RU143323U1 - OZONE CONCENTRATION METER (OPTIONS) - Google Patents

Abstract

1. The ozone concentration meter, consisting of an ultraviolet radiation source, a cuvette with a holder, a photodetector, a control unit and an indicator, characterized in that a cuvette presence sensor connected to the control unit is introduced, and the control unit, after the cuvette presence sensor is triggered, performs a single measurement of ozone concentration , after which measurements are not made, and the indicator shows the result of the first accurate measurement. 2. The ozone concentration meter according to claim 1, characterized in that the ultraviolet radiation source is connected to the control unit, and the control unit, after the cuvette presence sensor is triggered, turns on the ultraviolet radiation source only for the duration of one measurement. The ozone concentration meter according to claim 1, characterized in that between the ultraviolet radiation source and the cuvette there is a mechanical shutter with a drive that overlaps the radiation, the drive is connected to the control unit, and the control unit, after the cuvette presence sensor is triggered, opens the shutter only for the duration of one measurement. . An ozone concentration meter consisting of an ultraviolet radiation source, a cuvette with a holder, a photodetector, a control unit and an indicator, characterized in that the ultraviolet radiation source is connected to a control unit to which a button is connected, when pressed, the control unit briefly turns on the ultraviolet radiation source only for the duration of one measurement. 5. Ozone concentration meter, consisting of a source of ultraviolet radiation, a cell with a holder, a photodetector, a control unit

Description

The utility model relates to devices designed to measure the concentration of ozone in a liquid medium, and can be used in medicine, as well as in other areas of technology where measurement of the concentration of ozone in a liquid is required.

The ozone concentration meter belongs to a common class of optical ozone meters, the principle of operation of which is based on the absorption of ultraviolet radiation with a wavelength of 253.7 nm by ozone.

The known design of the optical meter of ozone concentration IKOZH-5K (MAYUI.413313.002TU, www.lepse.com).

The meter consists of a source of ultraviolet radiation with a wavelength of 253.7 nm, a cell in which ozonated liquid is poured, a photodetector, a control unit and an indicator. Ultraviolet radiation from the source passes through a cuvette with ozonated liquid and enters the photodetector. In the cuvette, ultraviolet radiation is absorbed to varying degrees depending on the concentration of ozone. This leads to the fact that the voltage at the terminals of the photodetector depends on the concentration of ozone in the cell. After amplification and processing of this voltage in the control unit, the ozone concentration value is obtained.

The meter continuously measures the concentration and displays the measurement results on the indicator.

When measuring by this method, the following problem arises.

Under the influence of ultraviolet radiation on the ozonated liquid in the cell, the concentration of ozone in it decreases and ceases to correspond to the concentration of ozone in the measured liquid. With a sufficiently strong ultraviolet radiation, after a few seconds, a significant drop in ozone concentration occurs.

In fact, only the first dimension is accurate. The error in subsequent measurements increases more and more, as a result of which ultimately the measurements become unsuitable for indication.

The technical problem is to ensure the accuracy of measuring the concentration of ozone in the liquid.

According to the first variant, the solution of the technical problem is achieved by the fact that an ozone concentration meter consisting of an ultraviolet radiation source, a cuvette with a holder, a photodetector, a control unit and an indicator contains a cuvette presence sensor, the signal from which is connected to the control unit to start the measurement process.

Figure 1 shows the structural diagram of the proposed meter of ozone concentration in the liquid.

The meter consists of an ultraviolet radiation source 1, a quartz cell 2 with ozonated liquid, a cell holder 11, a photodetector 3 with an amplifier 4, a control unit 5, an indicator 6, and a cell presence sensor 7.

The photodetector 3 is connected to an amplifier 4, which is connected to the control unit 5. The indicator 6 is connected to the control unit 5.

The presence sensor of the cell 7 is connected to the control unit 5.

The meter operates as follows.

The ultraviolet radiation of the source 1 through the cuvette 2 enters the photodetector 3. Due to absorption in the cuvette 2, the radiation is attenuated. The signals from the photodetector 3 enter the control unit 5, in which the ozone concentration is calculated. The calculated ozone concentration is displayed on indicator 6.

