RU100274U1 - SEMICONDUCTOR GAS ANALYZER - Google Patents

Abstract

The utility model is aimed at improving the accuracy of measurements when determining the concentration of the components of the gas mixture when the ambient temperature changes. The specified technical result is achieved by the fact that the semiconductor gas analyzer comprises an electric pulse generator connected to an electric pulse counter, the output of which is connected to the address input of the permanent storage device. The output of the permanent storage device is connected to the input of the multiplying digital-to-analog converter, the input of the reference signal of which is connected to the output of the semiconductor sensor. The transfer output of the electric pulse counter is connected to the input of the semiconductor sensor heater. The heater output is connected to a common wire. A heating element and a temperature sensor are attached to the housing of the semiconductor sensor, which are connected to the control circuit. The output of the digital-to-analog converter is connected to the input of a low-pass filter, the output of which is connected to the indicator. 1 ill.

Description

The utility model relates to measuring equipment, in particular to gas analysis, based on measuring the electrical resistance of a semiconductor sensor, and can be used to analyze the composition of the air in the working area.

An individual gas dosimeter is known, including a sensitive element, signal processing and indication systems. The sensitive element is made in the form of a multichannel sensor from parallel-connected semiconductor films, each with a selective characteristic for a specific type of gas, placed on one side of the ceramic substrate, connected by a differential measurement circuit and powered by a voltage regulator. The resistive heater is located on the other side of the ceramic substrate and is powered by a current stabilizer. The output of the multi-channel sensor is connected to the input of the signal processing cell to which the indication cell is connected in series (RF patent No. 2137116, IPC 6 G01N 27/16, publ. 1999.09.10).

The disadvantage of this device is the lack of compensation for the influence of ambient temperature on the output signal of the semiconductor sensor.

The closest adopted for the prototype is a gas analyzer containing an electric pulse generator connected to an electric pulse counter, the transfer output of which is connected to the input S of the RS flip-flop, the output of which is connected to the first terminal of the semiconductor sensor heater, and the second terminal of the semiconductor sensor heater is connected to a resistor, the second output of which is connected to a common wire, and a comparator, the output of which is connected to the input R of the RS-trigger. The outputs of the electric pulse counter are connected to the address input of a read-only memory device, the output of which is connected to the input of the multiplying digital-to-analog converter, the reference signal of which is connected to the output of the semiconductor sensor, and the output of the multiplying digital-to-analog converter is connected to the input of the low-pass filter, the output of which is connected to the indicator (Guselnikov M.E., Krotova Yu.V. Development of a semiconductor gas analyzer // Life Safety, 2008, No. 1, pp. 50-52).

The disadvantage of this gas analyzer is the incomplete elimination of the influence of changes in ambient temperature on the measurement results.

The objective of the utility model is to reduce measurement errors caused by changes in ambient temperature.

The problem is solved due to the fact that the semiconductor gas analyzer, as in the prototype, contains an electric pulse generator connected to an electric pulse counter, the output of which is connected to the address input of the permanent storage device. The output of the permanent storage device is connected to the input of the multiplying digital-to-analog converter, the input of the reference signal of which is connected to the output of the semiconductor sensor. The output of the multiplying digital-to-analog converter is connected to the input of the low-pass filter, the output of which is connected to the indicator.

According to a utility model, the transfer output of the electric pulse counter is connected to the heater input of the semiconductor sensor, the heater output is connected to a common wire, and a heating element and a temperature sensor are attached to the semiconductor sensor housing, which are connected to the control circuit.

Consider the heat fluxes that occur when a semiconductor sensor is heated. The initial temperature of the sensitive element of the semiconductor sensor is taken equal to the ambient temperature:

T _SE = T ₀ at τ = 0

where T _SE is the temperature of the sensitive element of the semiconductor sensor, K.

T ₀ - ambient temperature, K.

τ is the heating time, s.

When applied to a sensitive element of a semiconductor thermal energy sensor with power Q _1, its temperature changes according to the law:

where c is the heat capacity of the sensitive element of the semiconductor sensor, cal / (kg · K)

m is the mass of the sensitive element of the semiconductor sensor, kg

The temperature change of the sensitive element of the semiconductor sensor during heating can be represented by the expression:

ΔT _SE = T _max -T ₀

where T _max is the maximum temperature to which the sensitive element of the semiconductor sensor heats up, K.

Given equation (1), we can write the expression for the temperature of the sensitive element of the semiconductor sensor, which will change with heating over time:

Heat transfer due to thermal conductivity in the semiconductor sensor is carried out by heat exchange between the sensitive element of the semiconductor sensor and the housing of the semiconductor sensor, which can be described by the equation:

where λ is the coefficient of thermal conductivity, cal / (s · m · K),

T _corp - the temperature of the housing of the semiconductor sensor, K.

Given equation (3), equation (2) can be supplemented:

Heat is transferred to the environment from the surface of the semiconductor sensor housing. The interaction of the semiconductor sensor housing and the environment is described by convection law, which can be represented by the expression:

where α is the coefficient of heat transfer from the housing of the semiconductor sensor to the environment, cal / (s · m ² · K).

