SU805147A1 - Photoelectric meter of paper paremeters - Google Patents

Description

The invention relates to measuring equipment and is intended to measure the parameters of technological processes, for example, the concentration of mineral filler, mass per square meter of the canvas, humidity, etc. ⁵ . A device DPJ control parameters of the paper web, comprising a radiation source, modulating disc filters, a photodetector with power supply, the amplifier, functional transformation zovatel ^10, the switch and the registrar [1].

The closest technical solution to the proposed one is a photoelectric meter of paper ¹⁵ web parameters, containing a sequentially installed radiation source, a modulation disk with filters, a photo detector with a power supply, an amplifier, a switch, to the outputs of which are connected functional converters of the measuring and reference signals, a signal processing unit and a recorder [2].

The disadvantage of this device is the error associated with changes in temperature and temporary aging of the photoresistor. The signal of the reference channel depends on the measured parameters of the paper web, temperature changes and aging of photoresistors. When measuring in technological processes of chemical technology, such devices must be thermostated to eliminate the influence of temperature, but the sensitivity drops significantly.

The purpose of the invention is improving accuracy.

This goal is achieved by the fact that a second functional converter of the reference signal, an error changing unit and a correction unit, as well as an additional power supply unit with a commutator connected to the photodetector, the inputs of the correction unit are connected in series with the well-known photoelectric meter of the paper web parameters with the outputs of the functional converters of the measuring and reference signal, and the outputs with the signal processing unit ^ input of the additional functional the reference signal converter through the switch is connected to the amplifier output, and the second input of the error measurement unit is connected to the output of the reference signal functional converter.

Figure 1 presents a structural diagram of a photoelectric meter parameters of the paper web; as in FIG. 2 is an implementation diagram of an error measurement unit and a correction unit.

The device contains a radiation source 1 ', a modulation disk with filters 2,. '' photodetector 3 and amplifier 4 connected in series, switches 5 and 6, photodetector power supply units 7 and 8, connected to photodetector 3 through switch 5, functional converters 9 and 10 of the measuring and reference signals, the second functional converter 11 of the reference signal connected 'the inputs through the switch 6 to the output of the amplifier 4, the error measurement unit 12, the correction unit 13, the signal processing unit 14, the recording device 15, connected together in series, and the inputs of the correction unit 13 are connected to the outputs functional converters 9 and 10 of the measuring and reference signals.

The output of the second functional converter 11 of the reference signal is connected to one of the inputs of the error measuring unit 12 (Fig. 2). A possible implementation scheme of the error measuring unit 12 contains a scale converter 16, comparison circuits 17 and 18, and the head-mounted converters 19 and 20 , del., body device 21, key 22, polarity detectors 23 and 24, amplifier 25, trigger. 26 Schmidt. Log scale converter 16 connected to the ^output: second function converter 11 of the reference signal, and an output connected to the comparison circuit 18, the second input of which is connected to the output scale converter 19 connected to the functional input to an output of the reference signal converter 1D. The inputs of the comparison circuit 17 are connected one to the output of the second functional converter 11 of the reference signal, and the second to the output of the scale converter 2Q is input ⁵⁵ . It is connected to the output of the functional converter 10. The outputs of the comparison circuits 17 and 18 are connected to the inputs of the splitting device 21, the output of which is connected to the inputs of the key 22, polarity detectors 23 and 24. The output of the polarity detector 23 through the amplifier 25 and the Schmidt trigger 26 is connected to the second input of the key 22, and the output of the polarity detector 24 is connected to the input of the Schmidt trigger 6. The correction unit circuit 13 includes two dividing devices 27 and 28, two adders 29 and 30, and a reference voltage source 31.

Photoelectric meter parameters of the paper web is as follows.

