connected to the input of the processing device, the second input is connected to a reference voltage source, the sign of the output voltage - Uon of which matches that of the voltage across the input of the processing device, and its magnitude is determined by the expression: |Uon| = |ecm| + |Iin| R, and the output of the comparator is connected to the second input of the indicating device. ^ EFFECT: high accuracy of measuring ion concentration by reducing measurement error caused by bias voltage and input current of the processing device. ^ 2 cl, 7 dwg

Description

The invention relates to measuring technique and can be used to measure the concentration of air ions both in a free atmosphere and in residential, industrial and other rooms.

A known method of measuring the concentration of gas ions, in which the concentration of ions is determined by the amplitude of the pulse proportional to the measured concentration of ions, the pulse occurs at the output of the input device, the input of which is connected to the collecting electrode of the aspiration chamber through a key, the open time of which is known and set by the control device, and the high-voltage electrode of the camera is connected to its power source (ed. St. USSR No. 474827, Device for counting ions, G06M 11/00, BI No. 23, 1975). The disadvantage of this method is the low accuracy of the measurement, due to the influence of the capacity of the suction chamber on the measurement result, which can change with changing humidity of the test gas, the geometric dimensions of the suction chamber.

A known method of measuring the concentration of ions and a device for its implementation (RF patent for the invention No. 2267186. Method for measuring the concentration of ions H01J 47/04, G01T 1/185, BI No. 36, 2005). The method consists in the accumulation of charge on the capacity of the suction chamber when the ions of the test gas are deposited on its collecting electrode for a given period of time and its subsequent measurement by recording the pulse that arises at the output of the input device when the capacity of the suction chamber is discharged, the ion concentration being determined by the value of the integral of this momentum.

A device that implements this method includes an aspiration chamber with a high-voltage power source, a key connected in series, an input device, a processing device (an integrator built on an operational amplifier) and an indication device, as well as a control device, the first output of which is connected to the processing device, and the second the output goes to the key connecting the collecting electrode of the suction chamber to the input stage.

The disadvantage of the known invention adopted for the prototype is the low accuracy of the measurement, due to the bias voltage and the input current of the processing device (integrator).

The technical result to which the claimed invention is directed is to increase the accuracy of measuring the ion concentration by reducing the measurement error caused by the bias voltage and the input current of the processing device.

The technical result is achieved by the fact that in the method of measuring the concentration of ions, which consists in the accumulation of charge on the capacity of the suction chamber when the ions of the test gas are deposited on its collecting electrode for a given period of time and its subsequent measurement by recording the pulse that occurs at the output of the input device when the suction capacity is discharged cameras on its input resistance, in which the concentration of ions is determined by the value of the integral of this pulse, new is that the concentration of ions is about redelyayut largest integral of the pulse at the time point when the pulse value satisfies the expression module

where n is the measured ion concentration, f _(t) is the function that determines the shape of the pulse at the input of the processing device at an ion concentration of one unit, e _cm is the bias voltage of the integrator in the processing device, I _in is the input current of the integrator in the processing device, R is resistance in the time constant of the integrator in the processing device, t _and is the time instant of registration of the integral of the pulse arising at the output of the input device when the capacity of the suction chamber is discharged.

In the device for measuring the concentration of ions, containing an aspiration chamber with a high-voltage power source, a key, an input device, a processing device and an indication device, as well as a control device, the first output of which is connected to the processing device, and the second output is supplied to the key connecting the collecting the electrode of the suction chamber with an input device, new is that it additionally contains a voltage comparator, the trailing edge of the output signal of which determines m The time of measuring the voltage at the output of the processing device by the indicating device, the first input of the comparator is connected to the input of the processing device, and the second input is connected to a reference voltage source, the sign of the output voltage of which is U _op coincides with the sign of the voltage supplied to the input of the processing device, and its module defined by the expression

and the output of the comparator is connected to the second input of the display device, where U _op is the output voltage of the reference voltage source, e _cm is the bias voltage of the integrator in the processing device, I _in is the input current of the integrator in the processing device, R is the integrator resistance in the time constant of the processing device .

