SU1635070A1 - Device for automatic measurement of fluid density - Google Patents

Abstract

The invention relates to a measuring and control technique, namely, devices for automatically measuring the density of a liquid, and can be used in various industries. The purpose of the invention is to improve the measurement accuracy by compensating for the error associated with fluid oscillations. The measuring system is placed on a toroidal float, in the internal cavity of which there is a corrector float connected to the main float by a diaphragm allowing the main float to move freely relative to the additional float and to correct for vibrations of the device on the surface of the liquid. The introduction of a correction for the temperature fluctuations of the controlled liquid is made by a temperature compensation unit made in the form of a hermetic system filled with easily evaporating liquid. To equalize the pressure, the internal cavities of the conversion unit and the floats communicate with each other, and the floats are provided with channels for communication with the environment. 2 hp ff, 1 ill. Yo

Description

This invention relates to a measurement technique and can be used in various industries.

The purpose of the invention is to improve the measurement accuracy by compensating for errors due to fluid oscillations.

The drawing shows a device for automatic density measurement, a general view.

The device for automatic density measurement consists of a toroidal float 1, a membrane 2 and a transducer for moving the membrane 2 into an electrical signal consisting of a reichord 3 and a slider 4. The membrane 2 is balanced by a calibration spring 5 mounted on the bracket 6. Through the rod 7 the spring 5 loads the membrane 2, flanged to the housing 8. The toroidal float 1 is a supporting structure and a measuring meter of the densitometer is attached to it.

The thermomanometric system consists of a chamber 9 filled with a plug 10 with a light-expanding liquid (for example, ether, toluene, xylene, etc.). The chamber 9 is formed by a lid 11 made of a heat-conducting material with stiffeners to prevent its deformation during expansion of the filler and the bellows 12 attached to the lid 11 by flanges. The bellows 12 is spring-loaded spring 13. With the help of the nut 14 and the scale 15, the system sets the required temperature limits. The nut 14 is hollowed, rotates in the thread

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film 16, and through it passes the rod 17 from the bellows 12 to the Converter.

The displacement transducer of the bellows 12 to the electrical signal is common with the density measurement system, while the reochord 3 is fixed on the membrane 2 of the density measuring system, and the slider 4 of this reichord is mounted through the bracket 18 and the rod 17 is fixed on the bellows 12 of the chamber 9. The bracket 18 is also fixed the slider 19 of the reichord 20 of the temperature measurement system, the reochord 20 is fixed with the bracket 21 to the flanges of the cover 11.

The system of correction for the oscillation of the meter, mounted on the float 1, consists of a float-corrector 22 and a converter of these oscillations into an electrical signal. The conversion is also carried out by the re-chord 3 and the slider 4, but the latter is almost stationary, since the float 22 is on the surface and does not sink into the liquid, and the reochord 3 moves along with the measured system of the float 1 with respect to the pgppavka 22 when the density of the controlled liquid changes. The bracket 21 of the U-shaped form passes through the holes of the bracket 18 also of the U-shaped form.

The float 22 by the rod 23 is connected to the lid 11 of the chamber 9. The second flanges (the first ones are attached below the bellows 12) the lid 11 is mounted in a cut-out along the center of the membrane (diaphragm) 24. The latter is attached by flanges to the upper part of the housing 8, which is fastened with four brackets 25 to the toroidal float 1. The internal cavities of the housing 8 and the float 1 and 22 tubes 26 and 27 communicate with the atmosphere or supra-fluid space of the container, if the latter is under pressure or vacuum. The tube 28 serves to output the wires from the reichordov terminal box 29.

Densitometer works as follows.

The meter is placed on the surface of the liquid, and when measuring the density, the membrane 2 bends and moves the reochord 3, through the slider 4 and the reochord 3 the density readings are taken.

The membrane 2 is constantly at the same immersion depth, since the float 1 keeps it at this depth and, no matter how much the level in the process tank changes, it does not introduce errors into the measurements. On the membrane 2 itself, an ejection force acts, which is proportional to the density (specific weight) of the fluid.

When changing the density of the liquid with small changes, for example from 1

(water density) up to 1.8 kg / m, correction for the meter oscillation - the float 1 is not introduced, since the oscillation of the float 1 is 1-3 mm. Such fluctuations in terms of

the change in the weight of the fluid and, accordingly, the pressure on the membrane 2 at a height of the liquid column above the membrane is 2 200–800 mm (this is the height of the housing 8, chosen during the development of the meter) give an error of 0.01– 0.04%, which corresponds to a high instrument class.

With a change in density, the weight of the liquid column above the membrane 2 changes, the latter is spring loaded by the spring 5, which pulls the membrane 2 down, and the nut 7 sets the limits of measurement.

Under the action of the changing weight of the liquid column, the membrane 2 moves together with the reohord 3 fixed on it,

0 relative to the fixed slider 4. The signal from the transducer (rheochord 3 and slider 4) is transmitted to the secondary device or controller.

When changing the density of the liquid in

5 large limits the oscillation of the immersion of the float 1, and with it the entire measuring system. For example, when the density changes from 1.0 to 2.8 kg / m, it is already necessary to introduce a correction, which

0 the oscillation of the meter — the float 1 is introduced automatically by the float 22 and the transducer mounted on it and the chamber 9. If in the previous case both the floats, the float 1 and the float 22, are fixed

5 relative to each other, in this case, the float 1, and with it the body 8 and the membrane 2 lower as the density decreases.

