RU2154811C2 - Circuit diagram of unit processing signal from sensor of intensity of ultraviolet radiation - Google Patents

Abstract

FIELD: measurement and test of intensity of radiation of sources of ultraviolet bactericide range used in plants for disinfection of liquids. SUBSTANCE: proposed circuit diagram of unit processing signal from sensor of intensity of ultraviolet radiation includes photodetector linked to input of first operational amplifier, ripple filter connected to noninverting input of second operational amplifier, intensity indicator, trimming element, output signal element, voltage stabilizer. power supply unit and connector. In correspondence with invention microcircuit with built-in energy-independent storage is used as trimming element, commutation element with three levels of operation is employed in the capacity of output signal element and light-emitting diodes are utilized as intensity indicators. Output of first operational amplifier is connected via resistor and capacitor to its inverse input. Bias voltage from voltage divider is supplied to positive input of first operational amplifier. Digital potentiometer which center point is connected to noninverting input of second operational amplifier via ripple filter is placed between contacts of first operational amplifier. Controlling contacts of digital potentiometer are connected to connector. Resistors are placed between output and inverse input of second operational amplifier in feedback network and between inverse and noninverse inputs of first operational amplifier. Output of second operational amplifier is linked to inverting input of first comparator and to noninverting inputs of second and third comparators, second inputs of comparators are connected to voltage divider. Their outputs are linked to contacts of connector. Output of stabilizer is connected to supply inputs of microcircuit and its input is linked to connector. Filtering capacitors are coupled to input and output of stabilizer and common conductor of circuit is connected to connector. EFFECT: increased accuracy of measurement of signal, higher reliability of circuit, possibility of remote control over operation of plant. 2 dwg

Description

 The invention relates to the field of measuring the intensity of UV radiation and can be used to measure and control the radiation intensity of UV sources of the bactericidal range used in installations for disinfection and disinfection of liquids.

Bactericidal action has radiation at a wavelength of 240-280 nm. The effectiveness of exposure to UV radiation on microorganisms is determined by the intensity of UV radiation, as well as the exposure time. The product of the radiation intensity at a time is called the radiation dose (mJ / cm ² ) and is a measure of the bactericidal energy received by microorganisms when passing through the installation. The dose of radiation is the most important parameter that determines the efficiency of the installation and should not be lower than the required value necessary for reliable disinfection of water during operation of the installation. In case of contamination of quartz covers of UV lamps or a sharp deterioration in water quality, a decrease in the intensity of UV radiation and, consequently, the required dose of irradiation of water. The UV radiation intensity sensor is designed to monitor the radiation dose. The signal from the photodetector of the sensor enters the signal processing unit, where it is converted, analyzed and used to control the dose of water irradiation. When the dose value is below the set limit, an audio or light signal is given, along which the flow of water is blocked.

 A known circuit of the signal processing unit of the UV intensity sensor used in UV water disinfection units (patent EP 0202891, C 02 F 1/32, 11.26.86). The principle of operation of the sensor is based on the use of two identical photodetectors, one of which measures the radiation intensity of a UV lamp through quartz glass that transmits radiation of the bactericidal range, and the other through borosilicate glass that does not transmit the indicated radiation. The radiation intensity of the bactericidal range is proportional to the difference signal of the two photodetectors. The intensity level is indicated by a dial indicator.

 The electrical circuit of the signal processing unit of the known UV intensity sensor is intended to amplify the difference signal of the photodetectors and turn on the relay if the intensity decreases below the required level. The electrical circuit of the signal processing unit of the known sensor includes photodetectors (photodiodes) connected to two inputs of a differential amplifier, on which the difference signal is subtracted and amplified. The output of the differential amplifier through a resistor is connected to a dial indicator of the radiation intensity of the bactericidal spectrum and to the input of the operational amplifier with a high gain. The operational amplifier is used to compare the level of the received signal with a reference voltage set using a resistor. When the signal level is below the level of the reference voltage, the output of the operational amplifier goes into a state in which the alarm relay is activated. The circuit also includes tuning resistors - to set the differential amplifier to “zero”, to adjust the differential amplifier gain and set the dial indicator, to set the switching threshold of the operational amplifier and turn on the relay.

 The disadvantages of the prototype include the presence in the circuit of two photodetectors with different temperature and time dependencies of the characteristics, which leads to a decrease in the accuracy of the sensor readings. The different glass material of the photodetectors also reduces the accuracy of the sensor readings from time to time. The use of resistors as trimming elements significantly reduces the vibration resistance of the circuit and its resistance to environmental conditions, which is important when operating UV water disinfection units. Also, the known scheme requires complex calibration of the sensor, since three trimming elements are used for this. The electrical circuit of the known sensor does not allow the intensity indicator to be carried out over a large distance from the installation, which creates difficulties in its operation.

