DE2452442C3 - Kapi hair viscometer - Google Patents

Description

50

The invention relates to a capillary viscometer according to the preamble of claim 1.

Such a capillary viscometer is preferably used to examine the viscosity of a die The flow curve showing the dependence of the shear speed on the shear stress disperse and polymeric systems of a material to be investigated are used.

There are known capillary viscometer, in which the force of a pre-compressed spring a being transferred to the material under investigation from a chamber through a capillary-displacing piston ^ _0, the displacement is registered by a registration device (see for. Example SU Inventor's Certificate 485, Class GOlNl 1/08).

With the mentioned capillary viscometer for measuring the dependency of the viscosity of the to be examined Material from the pressure drop in the capillary and the A tared spring is used, which changes during the measuring process Pressure is generated on the material to be examined, which is accommodated in the chamber, causing it to variable speed runs out of the capillary.

The displacement of the piston displacing the material from the chamber is recorded with the aid of the recording device recorded as a function of time, followed by the thrust speed and the Voltage can be calculated. However, the record resulting from the recorder requires the Measurement results a subsequent evaluation - a graphic differentiation and logarithmization for Preservation of the results in a form suitable for analysis in the form of a graphic representation the dependence of the shear speed on the shear stress using a logarithmic Depiction.

In addition, when working with this viscometer it is necessary to adjust the recording speed, based on the shape of the curve to be registered, to switch manually, which is inconvenient and at rapidly changing speeds is not always possible.

The object of the invention is to provide a capillary viscometer while avoiding the above-mentioned disadvantages to create that has additional units that allow the shear stress and speed and at the same time in the form of a flow curve without additional calculations and in to register more favorable logarithmic representation.

This object is achieved according to the invention in a capillary viscometer of the type mentioned at the outset by the features according to the characterizing part of claim 1.

The invention is developed in an advantageous manner by the teaching according to the subclaims.

The capillary viscometer according to the invention allows the viscosity of a material to be examined in a wide range of shear stresses and speeds (with a ratio of maximum to minimum value of the shear stress equal to 10 ² and with a ratio of maximum to minimum value of the shear speed equal to 10 ⁵ ) without additional arithmetic Calculations in the form of a flow curve with a given logarithmic representation in the direction of the ordinate and abscissa.

These ratios of maximum to minimum value relate to a capillary viscometer with a and same capillary. It goes without saying that when changing the capillary the limits of the ratio of Maximum to minimum value of shear stress (and shear speed) can be significantly higher can.

In contrast, only one device for measuring the melt index of plastics has become known so far (See. DE-OS 17 73 754), so to determine those bulk materials that are below the in 10 min Effect of a specified force can be extruded through a standardized nozzle. The known device has a constructed in the manner of a flow cup device, in which a in a cylindrical bore a Housing vertically guidable and with a weight resilient stamp the material sample under certain Temperatures and pressure conditions towards one at the bottom of the cylindrical bore located nozzle can press, whereby the stamp with an optical or magnetic grid for reversing

Conversion of the stamp path into an electrical pulse train is connected and the grid is directly connected to a pulse pick-up for passing on the pulses to a counter with a digital display, in detail
the optical grid is a perforated disk which is connected to the punch in such a way that the linear movement of the punch sets the perforated disk in rotation, and immediately outside the perforated disk a photocell is arranged on the counter to generate a pulse proportional to the rotational speed of the perforated disk, and

The magnetic grid is a disc magnetized differently on its edge, which is connected to the stamp in such a way that the linear stamp movement sets the magnetized disc in rotation, and directly on the outer edge of the disc, a magnetic pickup head generates a pulse proportional to the speed of rotation of the disc the counter is arranged, and
the punch and the perforated disk or the magnetized disk are connected to one another by a wire stretched over a pulley and another pulley arranged coaxially to the perforated disk or the magnetized disk, which wire is loaded at its free end by a further weight .

Even with this known device for measuring the melt index in plastics, η cht the Viscosity determined in the form of a flow curve, i.e. as a relationship between shear stresses and speeds will.

