SU819627A1 - Vibration-type viscometer - Google Patents

Description

(54) VIBRATIONAL VISCOSIMETER

Claims (2)

The invention relates to the technique of measuring the viscosity of liquid media, and more specifically to industrial viscometers, and can be used in chemical, petrochemical; and other industries. According to the main author. St. No. 577431. An oscillating viscometer is known, which contains an exciting and measuring circuit and a measuring transducer, the sensitive element of which is located between a pair of recording transducers connected to the inputs of a control trigger. The sensing element of the measuring transducer is made in the form of a hollow cylinder, freely attached to the horizontal. axis is parallel to the bottom of the transmitter housing, with permanent magnets placed in it. The outputs of the flip-flop trigger are connected to the control inputs of a two-channel switching device, to whose down circuits the driving, inverters are connected, and an adjustable current regulator LlJ is connected between the input circuit of the switching device and the power source of the driving converters. The disadvantage of the known viscometer, which reduces the accuracy of its measurements, is the change in the magnetic permeability of the core of the exciting transducer and, consequently, the change in the magnitude of the exciting force with a change in the temperature of the controlled medium. The aim of the invention is to improve the measurement accuracy. This goal is achieved by the fact that the oscillating viscometer additionally contains permanent magnets placed parallel to the magnets of the sensitive element, and the pole tip of the core of the excitation coil of the device, placed coaxially with the sensitive element, has a wedge-shaped shape. 3 In FIG. 1 shows a functional diagram of the proposed viscometer; in fig. 2 - electromagnet of the exciting converter; in fig. 3 (a, b, c) the relative position of the wedge-shaped field ca of the magnetic circuit and the permanent magnetically mounted in the case of the measuring transducer and the magnetically sensitive element at its two extreme positions. The viscometer excitation circuit (Fig. 1) is an unstabilized power supply 1 connected to the excitation electromagnet 2, the winding of which is wound in a single wire on the magnetic core 3. The electromagnet 2 is housed in the housing 4. The power supply 1 is connected to the electromagnet excitation 2 through a switching device 5, which is an electronic k} 1uch. The switching device 5 is controlled by a control trigger 6, the inputs of which are connected to registering converters 7. The converters 7 are in one or another state depending on the relative position of the magnet 8 fixed on the flexible membrane 9 and the magnets 10 of the sensitive element 11 are parallel which are located magnets 12 One of the outputs of the control trigger is connected to the period-amplitude converter 13, which, in turn, is loaded onto the secondary recording device 14. The viscometer operates as follows. When the position of the sensing element 11 shown in FIG. 3, a, the first registering converter 7 is triggered, the trigger 6 is moved to the position in which the electronic key 5 is opened. As a result, the voltage of the power source 1 through this key is applied to the coil of the electromagnet 2. In this case, the wedge-shaped pole of the core 3 is magnetized as shown in FIG. Z.B. The rotational moment arising from the interaction of the magnetic fields of the core 3 and the magnets of the sensitive element 1O, significantly exceeds the torque of the permanent magnets 12. As a result, the sensitive element 11 begins to move, tending to assume the position shown in FIG. 3, c. In this position, the second registering converter 7 is activated, which disconnects the excitation voltage 7. Under the action of a magnetic field of a permanent magnet) in 12, the element 11 returns to its original position (Fig. 3, a), where the first control transducer is activated, and the process is repeated. The time interval during which the sensitive element 11 under the action of the field of permanent magnets 10 and 12 passes from one position 3, to another 3, and proportional to the value of viscosity, is converted into an analog signal by the converter 13 and fixed by a secondary self-searching device 14. Thanks that the movement of the sensing element 11 (from the position of Fig. 3, to the position of Fig. 3, a) occurs as a result of the interaction of the magnetic fields of permanent magnets 1O and 12, whose properties are stable over a wide temperature range e (to 300 C), eliminated the need to stabilize the current supply of the electromagnet and the effect of varying the magnetic permeability of the core that allows to simplify the design and improve the accuracy and reliability of the viscometer. The application of the proposed viscometer makes it possible to measure viscosity with high accuracy without the use of complex systems. The proposed viscometer can be used for laboratory express viscosity control and as an industrial viscometer for monitoring technological processes in the production of polymeric materials. The invention formula Oscillatory viscometer according to ed. St. No. 577431, characterized in that, in order to increase accuracy, it additionally contains permanent magnets placed parallel to the magnets of the sensitive element, and the pole tip of the core of the excitation coil placed coaxially with the sensitive element has a wedge shape. Sources of information taken into account during the examination 1. USSR author's certificate No. 577431, KG1. Q O1N 1.1 / 16, 1976 (prototype). j ten N f2-4l N N . liTs :: // ./ , / IS s f 9 7 4% g / v 2 arg njz.6 (Rig.d.