Modulation disk 2 with interference filters - cuts out two streams that differ in wavelength from the IR radiation source stream. The IR radiation intensity of the measuring stream is absorbed in the presence of a controlled property (filler concentration in the paper web), the IR radiation intensity of the reference stream weakly depends on the measured property. To increase the accuracy of the measurement, it is necessary to measure and introduce correction for the temperature and time instability of the photoelectric detector. For this, it is necessary to make the signal of the detector 3 completely independent of the parameters of the paper web. In the proposed device, this is achieved by a technical solution. As a photoelectric detector, photo-resistance is used, but you can also apply a photodiode in a diode inclusion, a photocell.

To obtain the correction signal, the following physical property of the photoresistor is used.

The photoresistor- ⁴⁰ torus conversion coefficient depends on the photosensitive material, structures, and on the applied voltage. We choose for the photoresistor, the supply voltage, for example, Y |. In this case, the value of the coefficient of conversion of IR radiation into the photocurrent of the photoresist will be K-j. A change in temperature T < _f as well as temporary changes in the parameters of the photosensitive material will cause a change in the conversion coefficient of the photoresistor by Δ CT, then the voltage of the measuring channel will be described by the equation where Φ _Ο ί is the amount of light flux depending on the measured parameter and the radiation wavelength.

The voltage of the reference channel is described by the equation ^ 12 ⁼ 5 ^ 1% &) ^ 02>

magnitude of the light flux,: 'U' of the measured wavelength

synchronization can

where Φ _{сла is} weakly dependent on the meter, depending on the th radiation.

Using the circuit, but make sure that with one revolution of the modulation disk, when the reference channel is working, the photoresistor is supplied. the selected supply voltage. At the next revolution of the modulation disk, when the reference channel is operating, the supply voltage 9 _2% is applied to the photoresistor, then the cycle repeats. When eating 9 g. the conversion coefficient of infrared radiation into a photocurrent will be already different in magnitude and equal to Kg .. Thus, with a 9g power supply, a linear dependence of the photocurrent on illumination can also be obtained. The voltage of the additional reference channel with power supply U g will be described by the equation where Ф _{02 is the} flux value, i.e.

reference light

K ₂ + dk ₂ k <± ak ₄

Changes in the conversion coefficients K, and K _{2 are} approximately proportional, ^t * ^e * a to

A “4 ~ and>

where And is the coefficient of proportionality. Solving the equations, we get where

Thus, by constructing a device with two reference channels, it is possible to isolate the instability Δ K of the photoresistor and, before processing the signals of the measuring and reference channel, to enter the value of the controlled parameter, introduce correction into each channel.

The IR study of the source 1 through a paper web and a modulation disk with filters 2 is fed to the detector 3. At the load of the detector 3, signals are proportionally generated proportionally to am805147 to the 6 wavelength plates of the measuring and reference filters with a photoresistor supply voltage equal to. Signals proportional to the amplitude of the wavelength of the reference filter when powering the photoresistor '

U stand out in this way. With one revolution of the modulation disk during the passage of the YK radiation through the reference, the filter supplies power to the photoresistor

1¼ a, during the second revolution of the disk, power is supplied to U ₂ . while only the support filter is working. Sync done. so that for any revolution of the disk 2, when the radiation passes the measuring filter, only power 9 / is supplied to the photoresistor,

The signals from the output of the detector 3 are amplified by an amplifier 4, and the switch 6 is divided into three channels. At the output of the functional converter 9, a signal U ₁ is generated ₍ proportional to the measured property, at the output of the converter 10, a signal 9 ^ 2, which is the reference signal for the measurement signal. At the output of the converter 11, a signal is generated which is an additional signal for the reference channel, obtained with the photoconductor supply voltage Gg. The voltage from the converters 10 and 11 is supplied to the error measuring unit 12, which produces a voltage proportional to the change in the conversion coefficient of the photoresistor. block 12, algorithm (8) can be implemented, but there can be other algorithms depending on the specific types of photoresistors, their linearity, and

etc. Eg <ix measuring channel converter 9 is supplied to the first correcting unit 13 is input to the second input of which the reference channel voltage converter 10. In the correction unit 13 also receives voltage _{proportional}} error block 12, by an amount which is necessary to correct the measuring and the reference signal . The adjusted voltages from block 13 enter the processing block 14, where they are processed according to an algorithm corresponding to the measurement of this parameter. According to the proposed structural scheme, it is possible to construct a series of photoelectric meters for paper web parameters. For each specific parameter, for example, the concentration of the filler mass per square meter, humidity, an interference filter is selected for the measuring channel with the desired wavelength and the processing algorithm in block 14 is changed depending on the particular foot parameter.

