RU55137U1 - REMOTE DEVICE FOR DETERMINING HARMFUL SUBSTANCES IN THE ATMOSPHERE - Google Patents

Abstract

The remote device for determining harmful substances in the atmosphere relates to instrumentation, and in particular to the field of means for selecting and analyzing industrial emissions, and can be used to control the air basin in cities and industrial centers, including on industrial sites of enterprises and highways. The objective of the utility model is to improve the operational characteristics of the device, which consists in reducing the time for conducting qualitative and quantitative analysis of the sample. The technical result that can be obtained using the utility model consists in the possibility of determining various types of organic and inorganic compounds in the atmosphere under study and the prompt transfer of the obtained data to the display of a stationary control center; the possibility of promptly obtaining a quantitative relative estimate of the concentration of a harmful substance in the studied atmosphere; the possibility of implementing a comprehensive study of the composition of a harmful substance through the use of sorption cartridges. The problem is achieved in that the remote device for determining harmful substances in the atmosphere contains electro-pneumatic valves, sorption elements, an aspirator and a control system. In this case, the sorption elements consist of flat indicator elements with a diverse sorbent composition and of sorption cartridges, the joint outputs of which are connected to the inlet of the aspirator, while a photosensitive element is added to the control system, the input of which is optically connected to one of the flat indicator elements and has two outputs , the first output through an amplification-converting device is connected to an electro-pneumatic valve placed in the air line for sorption cartridges, and the signal from the second ode through comparator unit associated with the reference data block is supplied to the display device, wherein the comparator unit and the reference data display placed at a stationary control station. 2 ill.

Description

The utility model relates to instrumentation, in particular to devices for sampling atmospheric air, and can be used to control the cleanliness of the air in cities and industrial sites of enterprises and highways.

A device for automatic sampling of atmospheric air, containing an air line, a flow meter, a flow meter, an impurity storage device and a control unit (USSR Author's Certificate N 1265520, IPC G 01 N 1/22, 1986).

The disadvantages of this device are the high complexity and low reliability of sampling. In addition, the reliability of the samples taken depends on the measurement error of the sampling time. These disadvantages are partially eliminated in the device for automatic sampling of atmospheric air according to the patent of the Russian Federation No. 2057314, IPC G 01 N 1/22 dated 03/27/1996. It contains an air line, a block of pneumatic valves, a block of accumulators of impurities with sampling channels. The air distributor, the pneumatic valve block and the impurity storage block are made in the form of an autonomous replaceable module, which is replaced after the end of the sampling cycles. In the module, a block of pneumatic valves is installed in front of the block of accumulators of impurities. The number of pneumatic valves corresponds to the number of sampling cycles. The device also contains a flow stabilization unit, including flow controllers for each sampling channel, an air collector and a total flow meter, and connected to a flow driver. The device includes a control unit with a time unit.

However, this device has low reliability. This is due to its complex device, because it contains a large number of parts and overhead lines, which requires the need for pneumatic switching and the development of a special control system for it.

The closest in technical essence and the achieved technical effect to the proposed technical solution is "Device for automatic sampling of atmospheric air" (RF patent No. 48414, IPC G 01 N 1/22 from 01.07.2005).

This device contains an air line, an air distributor, a block of pneumatic valves, a block of accumulators of impurities with sampling channels, a flow stabilization unit, a flow inducer and a control unit. In turn, the block of impurity accumulators with sampling channels is made in the form of sorption cartridges with several types of various sorbents, moreover, pneumatic valves are installed both at their inlet and at their outlet, and the block

stabilization of the flow and the flow inducer is made in the form of an aspirator, while the control unit is connected to both the aspirator and the block of pneumatic valves. This device allows you to perform a large number of sampling cycles due to the possibility of installing additional sorption cartridges, each of which allows you to study different types of organic and inorganic compounds due to the use of several types of sorbents in one sorption cartridge. The reliability of the sample increases, because sorption cartridge opens only for the period of its selection. The reliability of the device is increased by reducing the number of blocks. The operational characteristics of the device are improved, because an aspirator manufactured and certified by the industry is used, which leads to a reduction in the complexity of the operations performed.

The disadvantage of this device is the long time required to analyze the sample.

The objective of the utility model is to improve the operational characteristics of the device, which consists in reducing the time for conducting qualitative and quantitative analysis of the sample.

The technical result that can be obtained using the utility model is as follows:

- the ability to determine various types of organic and inorganic compounds in the atmosphere and the prompt transfer of data to the display of a stationary control center;

- the ability to quickly obtain a quantitative relative estimate of the concentration of a harmful substance in the atmosphere under study;

- the possibility of implementing a comprehensive study of the composition of a harmful substance through the use of sorption cartridges.