The invention is described below with reference to an exemplary embodiment shown in more detail in the drawing explained. Show it:

F i g. 1 shows a longitudinal section through the viscometer and the sensor for discrete displacements of the piston an embodiment of the capillary viscometer according to the invention,

2 shows the electrical functional diagram of a converter for the output signal of the sensor,

Fig. 3 shows section A in Fig. 1 on an enlarged scale and

F i g. 4 a flow curve obtained by means of the capillary viscometer.

The capillary viscometer contains a chamber 1 (Fig. 1) with a material to be examined 2, the is to be displaced by a calibrated cylindrical capillary 3 of the chamber I by means of a piston 5, and although under the action of a previously compressed spring 4, which is attached to a rod 6 of the piston 5 is attached.

The viscometer also contains a sensor 7 kinematically coupled to the rod 6 for discrete displacements of the piston 5 and a converter 8 (FIG. 2) electrically coupled to the sensor 7 Output signals of the sensor 7 in a decadic logarithm of the speed of movement of the piston 5 (Fig. 1) and the decadic logarithm of the pressure generated by the spring 4 is proportional electrical voltage.

A grid sensor can be used as the sensor 7 for discrete displacements of the piston 5. This has two transparent plates 9 and 10 with a grid of lines 11 (FIG. 3) evenly applied to them, one plate 10 (FIG. 1) because of the kinematic coupling with the rod 6 of the piston 5 movable, but the other plate 9 is immobile.

The pushbutton sensor also includes a lighting device 12 in the form of an incandescent lamp, from which a light beam falls on the plate 9 (in the direction of the arrow B) , passes through it and the plate 10 and (in the direction of the arrow Q) hits a light receiver 13.

The raster sensor is used as the sensor 7 for discrete displacements of the piston 5 to a high Measurement accuracy for the thrust speed and stress with a short length of the chamber 1 to obtain. The short length of the Kamnvr I allows one minimum amount of the material to be examined 2 for the implementation of its examination.

In the presence of larger amounts of the material to be examined can be used as a feeler for discrete Displacements, for example, an inductive sensor with a movable groove anchor and a toothed one Pole shoe are used.

To compress the spring 4, there is a lifting mechanism in the viscometer, which consists of a screw 14 which is arranged in the threaded part of a flywheel 15 which is freely rotatably built in the housing 16. The screw 14 has a pincer gripper 17 with a cylinder 18 which is kinematically connected to a release mechanism 19 and an upper plate 20 on which the upper end of the spring 4 rests. The pincer gripper 17 engages around the upper end of the rod 6, which has a lower plate 21 on which the lower end of the spring 4 rests and to which the movable plate 10 is attached

The converter 8 (Fig. 2) of the output signals of the sensor 7 (Fig. 1} for discrete shifts in a decadic logarithm of the speed of movement of the piston 5 and the value of the decadic logarithm of a pressure generated by the spring 4 contains a voltage proportional to the Light receiver 13 of the sensor 7 for discrete shifts connected digital knife 22 (Fig. 2) for the speed of movement of the piston 5 (Fig. 1) and one to the outputs of the knife 22 (Fig. 2) and to the K indicating the κ coordinate Input of a recorder 24 for recording the thrust speed connected converter 23 (Fig. 2) of the code received in the digital knife 22 into a voltage proportional to the decadic logarithm of the speed of movement of the piston 5. The recorder 24 is designed as a two-coordinate recorder Output signals of the sensor 7 (Fi g. I) for discrete displacements also contains one to the Li Receiver 13 of the sensor 7 for discrete shifts connected counter 25 (Fig. 2) for the amount of displacement of the piston 5 (FIG. 1) and a converter 26 of the connected to the outputs of the counter 25 (FIG. 2) and to the A "input of the recording device 24 for recording the shear stress indicating the x-coordinate The codes obtained in the counter 25 are converted into a voltage proportional to the decadic logarithm of a pressure generated by the spring 4 (FIG. 1) (FIG. 4), the values of the shear stress τ (dyn / cm ^; ) being plotted on the abscissa axis and the values of the shear speed D (s ') being plotted in a logarithmic representation on the ordinate axis.

The digital knife 22 (Fig. 2) for the speed of movement of the piston 5 (Fig. 1) contains a switch 29 (Fig. 2), one input of which is connected to the

Light receiver 13, the other input of which is connected to one of the reference pulse generators 30k, 30 /, 30m, 30n, 30p connected to the input of the switch 29 with the aid of a step switch 31. The number of reference pulse generators is determined by the number of sub-areas for the speed measurement into which the entire measuring range of the viscometer according to the invention is subdivided. In the exemplary embodiment described, the entire measuring range is divided into five sub-areas. | ₀

The output of the switch 29 is electrically coupled to the input of the counter 32, from which the Outputs of each point are in turn connected to a memory 33.

