RU66002U1 - AUTOMATIC GAS ODORIZER - Google Patents

Abstract

An automatic gas odorizer is designed to supply an odorant to a stream of natural gas in order to give it an odor and can be used at gas distribution stations. The gas cavity of the measuring tank (12) is connected to the supply tank (18) and through the solenoid valve (10) to the output of the reduction unit (3) installed on the main gas pipeline (1). The lack of a sufficient pressure drop between the measuring tank (12) and the supply tank (18) in the event of a leak in the solenoid valve (10) eliminates spontaneous flow of the odorant into the measuring tank, which makes it possible to increase the dosing accuracy, 1 ill.

Description

The utility model relates to pipeline transport, namely, to installations for the dosed introduction of chemicals into the transported natural gas and can be used in the gas industry at gas distribution stations to supply odorant to the gas stream in order to give it an odor.

Known automatic gas odorizer (see US Pat. No. 48696A, IPC F17D 3/12, B01F 3/04, 2001), which contains a gas main with a reduction unit, a gas reducer, a flow tank filled with an odorant, and a dispenser. A disadvantage of the known odorizer is the insufficient dosing accuracy, since a hydraulic dependence is used to calculate the actual consumption of the odorant and ensure its metered introduction into the gas.

Closest to the claimed technical solution is an automatic gas odorizer (see US Pat. No. 5787, IPC F17D 3/12, B01F 3/04, 2004), comprising a gas main with a reduction unit, the outlet of which is connected by a gas pipeline to a flowmeter consisting of a sensor the level of the odorant and the measuring tank, which has a gas cavity that is not filled with an odorant, a gas reducer, a dispenser, an electromagnetic valve and a supply tank. In this design, the actual odorant consumption is measured by a flow meter, however, with this design, the solenoid valve located on the hydraulic pipe connecting the measuring and supply containers can pass the odorant from the supply tank to the measuring one. As a result, it is impossible to accurately measure the amount of odorant coming from the measuring tank into the main gas pipeline.

The utility model is based on the task of improving the automatic gas odorizer in order to increase dosing accuracy.

The problem is solved due to the fact that in the automatic gas odorizer containing the main gas pipeline with a reduction unit, the outlet of which is connected by a gas pipeline to a flow meter consisting of an odorant level sensor and a measuring tank having a gas cavity that is not filled with an odorant, a gas reducer, a dispenser, an electromagnetic valve and supply capacity, according to the technical solution, the supply capacity is connected to the gas cavity of the measuring capacity, and the electromagnetic valve is installed on the gas pipeline connecting the outlet reduction unit with a gas cavity measuring capacity.

The connection of the supply tank with the measured gas cavity and the fact that the solenoid valve is installed on the gas pipeline connecting the outlet from the reduction unit to the measured cavity gas cavity, in the case of a solenoid valve leak, eliminates spontaneous flow of the odorant into the measured tank from the flow tank, since there is no sufficient pressure differential between these containers, which improves the accuracy of dosing.

In FIG. The gas-hydraulic diagram of the proposed automatic gas odorizer is presented.

The automatic gas odorizer contains a gas main 1 with metering units 2 and reduction 3 installed on it, connected by gas lines 4 and 5 to a gas reducer 6, in the outlet gas pipeline 7 of which a check valve 8 is installed. The output of the reduction unit 3 by gas pipelines 5 and 9 is connected through an electromagnetic valve 10 and a throttle 11 with a gas cavity of the measuring tank 12, the odorant level in which is measured by a level sensor 13. The gas cavity of the measuring tank 12 is connected to the gas lines 14 and 7 through the choke 15

a gas reducer 6, and a hydraulic line 16 through a throttle 17 is connected to a flow tank 18. Measured tank 12 is connected by a hydraulic wire 19 to the dispenser 20 and the main pipe 1.

Automatic gas odorizer works as follows. Gas is taken from the main gas pipeline 1 to the reduction unit 3 and supplied by a gas pipeline 4 to the inlet of the gas reducer 6, then through the check valve 8 through the pipeline 7 the gas enters through the throttle 14 into the gas cavity of the measuring tank 12 and into the flow tank 18, the pressure of which is in static are equalized. At the command of the control system (not shown in Fig.), An odorant is injected through the dispenser 20 through the dispenser 20 into the main pipeline 1. The actual odorant consumption is determined by the readings of the level sensor 13. When the odorant level is reduced to a minimum in the measuring tank 12, the solenoid valve 10 opens and under the influence of excess pressure in the supply tank 18, the odorant through the throttle 17 through the hydraulic line 16 enters the measuring tank 12, and gas from the gas cavity of the measuring tank 12 through the throttle 11 and the electromagnetic valve 10 return in ag ood sort gas pipeline 1, the downstream metering station 3 to 2. Once the level of odorant in a measuring container 12 is lifted to the maximum, the solenoid valve 10 closes. The pressure in the gas cavity of the measuring tank 12 becomes equal to the pressure in the supply tank 18, and replenishment of the measuring tank 12 with an odorant is stopped.

Claims (1)

An automatic gas odorizer comprising a main gas pipeline with a reduction unit, the outlet of which is connected by a gas pipeline to a flow meter consisting of an odorant level sensor and a measuring tank having a gas cavity not filled with an odorant, a gas reducer, a dispenser, an electromagnetic valve and a flow tank, characterized in that the flow tank connected to the gas cavity of the measured capacity, and the electromagnetic valve is installed on the gas pipe connecting the output of the reduction unit with the gas cavity of the measured capacity.