The problem is achieved in that the remote device for determining harmful substances in the atmosphere contains electro-pneumatic valves, sorption elements, an aspirator and a control system. In this case, the sorption elements consist of flat indicator elements with a diverse sorbent composition and of sorption cartridges, the joint outputs of which are connected to the inlet of the aspirator, while a photosensitive element is added to the control system, the input of which is optically connected to one of the flat indicator elements and has two outputs , the first output through an amplification-converting device is connected to an electro-pneumatic valve placed in the air line for sorption cartridges, and the signal from the second ode through comparator unit associated with the reference data block is supplied to the display device, wherein the comparator unit and the reference data display

placed at a stationary control post.

The essence of the utility model is illustrated by drawings, where Fig. 1 shows a block diagram of a device, and Fig. 2 shows a device and an operating principle of flat indicator elements with a diverse sorbent composition,

where: 1 - flat indicator elements with a diverse sorbent composition;

2 - sorption cartridges;

3 - photosensitive element;

4 - amplifier-converting device;

5 - electro-pneumatic valve;

6 - aspirator;

7 - a comparison device;

8 - block reference data;

9 - display

10 - cells with flat indicator elements;

11 - housing of the movable part of the device.

The remote device for determining harmful substances in the atmosphere consists of two main parts: mobile (measuring) “A” and stationary (recording) “B” (Fig. 1).

The movable (measuring) part “A” of the device consists of sorption elements, which are flat indicator elements with a variety of sorption composition 1 and of sorption cartridges 2. In this case, the flat indicator elements 1 are constantly connected to the analyzed atmosphere. The outputs of the flat indicator elements 1 and sorption cartridges 2 are connected to the inlet of the aspirator.

To quickly obtain an estimate of the infection in the atmosphere under study by various types of organic and inorganic compounds, a photosensitive element 3 was introduced, the input of which is optically connected to one of the flat indicator elements 1 and which has two outputs. One of the outputs of the photosensitive element 3 through an amplification-converting device 4 is connected to an electro-pneumatic valve 5 located in the air line for sorption cartridges 2. The analyzed air, both after flat indicator elements 1 and after sorption cartridges 2, enters the aspirator 6, which simultaneously determines and supports the set flow rate, as well as the sampling time, as It includes a timer, a flow meter, and an air flow meter. Thus, the aspirator b is designed to pump air through the flat indicator elements 1 and sorption cartridges 2 for a given time and with a given flow rate.

The signal from the second output of the photosensitive element 3 through the comparison device 7, associated with the reference data unit 8, is received on the display 9 of the device.

The stationary part “B” of the device consists of a comparator 7, a reference data unit 8 and a display 9 and is located at a stationary control station.

The device operates as follows.

For sampling of atmospheric air, it is necessary to give a command from the control system to the message of the cells 11 with flat indicator elements 1 located in the housing 10, with the atmosphere (figure 2). At the same time, the start time of the operation of this channel for sampling air and the volumetric flow rate of air passing through it are set, and the air flow inducer installed in the aspirator 6 is turned on. Upon reaching the specified volume of air flow, the aspirator flow inducer 6 is turned off.

In the event that there is evidence in the atmospheric air of that poisonous substance to which the operation of this indicator element 2 is configured, the color of its sorbent composition changes. The signal about the color change through the photosensitive element 3 is supplied to the comparator 7, which simultaneously receives a signal from the reference data unit 8. As a result of their comparison, information on the type of harmful substance and the relative degree of infection with it is displayed on the display 9, which is located at the stationary control station atmospheric air.

At the same time, the signal from the photosensitive element 3 through the amplification-converting device 4 is fed to the electro-pneumatic valve 5. It is triggered and the test air from the air line enters the sorption cartridges 2. After the remote device detects harmful substances in the atmosphere of the sorption cartridges 2, they are removed from the apparatus and examined laboratory conditions

The device allows you to simultaneously perform a large number of diverse sampling by installing flat indicator elements of various types, each of which allows you to explore different types of organic and inorganic compounds. Sampler performance increases as its result becomes apparent immediately after pumping air through the flat indicator elements. The reliability of the samples increases because flat indicator elements open only for the selection period. The operational characteristics of the device are improved, because an aspirator and flat indicator elements manufactured and certified by the industry are used. This device can be used to obtain quick information on the assessment of atmospheric pollution on the display of a stationary control station in order to make further operational decisions.

Claims (1)

A remote device for determining harmful substances in the atmosphere, containing sorption elements, an aspirator, electro-pneumatic valves and a control system, characterized in that the sorption elements consist of flat indicator elements with a diverse sorption composition and of sorption cartridges, the joint outputs of which are connected to the inlet of the aspirator, while the control system additionally introduced a photosensitive element, the input of which is optically connected to one of the flat indicator elements and has two outputs, the first the th output through the amplifying-converting device is connected to an electro-pneumatic valve placed on the sorption cartridges in the air line, and the signal from the second output through the comparison device connected to the reference data block is sent to the device’s display, and the comparison device, the reference data block, and the display are placed on stationary control post.