JPH05113434A - Gas chromatograph - Google Patents

Abstract

PURPOSE:To shorten the temperature measuring time of a constant temperature oven by providing the second detecting-function part, wherein number of times for detecting operation are fewer than that of the first detecting-function part, and a means, which starts the detecting operation with the voltage signal of a memory means when one of the detecting-function parts is started. CONSTITUTION:When the temperature of a constant temperature oven is detected as a voltage signal with a temperature sensor 1, the voltage signal is outputted into one input terminal of a comparator 4 as a voltage value V2, which is to be amplified with an amplifier circuit 3. Meanwhile, the voltage signal having the voltage value V3 is imparted to the other input terminal of the comparator 4 from a CPU 5 through a D/A converter 6, PWM circuit 7 and a low-pass filter 8. As a result, a value '1' is outputted from the comparator 4 when V3<V2. A value '0' is outputted when V3>V2. The CPU 5 detects the output of the comparator 4 and imparts the digital voltage value to the converter 6. When the output of the comparator 4 is changed, it is judged that the voltage, which is imparted to the converter 6, is the measured voltage value.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas chromatograph for detecting the concentration of a sample gas and measuring its components, and more particularly to a gas chromatograph for measuring the temperature of a gas to be measured and the temperature of a measuring system which keeps the temperature of a measuring system constant. Regarding Tograph.

[0002]

2. Description of the Related Art Generally, this type of gas chromatograph is
An appropriate stationary phase is filled inside, and a fixed amount of a mixed sample such as gas is put into a column in which a carrier gas as a mobile phase is constantly flowed to analyze its components. That is, the mixed sample is swept out to the outlet of the column by the carrier gas, but the moving speed of each component of this sample is determined by the affinity with the stationary phase, and each component separated by the stationary phase is delivered to the outlet of the column. Qualitative and quantitative analysis of a mixed sample by measuring the time and order of delivery and the peak height (peak voltage) and peak area showing the concentration of each component detected by the detector Has become.

In order to accurately measure the concentration of such sample gas, FIG. 1 shows the temperature of a constant temperature bath for keeping the temperature of the measurement gas and the measurement system such as the analyzer valve, the column, the TCD sensor and the gas passage constant. Is a circuit that measures the temperature of the constant temperature bath as a voltage signal by the temperature sensor 1 and measures the voltage value of the detected voltage signal via the output of the comparator 4. I am trying. That is, in FIG. 1, the temperature sensor 1
The value V2 of the voltage signal detected by the amplifier circuit 2 and amplified by the amplifier circuit 2 is output to one terminal of the comparator 4, and to the other terminal of the comparator 4, the CPU 5 outputs the D / A converter 6, the PWM circuit 7 and A voltage value V ₃ is given through an LPF (low pass filter) 8 and the comparator 4
It has a comparison output of the voltage value V ₂ and V _3, and that the voltage value V ₂ is determined from the relationship between the value given to the D / A converter 6 from CPU5 in.

FIG. 3 is an explanatory diagram showing a process of calculating such a voltage value V ₂ . In this case, the maximum voltage value is D
An example in which 0 (V) to DASPAN (V) is divided into 16 parts is shown because the D / A converter 6 for converting a digital signal into an analog signal has ASPAN (V) and has a resolution of 4 bits. This indicates that the voltage value V _{2 to} be obtained exists between the 13th division and the 14th division.

Next, the voltage measuring operation of the CPU 5 will be described with reference to FIG. That is, first, the voltage value V ₃ to be applied to the other terminal of the comparator 4 is set to (8/16) × DASP
The value of AN is output to the D / A converter 6 and a predetermined period is waited until the conversion operation from the digital signal to the analog signal in the D / A converter 6 becomes stable (0th time). Then, after a lapse of a predetermined time, the output of the comparator 4 is "1" because V ₃ <V ₂ . From this, the CPU 5 sets the value given to the 0th time (4/1
The value obtained by adding 6) × DASPAN is output to the D / A converter 6 and waits for a predetermined time (first time). However, also in this case, “1” is still output from the comparator 4 because V ₃ <V ₂ . From this, CPU5
Is (2/16) × DASP in addition to the value given at the first time
The value to which AN is added is output to the D / A converter 6 and waits for a predetermined time (second time).

In this case, since the output of the comparator 4 becomes "0" because V ₃ > V ₂ , the value given at the second time is reduced by (1/16) × DASPAN to obtain D.
Output to the / A converter 6 and wait for a predetermined time (third time).
As a result, the output of the comparator 4 is "0" and V ₃ > V ₂
In the case of, the third value is taken as the voltage value V ₂ , but when the output of the comparator 4 is “1” and V ₃ <V ₂ , (1/16) × DASPAN is added to the value given the third time. The value obtained is set as the voltage value V ₂ (fourth time).