The digital speedometer 22 also includes circuitry for evaluating the count of the Counter 32 (a number forming in the counter 32) after the minimum 34 and maximum 35, the Represent AND gates with a number of inputs which is equal to the number of digits of the counter 32, and flip-flops 36 and 37, the inputs of the two circuits to all positions of the counter 32 according to the code values for the beginning (AND element 34) and the end (AND element 35) each Measurement sub-range and their outputs are connected to the flip-flops 36 and 37. The exits the flip-flops 36 and 37 are connected to four inputs of a control decoder 38, the fifth of which The input is coupled to the output of the light receiver 13.

The control decoder 38 has four outputs, two of which to the step switch 31, the third to the Memory 33 and the fourth to the counter 32 and the flip-flops 36 and 37 are connected.

The converter 23 of the digital speedometer 22 codes obtained into a decadic logarithm of the speed of movement of the piston 5 (Fig. 1) contains a voltage proportional to the memory 33 of the digital speedometer 22 connected digital-to-analog converter 39 (FIG. 2) for the mantissa of the logarithm, one to the Converter 39 connected (logarithmic) function converter 40 and an adder 41, one of which Input to function converter 40 and its second input to a digital-to-analog converter 42 for the code number of the logarithm is connected. The digital-to-analog converter 42 for the code number is connected to the step switch 31 of the digital speedometer 22.

The number of connection channels between the digital-to-analog converter 39 for the mantissa and the memory 33 of the digital speedometer 22 and between the digital-to-analog converter 42 for the code number and the step switch 31 is determined in the first case by the number of digits in the counter 32 ( in the relevant case eight), in which each point is coupled via the memory 33 to the respective input of the digital-to-analog converter 39, and in the second case by the number of positions of the step switch 31, which is based on the number of sub-areas (five ) the operation of the digital speedometer 22 is determined.

The output of the adder 41 is connected to the Y input of the recorder 24.

The converter 26 of the code received in the counter 25 into a voltage proportional to the decadic logarithm of the pressure generated by the spring 4 (FIG. 1) contains a digital-to-analog converter 43 (FIG. 2) connected to the outputs of the counter 25 and a (logarithmic) function converter 44 connected to the output of the digital-to-analog converter 43. The number of connection channels between the counter 25 and the converter 43 corresponds to the number of digits in the counter 25 (eight in this case).

The output of the function converter 44 is connected to the -Y input of the recording device 24.

The method of operation of the capillary viscometer according to the invention consists in the following:

Before starting the measurements, the spring 4 is set by rotating the flywheel 15 (FIG. 1) of the lifting mechanism pressed together until the pincer gripper 17 grips the upper end of the rod 6. With the help of the trigger mechanism 19 the gripper 7 is secured by lowering the cylinder 18. After that, the rod 6 lifted by turning the flywheel 15 in the upper position and the one to be examined Material 2 filled chamber 1 with capillary 3 is set.

At the beginning of the measurements, the gripper 17 is pulled up with the aid of the release mechanism 19 of the cylinder 18 is opened, whereby the spring 4 is released. The ones in the compressed state The spring 4 located relaxes and pushes the piston 5 via the rod 6, which is charged with the test material 2 from the chamber 1 through the capillary 3 squeezes. To the extent that the spring 4 relaxed, take the pressure drop in the capillary 3 through which the material 2 to be examined flows, and accordingly its run-out speed and consequently also the speed of movement of the piston 5 from. The measured values of the shear stress and speed are determined by the size of the path the spring 4 with respect to its compressed initial state or that of the speed of movement of the piston 5 is determined.

