SU515974A1 - Gas analyzer - Google Patents

Description

one

The invention relates to the technique of analytical engineering and can be used in chemical, metallurgical

and other OTR: SLOWS OF READINESS.

A gas analyzer is known, which includes a comparative, measuring and bubbling cuvettes, metering devices, reagent tanks, a controller, a regulator and a booster of the gas to be analyzed, a tank for discharging waste reagent.

In a known gas analyzer, a large specific volume and weight (about 25%) occupies the capacity for the spent reagent, which in most cases can be discharged to sanitary standards. In addition, for discharging the spent reagents from the measuring and bubbling cuvette, the container for the spent reagent must be airtight and specially designed. All this increases the size and weight of the device, and also adds known inconveniences during the operation of the gas analyzer.

The aim of the invention is to improve the reliability of measurements of the gas analyzer.

The goal is achieved by the fact that the tank for draining the spent reagent is equipped with a rod with coaxially arranged crossbars.

In addition, the goal is achieved by the fact that the upper cross member of the rod is made

in the form of support and centering shanoy for reciprocating drive schoka. The middle cross member is made in the form of a hortic horizontal spool with vertical perforations, and the lower cross member is provided with a cone for sealing the volume from the top, and another cone for sealing the drain channel from the bottom. In the drawing is shown in Fig.

scheme of the proposed gas analyzer.

The gas analyzer has a series connection of the input filter 1, the gas channel 2, the measuring cell 3, the bubbling cell 4, the gas channel 5, and the hollow

volume 6, the output gas channel 1. the flow rate controller of the test gas 8, the flow rate booster of the test gas 9, the compressed air line 10 and the commander 11. In addition, metering devices 12 and 13 connected in parallel with liquid channels 14 and 15 are connected to line 10 with containers 16 and 17, in which the necessary reagents are poured. Measuring cuvette 3 is also connected

through the gas-liquid channel 18 with a multidimensional volume 6 and through it can be connected to the output gas channel 19, which is connected to the operating gas flow rate 20, which is connected through the pneumopite line PII 21 to the command-and-ordinate 11.

Bubbler cuvette 4 through the liquid channel 22 is connected with a comparative cuvette 23, and the latter through the liquid channel

24 is connected to the metering device 12. In addition, the cuvette 4 through the liquid channel

25 is connected to the metering device 13.

In the hollow volume 6, there is a jig 26 with an upper crossmember 27, to which a reciprocating actuator 28 is attached. On the jib 26 there is a middle cross bar 29, made in the form of a horizontal spool with vertical holes 30. Next on the jib 26 there is a lower crossbar 31 with an upper a cone 32 and a lower cone 33 extending into the drain channel 34 of the hollow volume 6.

In addition, the controller 11 is associated with a measuring circuit consisting of photoresistances 35, light filters 36 and light bulbs 37.

After pouring the corresponding reagents in the tank 16 and 17 and connecting the electrical and pneumatic supply of the gas gasket / .izator is ready for operation.

The cycle begins with the supply of a pneumatic command from the command device I through the compressed air line 10 to the metering devices 12 and 13, as well as to the consumption gas of the test gas 9. The metering device 12 takes the reagent and the liquid channel 24 through the channel 14 through the comparative liquid cuvette 23 channel 22 delivers the dose to the bubbling cuvette 4. At the same time, the dosing device 13 picks up the reagent from the tank 17 through the liquid channel 15 and feeds the dose to the bubbling cuvette 4. through the liquid channel 25. gas 9, flow regulator of the analyzed gas 8, the output gas channel 7, part of the hollow volume 6, the gas channel 5 creates a discharge in the bubbling chamber 4 and the gas to be analyzed, pass through the inlet filter 1, the gas channel 2, the measuring cuvette 3, the connection in a bubbling chamber 4 with complex reagent. After some time required for bubbling of a certain amount of the analyzed gas, bubbling on command from the command device 11 for 1 channel. When this metering device 12 and 13, respectively, take a new dose through the liquid channels 14 and 15 from the tanks with reagents 16 and 17 and wait for the next cycle.

At the same time, the reacted complex reagent from the bubbling chamber 4 is fed to measuring cell 3. After some time required to remove bubbles of the analyzed gas from the complex reaction, using the command device AND, photoresistors 35, light filters 36, light bulbs 37 and comparative cell 23 are produced Measurement of the optical density of the complex reagent reacted with the analyzed gas with respect to the optical density of the reagent in a comparative cell

23. The resulting electrical signal is proportional to the concentration of the analyzed gas. After that, from the command device 11 enters the pneumatic command to drain. At the same time, compressed air passes through the pneumatic supply line 21 to the gas flow rate stimulator 20 connected via the output gas channel 19 to the hollow volume 6 and via the pneumatic line 21 to the reciprocating actuator 28,

which is rigidly fixed to the upper crossbar 27 of the stem 26 and to the hollow volume 6. The actuator 28 lowers the brush 26 together with its crossbars 27, 29 and 31 until the tapered portion 33 seals the drain channel 34. In addition, the spool 29 will shut off tightly channels 5 and 7 and connect channels 18 and 19. The gas flow rate stimulator 20 through channel 19 creates discharge in the hollow volume 6 and gas-liquid channel 18. Under

under the action of discharge, the spent complex reactant enters through the gas-liquid channel 18 into the hollow volume 6 on the body of the spool 29 and through the vertical conical holes 30 completely drains to the conical

part 32 of the lower cross member 31. At the end of the pneumatic command, the suction of the command device 11 of the jaws 26 rises upwards under the action of the reciprocating actuator 28. At this time, the lower conical part 33 of the lower cross member 31 depressurizes the drain channel 34, and the spent complex reactant flows up from the conical part 32 of the lower cross member 31 and flows through the drain channel 34 directly into the sewer during the movement of the rod 26 upward. The rod 26 is in its original position when the channels 18 and 19 are hermetically closed by the spool 29, and the gas channels 5 and 7 are connected with hermetic locking with the tapered part 32 of the lower

hollow volume bars 31. The cycle and operations are then repeated.

The use of a functional device to ensure the discharge of the spent reagent from the measuring cell directly

In the sewage system, it was possible to get rid of the hermetic drain tank, which is equal in volume, size and weight to the sum of the volumes, weights and dimensions of the tanks with reagents that make up the complex reagent.

It also made it possible to simplify the design of the gas analyzer, reduce its overall weight by 20%, reduce its size and reduce operating costs by eliminating the loss of time spent on servicing the drainage tank.

Claims (4)

1. Gas analyzer containing measuring, comparative and bubbling cuvettes, metering devices, containers with reagents, command device, regulator and booster of the analyzed gas flow, capacity for discharging the spent reagent, in order to improve the reliability of measurements, the capacity for discharging the spent reagent is provided with a rod with coaxially arranged crossbars. 2. The gas analyzer according to p .1, is different, and with the fact that the upper cross member is designed as a washer. 3. Gas analyzer on PP. 1 and 2, characterized in that the middle cross member is made in the form of a horizontal spool with vertical bypass openings. 4. Gas analyzer on PP. 1-3, it is different, and with the fact that the lower cross member is made in the form of a biconical cylinder.   Jj