The above diagram of the implementation of the correction block (Fig. 2) works as follows. ,.

The voltage (7 ^ of the functional converter 11 is supplied to a scale converter 16, the output voltage of which is proportional to ^ The voltage Uc of the converter 10 is supplied to the input of the scale converters 19 and 20. At the output of the converter 19, the voltage is proportional to K ₂ Uf2, and the output 20 is “Voltage from the converters 16 and 19 go to the first and second input of the circuit 18, voltage from the output of the comparison circuit 18, proportional to the value (О *, К goes to the first input of the healing device 21. The voltage ^ of the outputs is converted 11 and 26 are fed to the first and second input of the comparison circuit 17, the output voltage of which is supplied to the second input of the dividing device 21. At the output 21, a voltage is generated ^ proportional to the error of the conversion coefficient of the photoresistor, which is received from the input of key 22. This is caused by the following circumstance. recorded by the photoresistor is somewhat statistical in nature, determined by the statistical nature of fluctuations in the parameters of the paper web. Therefore, at a constant coefficient, the conversion of the photoresistor, taking into account the basic fact, it is impossible to obtain * KL = 0, although ΔK will be a fairly small value. In this case, the correction of the measuring and reference signals can lead to a decrease in the stability of the device and even the appearance of oscillations. The error voltage from block 21 is also supplied to blocks 23 and 24, which are polarity detectors. When

Δ Кγ is positive, then through the detector 24 it enters the input of the Schmidt trigger 26. At. the negative Δ Kn is triggered by the detector 23 and the amplifier 25 inverts 4 | ζ which then also goes to the input of the Schmidt trigger. When Δ ^ exceeds a certain threshold value which is greater than the level of statistical fluctuations, the trigger 26 fires and opens the key 22. The voltage proportional to the error of the conversion coefficient of the photoresistor is input to the correction unit 13. The voltage of the measuring channel from the converter 9 is supplied to the first input of the dividing device 27. The voltage of the reference channel from the converter 10 is also supplied to the first input of the dividing device 28. The outputs of the adders 29 and 30 are loaded onto the second inputs _{5 of the} devices 27 and 28, respectively. The first inputs of the adders 29 and 30 receives the reference voltage of the source

31, which on a certain scale corresponds to the conversion coefficient of the photoresistor K _# · A voltage proportional to the error from block 21 is supplied to the second inputs of the adders 29 and 30. Signals proportional to the value ₁₅ are generated at the output of the adders 29 and 30. Thus, the output of the dividing device 27 stress is formed

Uh „(Ki + aK-i) ^φ ρί

Κ4 + ΔΚ4

At the output of the dividing device 28, voltage _# is formed equal to the ratio of ^{25 U} 12 .. (* 1 * ΔΚ ,;) cf ₀₂

Κ, + Δίς Κ ^. + ΑΚί Signals from the output of dividing devices. 30 27 and 28 are received at the input of the processing unit 14 of the measuring signals, where, in accordance with the algorithm of this measurement, they are processed and the processing result is recorded by the recording device 35.

The present invention significantly increases accuracy by compensating for the effect of temperature and aging on the 4Q conversion coefficient of the photoresistor. This makes it possible to abandon the thermal stabilization of sensors, which is used in technological processes in chemical technology and complicates the design, and most importantly, a sharp decrease in the sensitivity of such sensors.

Claims (2)

1.Patent UK M 1373807, cl. Q 1A, publ. 1976. 2. US patent number 3551678, cl. G O1 N 21/00, pubpick. 1977 (prototype).