SU1742676A1 - Vibration viscosimeter - Google Patents

Abstract

The invention relates to a device for measuring the viscosity of a liquid by a vibration method and allows to simplify the design of a viscometer and improve the measurement accuracy by eliminating non-linearity. The viscometer consists of an excitation converter in the form of a coil 1 with a winding 2 connected to JI -H 18 15 14 P 13 sources 3 and 4 of alternating and constant electric signals, registering the converter in the form of a hollow cylindrical permanent magnet 5 concentrically enveloped by the measuring winding 6 with an alternating electric current indicator 7 connected to its circuit, a closed tank 8 with a viscous liquid 9 under investigation, and also a sensitive element in the form of a ferromagnetic servo freely placed in the tank 10. The method of adjusting the viscometer consists in choosing a predetermined polarity of the constant electric signal source and amplitude exceeding the amplitude of the alternating electrical signal, analytically determining the zone of constant pulling force of the coil 1 and the linear increase area of the pulling force of magnet 5, after which axial displacement of the coil 1 and magnet 5 using the special mechanism of axial movement introduces the ends of the core 10 into the indicated zones 2 sec. f-ly, 3 ill. CL VI of VI FIG. 1 H 15181617

Description

The invention relates to a measurement technique, in particular, to devices for measuring the viscosity of liquids, and can be used in the chemical, petrochemical, engineering and other industries.

The purpose of the invention is to simplify the design and develop a method for adjusting a given viscometer.

Fig, 1 schematically shows the proposed vibration viscometer with a transverse central section; FIG. 2 is a section A-A in FIG. FIG. 3 shows the calculated dependence of the change in the thrust force of the solenoid (constant magnet) when the core is displaced, indicating the zones of constant and linearly increasing thrust force.

Vibration viscometer contains excitatory electromechanical transducer, made in the form of cylindrical coil 1 with winding 2, connected to source 3 of variable electric signal with adjustable frequency and source 4 of constant electric signal with adjustable amplitude, registering electromechanical converter made in the form of installed coaxially with coil 1 hollow cylindrical permanent magnet 5, axially magnetized and concentrically covered measuring winding 6 with an alternating current indicator 7 incorporated in its circuit, graduated in units of viscosity, a closed cylindrical tank 8 with a viscous liquid 9 under test, made transparent and installed in the axial holes of the coil 1 and the permanent magnet 5 with a tight fit in the hole the coil 1 and a sliding fit in the hole of the magnet 5, as well as a sensing element, freely located in the tank 8 and made in the form of a ferromagnetic cylindrical core 10, the end parts of which with about By sowing, ring dimensional risks 11 with digitization are placed in the axial holes of the coil 1 and the permanent magnet 5. In this case, the coil 1 and the permanent magnet 5 are equipped with independent axial movement mechanisms, made in the form of a stand 12 with a cylindrical recess 13 for moving the coil 1 and the magnet 5, the longitudinal guide grooves 14 in the stand 12 for moving the latches 15 fixed on the ends of the coil 1 and the permanent magnet 5, and the adjusting screws 16 freely mounted with limited axial movement in rikreplennyh to the stand 12 and the racks 17 screwed into the retainers 15 attached to the sleeve 18.

The adjustment of the vibration viscometer is carried out as follows.

Pre-select the polarity of the constant electric signal fed from the source 4 of the signal to the winding 2 such that the opposite polarity of the ferromagnetic core 10 and the permanent magnet 5 adjacent to one another is ensured. Such polarity ensures that the core 10 is pulled in in coil 1, the action on the opposite end of the core 10 of the restoring force from the permanent magnet 5, which

due to the diversity of poles facing each other. The amplitude of the constant electric signal from source 4 is chosen greater than the amplitude of the variable signal fed to the same winding 2 from source 3 of the variable signal with an adjustable frequency. This excess allows simultaneously with the excitation of the forced oscillations of the core 10 by a variable signal all the time to keep

the selected polarity of magnetization of the core 10 with respect to the permanent magnet 5 and thereby maintain the action on the core 10 of the restoring force from the magnet 5 during the whole work. Further, having the calculated dependences of the variation of the tractive effort F of the solenoid 1 and 2 and constant the magnet 5 at the displacement of the core 10, the nature of which is fundamentally similar and shown in FIG. 3, analytically determine the zone of constant pulling force F of the coil 1 with the core 10 (zone CB in FIG. 3) and the linear increase in pulling force of the permanent magnet 5 with the core 10 by moving

of the core, measured from the end of the magnet 5 that is remote from the coil 2 (the end face 00 in FIG. 3, and the area OA in the same FIG. 3). Next, the corresponding ends of the core 10 are introduced into the above zones, namely the left