The measurement process is as follows. After installing the cuvette 2 with ozonated liquid in the cuvette holder 11, the cuvette 7 sensor is activated. The signal from the cuvette 7 sensor is sent to the control unit 5, which measures the ozone concentration and displays these results on indicator 6. This measurement may include several quick measurements followed by averaging before displaying.

Further measurements are not made, the indicator constantly shows the result of the first accurate measurement. Due to this, the measurement indication is blocked with an increase in time with an error.

For repeated measurement, it is necessary to remove the cuvette, pour out the used liquid, pour a new portion of ozonized liquid and measure with it.

The sensor for the presence of the cuvette 7 can be made on the basis of the method of overlapping infrared radiation with a cuvette.

The design of such a cell presence sensor is as follows.

Near the two side walls 8 of the cuvette 2 there are a radiating diode 9 and a receiving photodiode 10. The side walls 8 of the cuvette 2 are blackened to prevent transmission of infrared radiation.

In the absence of the cuvette, infrared radiation from the emitting diode 9 through the holes in the holder of the cuvette 11 freely enters the receiving photodiode 10, as a result of which the presence of the cuvette 7 generates a signal indicating the absence of the cuvette.

When installing the cuvette 2 in the holder 11, the infrared radiation is blocked by the blackened walls 8 of the cuvette 2. The absence of infrared radiation leads to a change in the signal of the receiving photodiode 10, as a result of which the sensor 7 generates a signal indicating the presence of the cuvette. This signal enters the control unit 5 and initiates the process of measuring ozone concentration.

To exclude the influence of ultraviolet radiation on the operation of the cell presence sensor, it is possible to introduce modulation of infrared radiation with subsequent processing of the modulated signal in the sensor 7.

According to the second variant, the solution of the technical problem is achieved by the fact that in the ozone concentration meter, consisting of an ultraviolet radiation source, a cuvette with a holder, a photodetector, a control unit, an indicator and a cuvette presence sensor, the ultraviolet radiation source is connected to the control unit, and the control unit after operation The cell presence sensor includes a source of ultraviolet radiation only for the duration of one measurement.

As a source of ultraviolet radiation, a source, for example, an ultraviolet emitting diode connected to the control unit, can be turned on and off rapidly.

The ultraviolet diode is switched on for a short time only for the duration of one measurement, and the moment the diode is turned on is determined by the cell presence sensor.

The structural diagram of the proposed meter, shown in figure 2, is similar to the first option, the difference is as follows.

The emitting ultraviolet diode 1 is connected to the control unit 5.

When the cell 2 is installed in the holder 11, the cell presence sensor is activated, the signal from it enters the control unit 5, which turns on the ultraviolet diode 1 for a short time and measures the concentration of ozone. The diode turn-on time is selected sufficient for one measurement. After measurement, the control unit 5 turns off diode 1, the measurement result is displayed on the indicator.

The advantage of this method is also the increase in the service life of the ultraviolet diode 1, since it is switched on only for a short measurement time.

According to the third option, the solution of the technical problem is achieved by the fact that in the ozone concentration meter, consisting of an ultraviolet radiation source, a cell with a holder, a photodetector, a control unit, an indicator and a cell presence sensor, a mechanical shutter with a drive is located between the ultraviolet radiation source and the cell which is connected to the control unit.

The shutter opens briefly only for the duration of one measurement, and the moment of opening the shutter is determined from the cell presence sensor.

The structural diagram of such a meter is shown in figure 3. Between the source of ultraviolet radiation 1 and the cuvette 2, a mechanical shutter 13 that overlaps the ultraviolet radiation is connected to the drive 14. The drive 14 is connected to the control unit 5.

Such a meter works as follows. When the cell 2 is installed in the holder 11, the sensor for the presence of the cell 7 is triggered. Upon the signal from the sensor 7, the control unit 5 sends a signal to the drive 14 to open the shutter for a short time sufficient to measure the ozone concentration. After opening the shutter, the control unit 5 takes a measurement, displays the result of the measurement on the indicator and sends a signal to the drive 14 to close the shutter 13.