The invention is illustrated in figures 1-7.

Figure 1 shows a structural diagram of a device for measuring the concentration of ions.

Here: 1 - high-voltage power supply of the suction chamber; 2 - aspiration chamber; 3 - a key connecting the collecting electrode of the suction chamber to the input stage; 4 - input device; 5 - processing device (an integrator built on the operational amplifier DA1 and having an integration constant τ = RC); 6 - indication device; 7 - voltage comparator; 8 - control device; U _op is the output voltage of the reference voltage source, N is the measurement result.

Figure 2-7 shows the voltage diagrams at the outputs of the elements of the device at two values of the measured ion concentration, and the measured concentration n ₁ (diagrams indicated by the letter a) is less than the measured concentration n ₂ (diagrams are indicated by the letter b).

Figure 2 - plot voltage at the input of the processing device (output of the input device); figure 3 - plot of the output voltage of the comparator; figure 4 - plot of the output voltage of the processing device (integrator); 5 is an error in measuring the ion concentration caused by the limitation of the time for measuring the voltage at the output of the processing device (integration time); 6 is an error in measuring the concentration of ions caused by the bias voltage and the input current of the processing device; 7 is the total error of measuring the concentration of ions, t _{and 1} is the time instant of measuring the voltage at the output of the processing device at an ion concentration of n ₁ , t _{and 2} is the time instant of measuring the voltage at the output of the processing device at an ion concentration of n ₂ .

A device for measuring the concentration of ions contains an aspiration chamber 2 with a high-voltage power supply 1, a key 3 connected in series, an input device 4, a processing device (integrator built on an operational amplifier) 5, an indication device 6, and a control device 8, the first output of which is connected with the processing device 5, and the second output is supplied to the key 3, connecting the collecting electrode of the suction chamber 2 with the input device 4, and a voltage comparator 7, the trailing edge of the output signal of which limits the time point of measuring the voltage at the output of the processing device 5 by the indicating device 6. The first input of the comparator 7 is connected to the input of the processing device 5, and the second input is connected to a reference voltage source, the sign of the output voltage of which - U _op coincides with the sign of the voltage supplied to the input of the device processing 5, and its module is determined by the expression

The output of the comparator 7 is connected to the second input of the indicating device 6.

In this expression it is indicated: - U _op is the output voltage of the reference voltage source, e _cm is the bias voltage of the processing device (integrator), I _in is the input current of the processing device (integrator), R is the resistance in constant time of the processing device (integrator).

The device operates as follows.

When purging the test gas through the suction chamber 2, ions from the test gas are deposited under the influence of the electrostatic field created by the high-voltage power source of the chamber 1 on the high-voltage and collecting electrodes. After the key 3 is opened, the control device 8 on the collecting electrode of the chamber 2, due to the deposition of ions, a charge accumulates, the value of which is determined by the expression

where Q is the magnitude of the charge, C;

C is the capacity of the collecting electrode of the suction chamber, f;

U is the voltage across the capacitance of the collecting electrode of the suction chamber arising from the deposition of ions, V;

V is the volumetric flow rate of gas through the suction chamber, cm ³ / s;

T _n - open time of the key 3, sec;

е = 1.6 · 10 ^-19 C - the charge of one ion;

n is the measured ion concentration, 1 / cm ³ .

At the end of time T _n , at time t = 0, according to the signal from the control device 8, the indications of the indicating device 6 are reset to zero, the key K of the processing device 5 opens, and the key 3 closes. When the key 3 is closed, a voltage pulse appears at the output of the input device 4 (Fig. 2), the shape of which is determined by the input device circuit, but its amplitude and area are proportional to the measured ion concentration. The trailing edge of this pulse has infinite duration, since it is determined by the discharge of the capacitance of the collecting electrode of the aspiration chamber through the input resistance of the input stage. For this pulse, we can write the expression

where f _(t) is a function that determines the voltage pulse at the output of the input device (integrator input) at an ion concentration of unity. Without violating the generality of reasoning, we can assume that this quantity is positive.

