SU1253962A1 - Method of measuring levels of liquefied gas - Google Patents

Abstract

The invention relates to a measurement technique and allows for increased intrinsic safety by eliminating electrical heating. Sensors of heat flow are placed in a reservoir on a heat-conducting rod, which makes it possible to eliminate their electron heating. At the same time, local heat flux densities between the rod and the medium are measured at different heights. According to the measurement results, the location of the maximum heat flux density is determined, which determines the place where its direction changes, and, accordingly, the position of the liquid level. 2 Il. fi

Description

UH (acquired to measure the level of liquids, in particular, liquefied gases at low temperatures

The aim of the invention is to increase intrinsic safety by eliminating electrical heating and improving measurement accuracy by practically reducing the influence of the sensitivity of the sensors on the measurement result.

The proposed method consists in that heat flux sensors are placed in a reservoir on a heat-conducting rod that serves as a thermal bridge between gas and liquid, and locate. Heat flux densities between the core and the medium in the reservoir flow, indicating the position of the level of rest.

Placing a heat-conducting rod in the tank will prevent electrical heating of the sensors, which causes additional evaporation of the liquid, use natural heat exchange methods between the rod and the medium to measure, and increase intrinsic safety.

Measuring the heat flux densities and determining the location of its maximum value makes it possible to determine the position of the liquid level in the tank.

Determining the position of the level at the location of the change in the direction of the heat flux increases the accuracy of the measurements, since at this point the sensor signal will be zero regardless of its sensitivity. The place where the direction of heat flow changes is above the liquid level, and its position at a constant level of phase separation depends on the values that are constant for a given thermal bridge and the temperature of the liquid. As the fluid level moves, the position of the point of change of the directional heat flow changes proportionally.

Fig, 1 shows the scheme of the dimensioning; in fig. 2 - graphs of the average temperature over the cross section of the rod t, .. and the temperature of the medium (liquid and gas) t. , as well as the heat flux density q between the rod and the medium, depending on

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height H at a certain position of the liquid level.

The temperature of the liquid phase in the tank t is the same at all points and is equal to the saturation temperature for a given gas at an appropriate pressure. The temperature of the gas phase above the liquid, due to external heat, flow and continuous gas extraction, which is formed during the evaporation of the liquid, increases with distance from the surface and has the form shown in the graph.

The temperature of the heat-conducting rod placed in the tank smoothly varies in height. In the lower part immersed in the liquid, the temperature of the rod is higher than the temperature of the liquid due to the transfer of heat from the upper part and here a positive heat flux from the rod to the liquid takes place. In the upper part of the rod protruding from the liquid, its temperature is lower than the temperature of the medium at a corresponding height and here the heat flow is directed from the gas to the rod. At the altitude above the liquid level, the heat flow direction changes from positive to negative. The height of the point of change of direction of the heat flux above the liquid level depends on the thermophysical properties of the rod material, the geometric dimensions and the ratio of the heat transfer coefficients between the rod and the gas phase and between the rod and the liquid.

The heat-conducting rod serves as a thermal bridge between the gas and the liquid, through which a certain amount of heat flows.

The supply of heat from the gas to the rod occurs along the part of the rod protruding from the liquid. This heat is removed from the rod mainly in the upper layer of the liquid, where the maximum density of the heat flow from the rod to Hl-Schia has been observed.

The measurement of the position of the level of compressed gas is made as follows.

The sensors installed on the rod simultaneously measure the heat flux densities between the rod and the medium at various heights. The result is analyzed and the fluid level is determined by the position of the sensor, the signal of which is maximum,

The level can be determined by calculating the value of the height of the change in the direction of the heat flux above the liquid level by the known parameters of the heat-conducting rod, and setting the height of the sensor, whose signal is zero.

The invention is intended for intrinsically safe measurement and remote monitoring of liquefied hydrocarbon gases in low-temperature isothermal high-capacity storages.

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Claims (1)

Invention Formula The method of measuring the level of liquefied gas by placing in the reservoir at different heights of several temperature-sensitive sensors, In order to increase intrinsic safety by eliminating electrical heating, sensors are placed on a heat-conducting rod installed in a tank, local heat flux densities between the rod and the medium in the tank are measured, and the level of liquefied gas is determined by the maximum heat flux density. Woo -I   22 sh Fi.G , fi.2. Editor M. Nedoluzhenko Compiled by M. Nekrasov Tehred M. Khodanich Proofreader L. Pilipenko Z e 4684/27 Circulation 705 VNRSHYI State Committee of the USSR for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 Production and printing company, Uzhgorod, st. Project, 4 Subscription