DE4001341A1 - Viscosity measurement of fluids over wide shear rate range - uses viscometer with upper wide bore capillary and pressure connectors and lower narrow bore capillary - Google Patents

Abstract

Measurement of fluid viscosity over a wide range of shear rates is achieved by a capillary viscometer, the upper capillary tube of which has a broad tubular section and the lower tube has a narrow section. Two different shear rates and pressure sections and using established formula the fluid viscosity can be determined relative to the recorded shear rates. USE/ADVANTAGE - The appts. is used to measure fluid viscosity over a wide range of shear rates and used a single piece of equipment and a standardised method.

Description

The invention relates to an apparatus and a method using this device for viscosity measurement of Liquids over a wide shear rate rich, whereby under liquids also liquid mixtures, Solutions, suspensions or emulsions are to be understood.

In order to be able to measure the viscosity η _{i of} a liquid over a wide range of shear rates, for example more than five powers of ten, it was previously necessary to combine several measurement methods with one another. At low shear rates, the viscosity is determined using rotary viscometers, such as plate-plate rheometers, cone-plate rheometers or coaxial cylinder rheometers. The viscosity can then be determined from the angular velocity and the torque. At high shear speeds, viscosity determination with the capillary rheometer is the method of choice. The liquid to be measured is pressed through a capillary and the viscosity is determined from the flow rate and the pressure drop in the capillary (DE-A 27 19 626). Such methods are described, for example, in K. Baring, Testing of High Polymer Materials, Munich 1977, page 389.

The disadvantage of these methods is that viscous physical measurement over a wide range of shear rates, with two different devices, two different ones Series of measurements must be performed and from each of these principally different series of measurements, with differ corrections, first calculate the true viscosity function can be net.

There was therefore the task of a device for viscose to develop a physical measurement by means of an apparatus and with a uniform measuring method, the viscosity of Liquids over a wide range of shear rates can be determined.

The invention relates to a device for viscose measurement of liquids over a wide range of minions speed range consisting of a, if necessary thermostatted, equipped with a conveyor unit, Capillary viscometer, characterized in that the capillary tube is composed of two tube sections is, a wide pipe section arranged above and one adjoining narrow pipe section, whereby for measuring the pressure drop in the upper pipe section two Connections of a differential pressure transducer or two conv tional pressure transducers mounted at a distance from each other are and to measure the pressure drop in the narrow pipe section the ambient pressure, at the end of the wide pipe section or a conventional one at the beginning of the narrow pipe section Pressure sensor is arranged.

The capillary viscometer according to the invention is together sets out of a conveyor unit to promote the test liquid and a capillary unit, by means of which the vis determination of the necessary measurement variables.  

The liquid to be tested is fed with a delivery unit, for example a piston press, a screw extruder or a gear pump in the capillary, where the volume throughput was kept constant during a measurement becomes. The volume throughput is calculated in a known manner from the delivery capacity of the corresponding delivery units. In piston presses, for example, from the product of pistons area and piston speed, with screw extruders the product of liquid throughput and density.

Because the viscosity largely depends on the temperature of the rivers liquidity can be used to maintain the tem constant temperature during the measurement of the conveyor unit and Ka pillare can be tempered, for example via resistance radiator or liquid heating or cooling.

The capillary unit is composed of the capillary, as well as the pressure transducers or the differential pressure transducer, which may increase mechanical stability can be embedded in a cylinder.

The capillary is composed of two tube sections:
A wide capillary section (nozzle) and a narrower capillary section (nozzle) adjoining in the direction of flow. The two sections can be both round nozzles, rectangular nozzles or circular slot nozzles, or any suitable combination thereof. The upper tube section is preferably designed as a rectangular nozzle and the adjoining tube section as a round nozzle.

The ratio of the cross-sectional areas of the wide nozzle to subsequent narrow nozzle essentially depends on the con resistance of the liquid to be measured. Preferably be the ratio is 5: 1 to 50: 1. The same applies to the  Lengths of the two capillary sections, each preferably because they are between 5 and 200 mm.