 The technical result achieved by the proposed electrical circuit of the signal processing unit is to increase the accuracy of signal measurement, higher reliability of the circuit during operation of the sensor, as well as the possibility of remote monitoring of the installation.

 The electrical circuit of the signal processing unit of the UV radiation intensity sensor includes a photodetector connected to the input of the first operational amplifier, a smoothing filter connected to the non-inverting input of the second operational amplifier, and a comparator, intensity indicator, a tuned element, an output signal element, electrically connected to each other, voltage stabilizer, power supply and connector.

 According to the invention, microcircuits are used as comparators, and a chip with integrated non-volatile memory is used as a tuning element, a switching element with three response levels is used as an output signal element, LEDs are used as intensity indicators, and the output of the first operational amplifier through a resistor and capacitor is connected with its inverse input, the bias voltage from the voltage divider is applied to the positive input of the first operational amplifier In this case, between the contacts of the first operational amplifier, a digital potentiometer is connected through a resistor, the middle point of which is connected through a smoothing filter to the non-inverting input of the second operational amplifier, and the adjustment contacts of the digital potentiometer are connected to the output connector, between the output and the inverse input of the second operational amplifier in feedback and between resistors are included in its inverse and non-inverting input of the first operational amplifier, the output of the second amplifier is connected to the inverting input of the first comparator and non-inverting inputs of the second and third comparators, the second inputs of the comparators are connected to the voltage divider, and their outputs are connected to the connector pins, the stabilizer output is connected to the microcircuit power inputs, the stabilizer output is connected to the output connector, filter capacitors are connected to the input and output of the stabilizer, and the common wire of the circuit is connected to the connector.

The above essential features are associated with the achievement of a technical result as follows:
the use of one sensor (instead of two in the prototype) allows you to shoot directly useful, and not a differential signal proportional to useful, which significantly increases the accuracy of measurements;
the use of an operational amplifier (DA1) instead of a differential amplifier that requires correction "O", increases the signal amplification level by about 10 times without additional correction "O";
As a result of the use of a digital microcircuit with integrated non-volatile memory (DA2) instead of tuning resistors, the sensor durability increases, its resistance to the working environment increases, and the reliability and stability of the signal for turning on the LEDs for indicating emergency operation modes of the installation are also ensured. In addition, it becomes possible to remotely calibrate the sensor when it is fully assembled;
The use of a comparator (DA4) and signal LEDs in the circuit instead of a dial indicator and a transistor allows to indicate the operation of the sensor and, therefore, the operating mode of the installation in accordance with the level of measured intensity at a distance of up to 100 m from the installation;
Figure 1 presents the electrical circuit of the signal processing unit of the sensor; figure 2 is a block diagram of a UV-intensity sensor.

 Below is a more detailed description of the electrical circuit of the signal processing unit of the proposed UV sensor.

 The algorithm of the sensor is based on a color indication. If the radiation intensity is higher than the minimum allowable by more than 20%, the green LED is on, which indicates the normal operation of the installation. When the radiation intensity is above the minimum permissible less than 20%, the warning yellow LED flashes. In the event that the radiation intensity is below the minimum permissible, the yellow blinks and the red emergency LED lights up. As indicated in the block diagram (figure 2), the signal from the photodetector 1 is fed to the inputs of the current Converter 2 to voltage. The output voltage and accordingly the gain of the circuit are adjusted by a digital potentiometer 3. The set gain is stored in the non-volatile memory of the potentiometer. From a digital potentiometer, the signal is fed to a voltage amplifier 4, which amplifies the signal to the level required for the operation of the comparators 5 of the comparison circuit, which compares the signal level from the amplifier with a reference level and has three open collector outputs that are connected to connector 7. Stable the power of the entire circuit (+ 5V) is supplied from the power stabilizer 6. At the input of the stabilizer 6 from connector 7, a supply voltage is supplied for the operation of the entire electrical circuit of the sensor, which can be in the range +9 ... + 25V.