FIG. 1, the end of the core 10 is introduced into the zone CB of the constant pulling force of the solenoid.

1 and 2, and the right end in Fig. 1 of the core 10 is introduced into the OA zone of the linearly increasing pulling force of the magnet 5. Change in position of the core 10 relative to the coil

2 and magnet 5 are produced by independent and consistent adjustment of three parameters. Firstly, by changing the amplitude of the constant signal of the source 4 supplied to the winding 2, at which

because the traction force of the solenoid is proportional to the square of the current, and the restoring force from the magnet 5 to the magnitude of the magnetization of the core 10 with a naturally constant magnetization of the magnet 5, and therefore the first degree of direct current, the core 10 will shift relative to the coil 1 and magnet 5 to a new equilibrium position. Secondly, by shifting the adjusting screw 16 of the coil 1 relative to the stand 12 along the cylindrical recess 13 together with the reservoir 8 fixed in the coil 1. Thirdly, a similar displacement of the permanent magnet 5 relative to the stand 12 and the reservoir 8 freely entering the axial hole magnet 5. In this case, the insertion of the core 10 into the indicated zones is judged by the depth of insertion of its ends into the axial holes of the coil 1 and the magnet 5, and the insertion depth is fixed by the location of the A frame relative to the end surfaces of coil 1 and magnet 5. By analyzing (see below), the required amount of displacement of the right end of the core to hit it, for example, in the middle of the OA zone, where x is measured from the right end of the magnet 5, as well as the length I of the magnet 5, it is not difficult to calculate how much of the process 11 it is necessary to insert the right end of the core 5 into the axial hole to get into this zone. Similarly, in order to insert the left end of the core 10 into the center of the CB zone when counting x from the end of coil 1 left in FIG. 1, you must insert the end of the core into the axial opening of coil 1 with coil length I by an easily calculated number of divisions 11. The tank 8 is made transparent, and this nature of fixing the depth of insertion of the core 10 is naturally only possible for studying the viscosity of transparent liquids. If the fluid is opaque, which is much less common (full transparency is not needed here), the insertion of the end of the core 10 into a given zone can be judged by connecting alternating current meters to the windings 2 and 6. When introduced into the coils, the core changes, their inductive resistance, and the resistance value makes it easy to judge the core insertion depth inside the jacks, the sufficient insertion depth is given by the corresponding marks on the resistance meter, preset for these electromechanical parameters of the coil, magnet and core.

The operation of the vibration viscometer is as follows (after its adjustment).

A coil 1 from source 3 is supplied with a variable electrical signal to the winding 2, and its amplitude is chosen to be less than the amplitude of the constant signal from source 4 exposed during the adjustment process. Since the core 10 with this feed

variable signal from the side of the coil 1 acts variable tgovy force (magnetizing signal of the coil 1 - harmonic offset from zero by the amount of a constant signal), and from the magnet side

5 - restoring force, then the core 10 begins to perform forced oscillations in the tank 8 with the liquid under test 9 with the frequency of the alternating electrical signal. When you change the position

the core 10 relative to the magnet 5 with the coil 6, the magnetic flux of the magnet 5 penetrates the coil turns, while in the winding 6 an emf is induced proportional to the speed of movement of the core 10, the value of which is fixed by the alternating current indicator connected to the winding 6. Smoothly changing the frequency of the alternating electric signal of the source 3 and while watching