As described above, in the above example, since the D / A converter 6 has a resolution of 4 bits, the search operation until the final voltage value is measured is performed four times. If the resolution of the A / A converter 6 is set to 8 bits or 12 bits, it is necessary to perform the search operation a number of times corresponding to this. However, in this case, the range of the measurement voltage is divided more finely, and the measurement accuracy can be further improved.

FIG. 4 shows a CPU for performing the above voltage measurement operation.
6 is a flowchart of FIG. Note that n in the figure indicates the number of bits corresponding to the resolution of the D / A converter.

[0009]

In the conventional gas chromatograph, when the value of the voltage signal indicating the temperature of the constant temperature bath is to be measured, the D / A converter 6 is initially set to ½ of the maximum voltage value as an initial value. Value is given to detect the output of the comparator 4, and thereafter, the voltage value given last time is added to the value of 1/2 of the voltage value added last time and given to the D / A converter 6. The output change of the comparator 6 is detected each time. On the other hand, the D / A converter 6 requires a considerable time to convert a digital signal into an analog signal, and the search operation as described above is continued for the number of times corresponding to the resolution of the D / A converter 6. Therefore, there is a problem that it takes time to measure the temperature.

[0010]

In order to solve such a problem, the present invention provides a temperature sensor for detecting temperature and outputting it as a first voltage signal, a first voltage signal and the first voltage signal. A comparator for inputting a second voltage signal for detecting the value of the voltage signal and comparing the magnitudes thereof; a D / A converter for outputting a second voltage signal having n-bit resolution; /
A control unit having a first search function unit for outputting a third voltage signal to the A converter to detect a change in the output of the comparator a number of times corresponding to the number of bits of resolution; In a gas chromatograph for measuring the value of the first voltage signal from the value of the third voltage signal at the end of the search operation by the search function unit, the third voltage signal of the third voltage signal at the end of the search operation by the first search function unit Any of the storage means for storing a value, the second search function section that performs the number of search operations less than the number of times of the first search function section, and the first and second search function sections when measuring the first voltage signal And a means for starting the search operation based on the value of the third voltage signal stored in the storage means when either one of the first and second search function units is started. Be prepared.

[0011]

When measuring the first voltage signal corresponding to the temperature of the incoming gas, the first search function unit and the second search function unit in which the number of search operations is less than the number of times of the first search function unit. Since either one of them is activated, the number of search operations is reduced, and as a result, the time required to measure the temperature of the constant temperature bath is shortened.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an embodiment of a gas chromatograph according to the present invention. In the figure, 1 is a sensor that detects the temperature of a thermostatic bath (not shown) and outputs it as a voltage signal, 2 is a constant current circuit, 3 is an amplifier circuit, 4 is the value V _{2 of the} voltage signal indicating the temperature, and for temperature measurement. A comparator 5 for comparing the value V ₃ of the voltage signal given to
Is a D / A converter that converts a digital voltage value given from the CPU 5 into an analog signal, 7 is a PWM circuit that changes the duty ratio of the pulse width according to the input voltage signal, and 8 is a low-frequency signal. LPF (low pass filter)
Is.

When the temperature of the constant temperature bath is detected by the temperature sensor 1 as a voltage signal, the detected voltage signal is amplified by the amplifier circuit 3 and is input to one input terminal of the comparator 4 as a voltage value V ₂ to be measured. Is output. On the other hand, the other input terminal of the comparator 4 is given a voltage signal of the voltage value V ₃ by the CPU 5 via the D / A converter 6, the PWM circuit 7 and the LPF 8. As a result, the comparator 4 outputs the value “1” when V ₃ <V _{2 and} the value “0” when V ₃ > V ₂ . CPU5
Gives a digital voltage value to the D / A converter 6 while detecting the output of the comparator 4, and when the output of the comparator 4 changes, the voltage value given to the D / A converter 6 at that time is regarded as the measured voltage value. judge.

FIG. 2 is a flow chart of the CPU 5 which performs such a voltage signal measuring operation. The detailed operation of the present invention will be described based on this flowchart. When the voltage signal having the voltage value V ₂ is applied to one terminal of the comparator 4, it is determined in step 20 whether the value of the register y is "1". If it is "1", it means the first measurement operation, so "1" is set in the register N (step 21), and the voltage finally measured at the time of the previous measurement and stored in the memory in the CPU 5 is stored. The value is output as a DA value to the D / A converter 6 (step 23). When the voltage measurement is started from the beginning, 1/2 of the maximum voltage value is output to the D / A converter 6.
Then, thereafter, the D / A converter 6 waits for a settling time to complete the digital-analog conversion operation (step 2).
4). The settling time is about 0.5 seconds. When this settling time has elapsed, the voltage signal of the voltage value V ₂ is applied to the other terminal of the comparator 4.