As the photodetector, a SiC-based VD1 photodiode is used. The photodiode VD1 is connected according to the scheme of the current source with zero bias. In such a switching circuit, the output current of the photodiode is proportional to the intensity of the radiation incident on the photosensitive surface of the photodiode in a wide range. The conversion of current into voltage is carried out on the first operational amplifier DA1 (the DA1 chip has two identical operational amplifiers). Resistor R1 and capacitor C1 serve as the feedback of the converter, the resistor value sets the conversion coefficient. The circuit has unipolar power, therefore, for the converter to operate, a voltage offset is introduced at the elements R6, R7, R8, VD2 and VD3. That is, at the input of the operational amplifier DA1 / 3, the voltage is set and equal to about 1.2 V. Thus, the radiation intensity at the photodetector is proportional to the voltage between the contacts DA1 / 3 and DA1 / 1. To adjust the gain between these contacts, a digital potentiometer DA2 is connected through resistor R3. Resistor R3 reduces the depth of gain adjustment and improves the accuracy of this adjustment. The output voltage is adjusted at the midpoint of the potentiometer (DA2 / 6) by shorting the contacts DA2 / 2 and DA2 / 7 to ground (contact DA2 / 5). Adjustment step with a graduation of 1/64. After the adjustment, its value is automatically stored in the internal non-volatile memory of the potentiometer DA2. The voltage from the midpoint of the potentiometer DA2 / 6 through the smoothing ripple filter R2C2 is supplied to the input of the voltage amplifier DA1 / 5 (second operational amplifier DA1). The gain is set by resistors R4 and R5. The voltage between the amplifier output (DA1 / 7) and the bias voltage (DA1 / 3) is proportional to the radiation intensity at the photodetector. The output of the DA1 / 7 amplifier is connected to the three inputs of the three comparators of the DA4 chip. To the other inputs of the comparators, a reference voltage is supplied from the divider assembled on resistors R6, R7 and R8. On the comparators of the DA4 chip, the output signal (and, accordingly, the radiation intensity) is compared with a given level. The divider on resistors R6, R7 and R8 sets two voltage levels, and the second is 20% higher than the first. In the event that the input signal level is lower than both reference levels, then the outputs of the comparators 2 (DA4 / 1) and 3 (DA4 / 14) ("open collector") are turned on. If the input signal level is between two reference levels, the output of comparator 2 (DA4 / 1) is turned on. When the input signal of both reference levels is exceeded, the output of comparator 1 (DA4 / 2) is turned on, LEDs are connected through the output connector to the outputs of the comparators, green is connected to the first output (DA4 / 2), and yellow to the second (DA4 / 1) , to the third (DA4 / 14) - "red". Thus, one of the signal LEDs is always on, which indicates the operation of the sensor. In addition to the advantages of the proposed scheme of the signal processing unit of the UV sensor, the following can be attributed:
- the circuit has unipolar power, the voltage level can vary within wide limits (+9 ... + 25V), which simplifies the use of the sensor;
- as the sensor output signal, a key circuit with an open collector is used, which makes it possible to carry out the sensor indication over a considerable distance without losing the accuracy of the circuit even in strong industrial electromagnetic fields;
- the use of a digital potentiometer in the circuit allows calibration of the sensor (gain adjustment) when the sensor is fully assembled;
- the rejection of a mechanical potentiometer to adjust the gain increases the stability of the readings over time.

Claims (1)

 The electric circuit of the signal processing unit of the ultraviolet radiation intensity sensor, including a photodetector electrically connected to each other, connected to the input of the first operational amplifier, a smoothing filter connected to the non-inverting input of the second operational amplifier, as well as a comparator, intensity indicator, tuning element, output signal element, stabilizer voltage, power supply and connector, characterized in that it additionally contains two comparators, using as comparators They use a microcircuit, and use a microcircuit with a built-in non-volatile memory as a tuning element, use a switching element with three response levels as an output signal element, use LEDs as an intensity indicator, the output of the first operational amplifier through a resistor and capacitor connected to its inverse input, the bias voltage from the voltage divider is applied to the positive input of the first operational amplifier, between the contacts of the first operational amplifier For the resistor, a digital potentiometer is connected, the middle point of which is connected through a smoothing filter to the non-inverting input of the second operational amplifier, and the regulation contacts of the digital potentiometer are connected to the connector between the output and the inverse input of the second operational amplifier in feedback and between its inverse and non-inverting input of the first operational the amplifier includes resistors, and the output of the second amplifier is connected to the inverting input of the first comparator and non-inverting inputs of the second of the third and third comparators, the second inputs of the comparators are connected to the voltage divider, their outputs are connected to the contacts of the connector, the output of the stabilizer is connected to the power inputs of the microcircuits, the input of the stabilizer is connected to the connector, filter capacitors are connected to the input and output of the stabilizer, and the common circuit wire is connected to the connector .

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