To determine these variables, the sensor 7 for discrete displacements is coupled to the piston 5. When the piston 5 is displaced, the movable plate 10 of the sensor 7, which is rigidly coupled to the rod 6, moves together with it. Since the movable plate 10 moves in a direction perpendicular to the lines of the grid 11 (FIG. 3), the from the lighting device 12 (Fig. 1) through the immovable plate 9 and the movable plate 10 on the light receiver 13 of the sensor 7 is modulated periodically incident luminous flux. As a result, a periodic voltage arises in the light receiver 13, which is converted into a sequence of pulses due to a current limitation in the light receiver 13, the duration of which is determined by the reciprocal value of the movement speed of the piston 5 and the width of the lines of the grid 11 (Fig. 3) and their number by the Verschiebungsgrö SSE of the piston 5 (Fig. 1), measured from dei initial position, that is, by the way of the spring 4 unc the step of strokes of the grid 11 (F i g. 3) is limited hours. These pulses arrive at the input de: switch 29 (Fig. 2), where a signal from one of the reference pulse generators 30Jt, 30 /, 30m, 30n, 30p also arrives via the step switch 31 Pulse bundle from, the duration of which is determined by a pulse coming from the light receiver 13 and its repetition frequencies: the pulses in the bundle due to the signal frequency of the connected reference pulse generator 3OA, 30 /, 3OiT 3On. 30p is determined. The reciprocal of the speed of movement of the piston 5 (FIG. 1

determining number of pulses is counted by the counter 32 (Fig. 2). After the impulse from Light receiver 13 is the code from the counter 32 with the help of one of the through the trailing edge of this Pulse controlled decoder 38 at the memory 33 transmitted incoming signal to the memory 33.

The code stored in the memory 33 is used for the mantissa with the aid of the digital-to-analog converter 39 into a voltage proportional to the code and then, with the aid of the function converter 40, into one of the mantissa des decadic logarithm of the reciprocal value of the speed of movement of the piston 5 (Fig. 1) proportional voltage transformed.

For the transition from one measuring sub-range to the other, evaluation circuits 34 and 35 for evaluating the counter reading of counter 32 (one in counter 32 If during a serial count towards the end of the measuring interval (the duration of a pulse coming from the light receiver 13) a pulse number N arrives in the counter 32 which corresponds to the value of the code character Nmin set in the circuit 34 for an evaluation exceeds, but falls below the value of the code character N _max set in the evaluation circuit 35, at the moment of selection / V _m , “the circuit 34 responds for an evaluation and flips the flip-flop 36 over, while the evaluation circuit 35 remains in its initial state testifies to the correspondence of the measurement sub-range with the value of the speed to be measured, in this case After the end of the measurement interval, the decoder 38 sends a signal to transfer the code received in the counter 32 into the memory 33.

If, however, the number of pulses arriving in the counter 32 is less than / V _1711n or greater than N _max , then the flip-flops 36 and 37 either do not tip over or at least tip over. Then, after the end of the measuring interval, the decoder 38 delivers a signal to the step switch 31, which connects to the switch 29 one of the reference pulse generators 30it, 30 /, 30m, 30n, 30p with a higher or lower pulse repetition frequency. Such a switchover of the generators lasts until the repetition frequency of the reference pulses corresponds to the measuring range for the speed of movement of the piston 5 (FIG. 1).

After each measurement, the decoder 38 (FIG. 2) to the counter 32 and the flip-flops 36 and 37 given a signal that the counter 32 and the flip-flops 36 and 37 resets to the initial state.

With regard to the change in the measurement sub-range when registering the flow curve 28 (Fig. 4) is from the step switch 31 (Fig. 2) to the digital-to-analog converter 42 for the code number of the code converter 23 given a signal in the form of a position code, which is converted into one of the code digits of the logarithm of the The reciprocal of the speed of movement of the piston 5 (FIG. 1) is transformed into a proportional voltage will. The in the digital-to-analog converter 42 (Fig. 2) obtained, the code number of the logarithm of the reciprocal of the speed of movement of the piston 5 (Fig. 1) proportional voltage and the generated by the function converter 40, the mantissa proportional Voltages are summed up in adder 41. The summed voltage comes from adder 41 to the V input of the recorder 24 for recording the logarithm of the reciprocal value of the speed of movement of the piston 5 (Fig. I).