This pulse is fed to the input of the processing device 5. Since the integration time is limited, and the processing device (operational amplifier DA1) has an input current and bias voltage, we obtain for the output signal of the processing device (Volkenberry L. Application of operational amplifiers in linear ICs. from English M .: Mir, 1985, 572 p.) (Fig. 4, a, b):

where e _cm and I _in are the bias voltage and input current of the operational amplifier DA1 (positive values), t _and are the time instant of registration of the integral of the pulse arising at the output of the input device 4 when the capacity of the suction chamber 2 is discharged (integration time).

Expression (3) corresponds to the worst case (the largest integration error). This is explained by the fact that in practice it is advisable to use a single processing device when measuring the concentration of both positive and negative ions, and in the reference literature the signs _cm and I _in do not lead.

Then the absolute value of the integration error caused by the limitation of the integration time, input currents and bias voltage is determined by the expression:

From the expression (4) it is seen that with increasing integration time, the error component in parentheses decreases and tends to zero (Fig. 5, a, b), and in squares it increases (Fig. 6, a, b). When the integration time decreases, on the contrary, the error component in parentheses increases, and in square brackets it decreases and tends to zero. That is, it can be argued that there is an integration time at which the absolute integration error will be minimal (Fig. 7, a, b). Differentiating expression (4) with respect to t _and , and equating the resulting equation to zero, we obtain that the absolute value of the integration error will be minimal if the condition

That is, to obtain the minimum integration error, and hence the error of measuring the ion concentration, the voltage at the output of the processing device must be measured at a time when the voltage at its input reaches a value equal to (Fig. 3, a, b):

To implement this, it is enough to introduce a voltage comparator into the device in question, to one input of which to apply the input signal of the processing device, and to the second - a reference voltage of the same polarity as the input signal, and equal (Fig. 3, a, b):

In this case, a voltage pulse appears at the output of the comparator, on the trailing edge of which it is necessary to measure the voltage at the output of the processing device.

Thus, for any value of the measured concentration of ions, the proposed device allows you to measure their concentration with the least error.

Claims (2)

1. The method of measuring the concentration of ions, which consists in the accumulation of charge on the capacity of the suction chamber when the ions of the test gas are deposited on its collecting electrode for a given period of time and its subsequent measurement by recording the pulse that arises at the output of the input device when the capacity of the suction chamber is discharged to its input resistance in which the concentration of ions is determined by the value of the integral of this pulse, characterized in that the concentration of ions is determined by the value of the integral of the pulse in point in time when the magnitude of the pulse modulus satisfies the expression

where n is the measured ion concentration;

- a function that determines the shape of the pulse at the output of the input device at an ion concentration equal to unity; e _cm is the bias voltage of the processing device (integrator); I _in - input current of the processing device; R is the resistance in constant time in the processing device; t _and is the instant of registration of the integral of the pulse arising at the output of the input device when the capacity of the suction chamber is discharged. 2. A device for measuring the concentration of ions, containing an aspiration chamber with a high-voltage power source, a key connected in series, an input device, a processing device and an indication device, as well as a control device, the first output of which is connected to the processing device, and the second output is supplied to the key connecting the collecting electrode of the suction chamber with an input device, characterized in that it further comprises a voltage comparator, the trailing edge of the output signal of which determines m voltage measuring point in time on the output display device processing apparatus, the first input of the comparator is connected to the input of the processing device and the second input - to a reference voltage source, whose sign of the output voltage coincides with that of the voltage input to the input processing apparatus, and the modulus is given by

and the output of the comparator is connected to the second input of the display device, where U _op - voltage of the reference voltage source; e _cm is the bias voltage of the processing device (integrator); I _in - input current of the processing device; R is the resistance in constant time in the processing device.

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