To determine the pressure gradient are in the wide capillary Section two connections of a differential pressure sensor or two conventional pressure transducers at a distance from each other the arranged. The distance depends primarily on the measuring sensitivity of the differential pressure transducer or Pressure transducer. As a differential pressure transducer or conv tional pressure transducers can be used with commercially available devices be used. It is only important to ensure that the sensitivity is adapted to the measuring conditions and the Membranes in the pressure transducers withstand the pressure that is built up by the downstream narrow capillary. These Adjustments can be made in a known manner through exchange the diaphragms in the pressure transducers.

At the end of the wide capillary section, before narrowing to downstream narrow capillary section, or at the beginning of the narrow capillary section is a commercially available convention neller pressure transducer, for example a front membrane Pressure sensor arranged, by means of which the pressure drop to Ambient pressure along the length of the narrow capillary section can be determined.

This device according to the invention makes it possible to determine the viscosities over a wide shear rate range. For a given delivery rate for a measurement i, only small pressure differences Δp ₁ (i) and low shear rates (i) arise in the wide capillary section. The pressure difference Δp₁ (i) is measured and read off via the differential pressure transducer or two conventional pressure transducers or passed on to a computer for calculating the viscosity.

In the following narrow nozzle, the cross-sectional constriction results in a higher differential pressure Δp ₂ (i) to the ambient pressure and a higher gravity (i). The pressure drop at a higher shear rate is measured via a pressure sensor at the transition from the wide to the narrow nozzle or a pressure sensor at the narrow nozzle, and the signal is read off or forwarded to a computer for calculating the viscosity.

The narrow capillary section also acts on Mes solutions at low shear speed as a throttle, because without this arrangement, a measurement for small minions speed in the wide nozzle would not be possible because in in this case, flow through the test liquid on its own would.

With the arrangement according to the invention, the differences can thus limit pressures at two different ones, depending on the dimension tion as far apart as possible, shear rate be determined. From several measurements at under As a result, the different viscous output quantities are obtained η of the test liquid as a function of the minions speed.

The device according to the invention can determine viscosity with any liquids, liquid mixtures, Solutions, suspensions or emulsions are used. One area of application is, for example, the measurement of shear rate-dependent viscosity of PVC pastes.

In Fig. 1, the construction principle of the device according to the invention is described in more detail. The upper white capillary 4 is filled with the test liquid via a piston press with a cylinder 1 and a piston 2 . The narrow capillary 5 adjoins the wide capillary 4 . To determine the differential pressure in the upper capillary section 4 , the connections 3 of the differential pressure transducer are mounted at a distance from one another. At the lower end of the wide capillary 4 , a conventional pressure transducer 6 is arranged to measure the absolute pressure in front of the narrow capillary 5 . The sleeve screw 7 enables the capillary 5 to be changed quickly.

example

As an example of how the invention works, the Viscosity of two PVC pastes depending on the shear speed determined. When the capillary became wider a rectangular nozzle with a length of 120 mm and a base area of 10 mm × 2 mm inserted. The distance between the ports of the Dif reference pressure transducer was 80 mm. As a narrow capillary a round nozzle with a length of 30 mm and a diameter was cut knife of 1 mm inserted. The pressure sensor for determination The pressure drop across the length of the round nozzle was at End of the rectangular nozzle arranged before the transition to the round nozzle net. The capillary was closed with a piston press Channel diameter of 15 mm filled.

In the table are the shear rates (i) and the viscosities for the two pastes with the viscosities 1 and 10 Pa · s, from the measured quantities feed rate v (i) and the pressures p ₁ (i), p ₂ (i) η _i calculated using the following equations:

table

Claims (1)

Device for viscosity measurement of liquids over a wide shear rate range consisting of a, optionally thermostatted, capillary viscometer equipped with a delivery unit, as characterized by
that the capillary tube is composed of two tube sections, a wide tube section arranged at the top and an adjoining narrow tube section, where at
to measure the pressure drop in the upper pipe section two connections of a differential pressure transducer or two conventional pressure transducers are placed at a distance from each other, and
to measure the pressure drop in the narrow pipe section ge against the ambient pressure, at the end of the wide pipe section or at the narrow pipe section, a conventional pressure sensor is arranged.