The pulse signal from the output of the light receiver 13 (F i g. 2) also passes to the counter 25 where in the _s degree, as the pulses arrive, a current code value for the amount of displacement of the piston 5 (Fig. 1) is formed. With the help of the code converter 26 (Fig. 2), this instantaneous value is converted into a voltage proportional to the decadic logarithm for the amount of displacement of the piston 5 (Fig. 1) (the path length of the spring 4 in relation to its compressed initial state), for which the code converter 26 (Fig 2) Includes the digital to analog converter 43 which converts the code into it

, ₅ converts proportional voltage, which is converted with the aid of the (logarithmic) function converter 44 into a voltage which is already proportional to the decadic logarithm of the displacement of the piston 5 (FIG. 1).

The voltage from the output of the transducer 44 ( Fig. 2) goes to the X input of the recorder 24 for recording the value of the logarithm of the travel of the spring 4 (Fig. 1) with respect to its initial position, ie the value of the logarithm of a decade

J ₅ Change in pressure compared to its maximum initial value.

It should be emphasized that the pressure generated by the spring 4 varies from the maximum to the minimum value while the digital speedometer 22 (FIG. 2) changes the reciprocal of the speed of movement of the piston 5 (Fig. 1) measures, which is why the recorder 24 (Fig. 2) to record the Signals from the two code converters 23 and 26 is switched in the reverse direction, d. h, the (not The pen (shown) should be on the coordinate paper 27 (FIG. 4) from top to bottom and from right to bottom moved to the left.

With the used capillary 3 (Fig. 1) and the chamber 4, the values of the decadic The logarithm of the pressure of the spring 4 and the logarithm of the decade of the speed of movement of the piston 5 into the decadic logarithm of the shear stress and the decadic logarithm the thrust speed is converted Recording device 24 (FIG. 2) resulting record when it is linked to the diameter of the chamber 1 and the capillary 3 (FIG. 1) represent a flow curve 28 (FIG. 4) of the material 2 to be examined (FIG. 1).

The capillary viscometer is used for measurement and automatic double logarithmic registration of the viscosity of elastomers, melts and concentrated solutions polymeric and dispersed Systems of specified flow curves provided.

The measurements are carried out under isothermal conditions at a given temperature

Main technical parameters:

1. Effective viscosity: 150-510 * P.
2. Shear stress: 5 · MPS ■ Wdyn / cm ² at T _n J Tn, in = MP.

3. Pushing speed D = I- 10 ~ ² -5 · 10 ⁴ s-> at D _m JD _min = 10 ^s .

4. Temperature range in the chamber: -50 to +250 ⁰ C.

5. Major flaws in the

a) Shear stress Ax = ± 0.015-0.002,
b) speed of thrust

OD = ± 0.035-0.02 · D _max .

6. Amount of material required to load the chamber: 7.5 cm ³ .

7. Representation: logarithmic on both coordinate axes.

8. Mass of the device: 120 kg.

9. Stand area: 830 χ 470 mm ² .

For this purpose 3 sheets of drawings

Claims (3)

Patent claims: 1. Capillary viscometer, in which the force of a previously compressed spring is transmitted to a piston displacing a material to be examined through a capillary, the displacement of which is recorded by means of a recording device, characterized by a sensor (7) for discrete displacements of the piston (5), which is kinematically coupled to the piston, and by a converter (8) electrically coupled to the sensor (7) of the output signals of the sensor (7) for discrete shifts in a decadic logarithm of the movement speed, ₅ speed of the piston (5) and the voltage (F i 3. 1) proportional to the value of the logarithm of the pressure generated by the spring (4). 2. Viscometer according to claim Ϊ, characterized in that the sensor (7) for discrete Displacements is a grid sensor (Fig. 3). 3. Viscometer according to claim 1 or 2, characterized in that the converter (8) (Fig. 2): a digital knife (22) connected to the sensor (7) for discrete displacements for the speed of movement of the piston (5) and
a converter (23), connected to the outputs of the knife (22) and to the V input of a recording device (24) for recording the thrust speed, of a code received in the digital knife (22) into a decadic logarithm of the speed of movement of the piston (5 ) proportional voltage as well
a counter (25) connected to the sensor (7) for discrete displacements for the displacement size of the piston (5) and one to the outputs of the counter (25) and to the X input of the recorder (24) for the recording the shear stress converter (26) of a code received in the counter (25) into a voltage proportional to the logarithm of the pressure generated by the spring (4), in order to record a flow curve (28) on a coordinate paper (27) of the recording device (24) (Fig. 4).