Then expression (4) can be supplemented:

In the prototype, the temperature stabilization of the sensitive element of the semiconductor sensor is carried out at the time of reaching the maximum value of the heating temperature according to equation (6). Since the period of operation of the semiconductor gas analyzer is constant, it follows from equation (6) that a change in the ambient temperature affects the cooling process of the sensitive element of the semiconductor sensor. For example, the higher the ambient temperature, the slower it will cool, and therefore more quickly heat up to the maximum temperature in the next heating period. In this case, the amplitude of the temperature fluctuations of the sensitive element of the semiconductor sensor decreases, which causes measurement errors. To eliminate the possibility of the influence of changes in ambient temperature on the measurement result, it is proposed to stabilize the temperature of the semiconductor sensor housing. With a constant temperature of the semiconductor sensor case, the temperature of the semiconductor sensor element is described by equation (4), which shows that the temperature of the semiconductor sensor element is independent of the ambient temperature.

Thus, the proposed design of a semiconductor gas analyzer can reduce measurement errors when determining the concentration of the components of the gas mixture when the ambient temperature changes.

Figure 1 presents a diagram of a semiconductor gas analyzer.

The semiconductor gas analyzer comprises an electric pulse generator 1 (G) connected to an electric pulse counter 2 (SEI), the output of which is connected to the address input of the read-only memory 3 (ROM). The output of read-only memory 3 (ROM) is connected to the input of the multiplying digital-to-analog converter 4 (DAC), the input of the reference signal of which is connected to the output of the semiconductor sensor 5 (PD). The transfer output of the counter of electrical pulses 2 (SEI) is connected to the input of the heater of the semiconductor sensor 5 (PD). The output of the semiconductor sensor heater is connected to a common wire. A heating element 6 and a temperature sensor 7 are attached to the housing of the semiconductor sensor 5 (PD), which are connected to the control circuit 8 (SU). The output of the multiplying digital-to-analog converter 4 (DAC) is connected to the input of the low-pass filter 9 (low-pass filter), the output of which is connected to indicator 10 (I).

The electric pulse generator 1 (G) can be assembled, for example, according to the multivibrator scheme on a type 1006VI1 microcircuit. As a counter of electrical pulses 2 (SEI), a binary counter of electrical pulses with a transfer output, for example, 8-bit, made on two K1533IE7 type microcircuits, was selected. Permanent storage device 3 (ROM) is an electrically programmable ROM, for example, type K573PP12, and a multiplying digital-to-analog converter 4 (DAC) - for example, type KR572PAA. As the semiconductor sensor 5 (PD) can be used any semiconductor sensor designed to operate in a pulsed mode, in which the heater and the sensing element are on the same side of the substrate. As a control circuit, for example, the thermal stabilization circuit described in the prototype can be used. As a temperature sensor 7, for example, an Epcos type B57703 thermistor can be used, and a Vishay type LT030 series resistor as a heating element 6. A low-pass filter 9 (low-pass filter) can be made, for example, from an integrating amplifier based on the K140UD74 microcircuit and a sampling and storage device of the K1100SK2 type. Indicator 10 (I) can be a pointer milliammeter or digital, consisting of an ADC and segment indicators of any type.

The operation of the semiconductor gas analyzer is controlled by an electric pulse generator 1 (G), the pulses from which are supplied to an electric pulse counter 2 (SEI), which calculates their number in the form of a code and generates a sequence of binary codes. When the output code is zero, the counter of electrical pulses 2 (SEI) generates a heating pulse, which from the transfer output of the counter of electrical pulses 2 (SEI) is fed to the input of the heater of the semiconductor sensor 5 (PD). With changes in ambient temperature, the temperature of the sensitive element of the semiconductor sensor 5 (PD) changes, as a result of which measurement errors appear. The control circuit 8 (SU) generates a voltage on the heating element 6 so that the output signal of the temperature sensor 7 is constant. The sequence of binary codes from the output of the counter of electrical pulses 2 (SEI) is fed to the address input of the permanent memory 3 (ROM), which stores pre-recorded information about the analyzed gases. From the output of read-only memory 3 (ROM), these codes are fed to the input of a multiplying digital-to-analog converter 4 (DAC). The output signal of the multiplying digital-to-analog converter 4 (DAC) is proportional to the product of the input code by the signal from the output of the semiconductor sensor 5 (PD). Integration of the obtained product is carried out by an integrating unit - a low-pass filter 9 (low-pass filter). The measurement result, proportional to the desired concentration of the determined component, is displayed on indicator 10 (I).

Thus, the use of the claimed solution will improve the accuracy of measurements when determining the concentration of the components of the gas mixture with a change in ambient temperature.

Claims (1)

A semiconductor gas analyzer containing an electric pulse generator connected to an electric pulse counter, the output of which is connected to an address input of a read-only memory device, the output of which is connected to the input of a multiplying digital-to-analog converter, the input of a reference signal of which is connected to the output of the semiconductor sensor, and the output of the digital-to-analog converter is connected to the input low-pass filter, the output of which is connected to an indicator, characterized in that the counter transfer output a series of electrical pulses is connected to the heater input of the semiconductor sensor, the heater output is connected to a common wire, and a heating element and a temperature sensor are attached to the semiconductor sensor housing, which are connected to the control circuit.