Float 22 is relatively stationary because it has the best working conditions and

0 very light weight (hollow, made of light materials) compared with the float 1.

The float 22 is inside the float 1 (torus) and is practically not subject to dynamic flow.

The weight of the elements lifted by the float 22 is insignificant, the reocord 20, the sliders 4 and 19 are of instrument type, and chamber 9 and bellows 12 all weigh 50-60 g, chamber

0 9 is filled with a lightly expanding liquid, the specific weight of which is several times less than the specific weight of the measured liquid, therefore the latter tends to push the chamber 9 to the surface and its

5, the buoyancy force 22 helps the float 22 to support the elements suspended to it and to be on the surface itself.

LIQUID.

Float immobility 22 concept of relative, ideal immobility

it can not be. In the application, the immobility of the float 22 is considered not in absolute terms, but relative to the float 1.

Chamber 9 is filled with a liquid (toluene, xylene), the specific weight of which is about 0.86, so the easy-expanding liquid is lighter than water and the minimum density of the controlled liquid, and at the working (average) density of the controlled medium, the easy-expanding liquid is many times easier therefore, the controlled fluid displaces the chamber 9, which tends to float, pushing the float 22. The ejecting force acting on the float 22 itself and on the chamber 9 stably holds the float 22 on the surface of the controlled fluid.

With the minimum density of the controlled liquid, the lower part of the float 22 is on the surface of the liquid, therefore, with a further increase in the density of the controlled liquid, the float 22 cannot be pushed out more (float), all this gives the right to consider the float 22 to be fixed relative to the float 1 and the entire measuring system.

Immersion of the float 1 with a decrease in density from 1.8 to 1 kg / m with a height of a liquid column above the membrane of 2,200 to 800 mm constitutes an insignificant change in weight and, accordingly, pressure on the membrane 2, therefore the meter error even without introducing a correction provides high accuracy measurements. But if the density of the fluid decreases over a wide range and the float 1 descends, and with it the housing 8 descends, the membrane 2 and the rheochord 3 are displaced downward relative to the slider 4, then the resistance in the converter circuit changes. As the density decreases, the column of fluid above membrane 2 becomes lighter, the buoyant force is less and membrane 2 goes down, and the meter also drops below. When lowering the meter, the column of liquid above membrane 2 increases by the amount of immersion of the float 1, the pressure on the membrane 2 becomes greater, although the density does not increase, the float 22 that does not immerse along with the float 1 and restores the slider 4 to the same compensation level The displacement of the membrane 2, and with it the reichord 3 down from the slide 4 increases the resistance in the converter circuit and the meter device, taking into account the additional weight of the liquid column, shows the true density. With an increase in density, the process of introducing correction goes in the reverse order.

The operation of the temperature correction device should be considered as a separate system, not related to oscillations of the floats 1 and 22. No matter how the whole measurement system moves on the float 1 or 22, the sliders 4 and 19 move only when the pressure in the chamber changes 9 formed by a rigid lid 12 of the bellows 12. 0 When the temperature of the measured liquid changes, the pressure in the chamber 9 changes, since the lid 11 is thermally conductive and rigid enough so that the bellows 12 can move the bracket 18 with sliders 4 and 19.

5 The temperature correction system and the temperature measurement unit operate according to the principle of a manometric thermometer, where the thermo-manometric system consists of a thermal bottle, a capillary and a bellows or

0 manometric tubes.

Measurement of the density at varying liquid temperature requires the introduction of a correction for its fluctuation. Temperature correction is introduced by a thermomanometric system when the temperature of the fluid changes. As the temperature rises, the liquid becomes less viscous, the weight of its column above the membrane 2 becomes less, the pressure on the membrane 2 is less and it

0 bends downwards along with the reichord 3, the resistance in the converter circuit increases and the instrument shows an underestimated density, although it is normal at 20 ° C. To prevent this from happening,

5, a correction for temperature change is introduced. When the fluid temperature rises, the filler of chamber 9 expands, presses on the bellows 12. the latter moves the bracket 18 through the rod-17, and with it the slider 4 (with the slider 4 slider 19 moves). Thus, the slider 4 is displaced by the displacement of the reichord 3, the resistance in the converter circuit does not change, the correction is introduced by mechanical

5 by not changing the resistance of the measurement circuits. Before installing the densitometer in the tank, knowing the temperature of the controlled fluid, the nut 14 and the scale 15 use the spring 13 to set the required temperature.

With a decrease in temperature, the process and operation of the thermomanometric system occurs in the reverse order.

Claims (3)

1. An apparatus for automatically measuring the density of a liquid, comprising a float, a temperature compensation unit connected to it, consisting of a sensing element-bellows filled an easily evaporating fluid, and a measuring signal conversion unit, characterized in that, in order to increase measurement accuracy by compensating for errors due to fluid oscillations, the float is made of a toroidal shape, in the inner cavity of which there is an additional equalizer float . 2. The device according to claim 1, that is, so that the sensitive element is strong The background of the temperature compensation unit on top is provided with a lid, made of heat-conducting material, with stiffeners, located on the spring and connected to the conversion unit of the measuring signal. 3. Pop-1 device, characterized in that the cavities of the floats and the measuring signal conversion unit are interconnected by means of channels, and the floats are provided with channels for communication with the environment, nineteen eleven Flanges Editor M.Petrova Compiled by V.Kalikov Tehred M. Morgental - Dipped П 13 № Н 15 21 I .1 lit Notch Proofreader L. Pilipenko