Thereafter, the output of the comparator 4 is read (step 25), and when this value is "1" (that is,
If V ₃ <V ₂ , the D / A converter 6 is operated in step 23.
The value of 1/2 of this DA value is added to the DA value output to the D / A converter 6 (step 26). When the output value of the comparator 4 is “0” (that is, V ₃ > V
_In the case of ₂ ), the value of 1/2 of this DA value is subtracted from the DA value output to the D / A converter 6 and output to the D / A converter 6 (step 27). Thereafter, at step 28, the value of the register N is incremented by 1, and at step 29, the value of the register N corresponds to the resolution of the D / A converter 6 n.
If the value n has not been reached, after the settling time of the D / A converter 6 in step 24 has elapsed, the above-mentioned steps 25 to 29 are repeatedly executed.

When the search operation is repeatedly executed and the number of times reaches n times, the process proceeds to "Y" in step 29,
In step 30, the final DA value, that is, the final measured voltage value of the voltage signal indicating the gas temperature is stored in the memory, and the register y
Is incremented by 1 (step 31). The final DA value stored in the memory is read from the memory and output to the D / A converter 6 at the start of the next voltage measurement process.

When the first voltage measurement process is completed, the second voltage measurement process is subsequently started.
Since the process in this case is the second process, "y = 1" in step 20 is determined to be "N", and in this case, "nx" is set in the register N in step 22. The value of x is, for example, n = 12 as described later.
When it is set to (bit), the value is "5", which is set to a value smaller than n. Then, the process proceeds to step 23, and the processes as described above are executed up to step 31 thereafter. However, in this case, the value “n−
Since “x” is set, the number of search operations may be x, and the voltage measurement can be performed with a smaller number of search operations than the number of search operations n during the first voltage measurement.

Then, such voltage measurement processing with the number of search operations x times is sequentially performed at predetermined time intervals, and if the number of times of the voltage measurement processing is counted z times, it is judged as "Y" in step 32, and step 33 Is set to "1" in the register y. As a result, the voltage measurement process performed next time is treated as the first process.

Since the above value x has little fluctuation of the voltage to be measured, the resolution n of the D / A converter 6 is usually "1".
In the case of "2", the value is set to "5", which is set to a value approximately twice the expected maximum voltage fluctuation value. Therefore, the measurement accuracy can be expected to be improved, and the measurement time can be reduced from the conventional 12 × 0.5 = 6 (seconds) to 5 × 0.5 =
It becomes 2.5 (seconds). In this way, when voltage measurement is performed, the search operation is started from this value using the last measured value of the previous time, and the search operation is not always performed the number of times corresponding to the resolution n of the D / A converter 6. In addition, such a search operation is performed only once in z times, and the search frequency is x when other voltage measurement is performed.
This is done only (z <n) times. As a result, the time required for voltage measurement can be shortened and accurate measurement can be performed, so that the temperature of the constant temperature bath can be efficiently measured.

[0020]

As described above, according to the present invention, when the first voltage signal corresponding to the temperature of the incoming gas is measured, the first search function unit and the number of search operations are the first search. Since one of the second search function units that is less than the number of function units is activated, the number of search operations decreases,
As a result, the time required for measuring the temperature of the constant temperature bath is shortened.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a gas chromatograph according to the present invention.

FIG. 2 is a flow chart showing the operation of the apparatus of the above embodiment.

FIG. 3 is a diagram illustrating the operation of a conventional gas chromatograph.

FIG. 4 is a flowchart showing the operation of a conventional gas chromatograph.

[Explanation of symbols]

 1 Temperature Sensor 2 Constant Current Circuit 3 Amplifier Circuit 4 Comparator 5 CPU 6 D / A Converter 7 PWM Circuit 8 LPF

Claims (1)

[Claims] 1. A temperature sensor for detecting a temperature and outputting it as a first voltage signal, the first voltage signal and the first voltage signal.
A comparator for inputting a second voltage signal for detecting the value of the voltage signal and comparing the magnitude of the second voltage signal and D for outputting the second voltage signal having a resolution of n (n is a natural number) bits. /
A converter and a first search function unit for performing a search operation for outputting the third voltage signal to the D / A converter to detect an output change of the comparator, the number of times corresponding to the number of bits of the resolution. A gas chromatograph that measures the value of the first voltage signal from the value of the third voltage signal at the end of the search operation by the first search function unit. Storage means for storing the value of the third voltage signal at the end of the search operation by the search function section; a second search function section in which the number of times of the search operation is less than the number of times in the first search function section; Means for activating one of the first and second search function sections when measuring the first voltage signal, and the storage means when one of the first and second search function sections is activated Based on the value of the third voltage signal stored in A gas chromatograph, comprising: means for starting an operation.