The indications of the indicator 7 at the maximum of the signal are tuned to the resonance of the elastic system — a ferromagnetic core 10, elastically fixed between the coil 1 and the magnet 5, while the electromagnetic forces perform the function of the elastic forces. In the case of large viscous liquids, the viscosity is determined at the fixed resonant frequency of the sensitive element, using the known dependences of the coefficient of viscosity of the medium on the natural frequency for a linear oscillatory system, since the variation of the natural frequencies with viscosity at large The frequencies are quite significant and allow to obtain the required measurement accuracy. In the case of measuring small viscosities, the oscillation amplitude of the sensitive element (core 10) is measured using indicator 7, calibrated in viscosity units (in this case, the amplitude of the alternating electrical signal is set to the set value at which the scale of the indicator 7 was calibrated).

In the case of large viscosities, a relationship known for linear oscillatory systems is used (i.e. where ah is known in advance for the sensitive element of the viscometer, the intrinsic frequency in the absence of the test liquid; (From the frequency at which the oscillation maximum is fixed; / 3 - relative damping coefficient

y3 b / () b / f2ViT7c7 2

Where b is the coefficient of viscous resistance; m is the mass of the sensitive element; c is the rigidity in the longitudinal direction.

In the case of small viscosities, the dependence of the dynamic coefficient at resonance vm on the relative damping coefficient is also known for determining viscosity for linear oscillatory systems.

Vm

By knowing the value of the indication of the indicator 7 with the resonant deviation of the sensitive element, the scale of the indicator 7 is calibrated directly in units of viscosity.

When the sensitive element 10 oscillates with respect to the reservoir 8 during the measurement, as well as when the amplitude of these oscillations changes, in the case of measurement in liquids with different viscosities, a change in the amplitude of oscillations does not affect the resonant frequency. This is explained both by the constant pull force of the solenoid 1 and 2 when the core 10 is displaced in the CB zone (Fig. 3), and by the linear increase in the restoring force of the permanent magnet 5 when the core is displaced in the OA zone (Fig. C), which characteristic of linear oscillatory systems.

The calculated lengths of the constant and linear zones of the increasing tractive effort of the solenoid and the permanent magnet are sufficient so that with different parameters of the oscillatory modes of the sensitive element and different viscosities of the measured media, the sensitive element does not exceed the limits of these zones.

Claims (2)

Claim 1. Vibration viscometer containing excitation and recording electromechanical transducers, as well as a sensitive element freely located in a closed cylindrical tank with a viscous liquid under investigation, characterized in that, to simplify the design of the viscometer, the excitation transducer is designed as a cylindrical coil with a winding connected to variable frequency electric signal sources and a constant electric signal with adjustable Rui amplitude recording transducer is a set soos- but with the hollow cylindrical coil a permanent magnet magnetized axially and concentrically enveloped by the measuring winding with an alternating current indicator included in its circuit, the tank is made transparent and installed in the axial holes of the coil and the permanent magnet with a tight fit in one of the holes and sliding in the other hole, and the sensing element is designed in the form of a ferromagnetic cylindrical core, the end parts of which with annular dimensional risks deposited on them in the axial direction are placed in the axial bore and x coils and permanent magnet fitted with mechanisms for independent axial movement, 2. The method of adjusting the vibration viscometer, which consists in ensuring the independence of the frequency of the resonant oscillations of the sensitive element from the amplitude of its oscillations, characterized in that, in order to increase the measurement accuracy, the polarity of the constant electric signal of the source is chosen, providing the difference between the adjacent poles of the ferromagnetic core and the permanent magnet which are magnetised by this signal and amplitude exceeding the amplitude AC signal The zone of constant pulling force of a coil with a cylindrical core and the zone of linear increase of pulling force of a constant magnet as the core moves, measured by from the end of the magnet distant from the coil, and then by successively changing the amplitude of the constant electric signal of the source while maintaining the amplitude of the alternating signal and axial displacement of the coil and the permanent magnet introduce the corresponding ends of the core into the zones indicated above, and the depth of insertion of the core into the axial holes of the coil and the magnet is fixed along dimensional risks on the end parts of the core. WO 0.73 0.50 0.25 Fig. 3 FIG. 2