SU145027A1 - Thermal gas equivalent sensor - Google Patents

Description

Instruments are known for measuring heat fluxes and, in particular, for measuring the "Wobbe index. In known devices there are two coaxial tubes. The difference between the proposed sensor is that the two coaxial pipes are rigidly connected to each other at one end and serve simultaneously for thermal compensation of the measured parameter.

The sensor for determining the thermal equivalent of a gas is structurally made in the form of two coaxial tubes rigidly interconnected by their lower ends. The upper end of the outer tube is rigidly connected to the base, and a nozzle-flap system is mounted on the upper end of the inner tube, the flap being made in the form of a micrometric screw, which measures the gap between the nozzle and flap. The heat generated by the combustion of the gas heats the tubes, and their elongation from heating is proportional to the calorific value of the gas and inversely proportional to the square root of the specific gravity of the gas.

Diagram of the device shown in the drawing.

The device consists of two main parts, one of which regulates the flow rate of the gas entering the burner, and the other determines the heat generated during the combustion of this gas.

The test gas passes through the cleaning filters (not shown in the diagram) and enters the pressure regulator 1 of the bell type with mercury filling, after which the residual gas pressure is 25-30 mm water column. The gas then enters the pressure regulator 2 with glycerol filling, which maintains a gas pressure of 12 mm water. Art. with high precision, after which it enters the ejector of the burner 5 and its pressure drops.

The air required for the combustion of gas is injected by the burner from the environment through the casing of the sensing element 4.

jYo 145027-2 The heat generated by the combustion of gas heats the differential tubes 5 of the sensing element and is lost to the environment.

When the ambient temperature changes, both tubes are lengthened so that their differential elongation is zero.

Differential tubes are rigidly connected to the lower ends with each other. The upper end of the outer tube is rigidly connected to the base (basal plane) 6, the head with the nozzle 7 of the nozzle-flap element is mounted on the upper end of the inner tube. The flap is a micrometric screw 8, which measures the gap between the nozzle and the flap with a very high accuracy, thereby setting the required measuring range.

The impulse air pressure in front of the nozzle, proportional to the differential elongation of the tubes, i.e., proportional to the thermal equivalent of the test gas, is amplified in pneumatic relay 9 of type 04 and fed to the automatic control system.

Since the combustion products of the test gas exit the device with a temperature above 100 ° C and the moisture of the combustion products in the device does not condense, the device determines the lower thermal equivalent of gas (similarly to the lower calorific value of gas).

Since the physical state of the test gas does not change until the combustion (the gas is not moistened and does not lead to a constant temperature), the device determines the thermal equivalent of the actual gas.

According to Giprokoks, the proposed sensor is recommended to be introduced into the system of automating the heating of coke ovens, which creates great savings, and be used in other industries where automatic maintenance of constant torch parameters is required.

Subject invention

A thermal gas equivalent sensor consisting of two coaxial tubes and a nozzle-flap system for remote pulse transmission, characterized in that, in order to use the tubes as a combustion chamber, to compensate for the influence of the ambient temperature and to measure the low thermal equivalent of the measured gas, tube ends are rigidly interconnected.