In this embodiment, there is practically no prolonged exposure to ultraviolet radiation of the ozonated liquid in the cell 2, so that it is possible to carry out several measurements of the ozone concentration without filling a new portion of the ozonated liquid.

According to the fourth variant, the solution of the technical problem is achieved by the fact that in the ozone concentration meter, consisting of an ultraviolet radiation source, a cuvette with a holder, a photodetector, a control unit and an indicator, the ultraviolet radiation source is connected to the control unit, to which a button is connected, when pressed, the control unit briefly turns on the source of ultraviolet radiation only for the duration of one measurement.

As a source of ultraviolet radiation, a source that can be turned on and off quickly, for example, an ultraviolet emitting diode connected to the control unit, is used, and a button on the front panel of the meter is used to turn on the ultraviolet diode.

The structural diagram of such a meter is shown in figure 4.

Button 12 located on the front panel of the meter is connected to the control unit 5.

When you press the button 12, the control unit 5 briefly turns on the ultraviolet diode 1 and measures the concentration of ozone. The turn-on time of diode 1 is selected sufficient for one measurement. After measurement, the control unit 5 turns off diode 1, the measurement result is displayed on the indicator.

According to the fifth embodiment, the solution of the technical problem is achieved by the fact that in the ozone concentration meter, consisting of an ultraviolet radiation source, a cuvette with a holder, a photodetector, a control unit and an indicator, a mechanical shutter with a drive that is connected to the radiation is located between the ultraviolet radiation source and the cuvette control unit, and a button on the front panel of the meter is connected to the control unit.

When the button is pressed, the curtain opens for a time sufficient to measure the ozone concentration.

The structural diagram of such a meter is shown in Fig.5.

Button 12 located on the front panel of the meter is connected to the control unit 5.

When you press the button 12, the control unit 5 sends a signal to the actuator 14 to open the shutter 13 for a short time, sufficient to measure the concentration of ozone. After opening the shutter 13, the control unit 5 takes a measurement, displays the result of the measurement on the indicator 6 and sends a signal to the drive 14 to close the shutter 13.

In this embodiment, the time of ultraviolet irradiation of the ozonated liquid in the cell 2 is short, so that it is possible to carry out several measurements of the ozone concentration without filling a new portion of the ozonated liquid.

To simplify the design, it is possible to provide a mechanical connection between the button 12 and the curtain 13. In this case, the opening of the curtain will occur due to the mechanical movement of the button 12.

According to the first option, a prototype of a liquid ozone concentration meter was manufactured and tested at Lepse OJSC.

The proposed technical solution is simple to manufacture and convenient to use, it provides an accurate measurement of the concentration of ozone in the liquid.

Claims (5)

1. The ozone concentration meter, consisting of an ultraviolet radiation source, a cuvette with a holder, a photodetector, a control unit and an indicator, characterized in that a cuvette presence sensor connected to the control unit is introduced, and the control unit, after the cuvette presence sensor is triggered, performs a single measurement of ozone concentration , after which the measurements are not made, and the indicator shows the result of the first accurate measurement. 2. The ozone concentration meter according to claim 1, characterized in that the ultraviolet radiation source is connected to the control unit, and the control unit, after the cuvette presence sensor is triggered, turns on the ultraviolet radiation source only for the duration of one measurement. 3. The ozone concentration meter according to claim 1, characterized in that between the ultraviolet radiation source and the cuvette there is a mechanical shutter with a drive that overlaps the radiation, the drive is connected to the control unit, and the control unit, after the cuvette presence sensor is triggered, opens the shutter only for the duration of one measurement . 4. An ozone concentration meter consisting of an ultraviolet radiation source, a cuvette with a holder, a photodetector, a control unit and an indicator, characterized in that the ultraviolet radiation source is connected to a control unit to which a button is connected, when pressed, the control unit briefly turns on the ultraviolet source radiation only for the duration of one measurement. 5. An ozone concentration meter consisting of an ultraviolet radiation source, a cuvette with a holder, a photodetector, a control unit and an indicator, characterized in that a mechanical shutter with a drive is located between the ultraviolet radiation source and the cuvette, the drive is connected to the control unit to which it is connected button, when pressed, the control unit briefly opens the curtain only for the duration of one measurement.