RU188620U1 - DEVICE FOR MEASUREMENT OF VISCOELASTIC PARAMETERS OF LIQUID CRYSTALS BY THE RHEOLOGICAL METHOD - Google Patents

Abstract

The invention relates to a device for measuring viscoelastic parameters of liquid crystals (LC). A device for measuring viscoelastic parameters of liquid crystals by a rheological method contains a motorized table, the platform of which is designed to fix a controlled sample — a liquid crystal capillary; driving the platform of the motorized table, and a laser distance sensor measuring the movement of the platforms The motorized table corresponds to the movement of the meniscus of the liquid crystal in the capillary, with the specified laser distance sensor configured to transmit a signal to the said microcontroller. The technical result is to improve the measurement accuracy and simplify the processing of the obtained images. 2 Il.

Description

The invention relates to devices for measuring viscoelastic parameters (shear viscosity and surface tension coefficient) of liquid crystals (LC) and can be used in scientific studies of the physicochemical properties of LCs that characterize the performance characteristics of LCD displays and photonics devices.

In the prior art [Mohammad Heshmati et al. Experimental investigation of the contact angle of the tube and the circular cross sections / Langmuir, 2014, V. 30, pp. 14151-14162] known method for determining the rheological parameters of isotropic liquids by creating and studying the shear damped Poiseuille flow, implemented when the fluid flows into a vertically oriented capillary. While the maximum height of the liquid (l ₀ ) with a known value of the contact angle θ and the surface tension coefficient σ, is determined by the relations:

- для цилиндрического капилляра,

- for a cylindrical capillary,

- для плоского капилляра,

- for a flat capillary,

высоты подъема мениска с последующей аппроксимацией нелинейной функцией, которую для плоского капилляра можно записать в видеwhere r (h) is the radius of the cylindrical capillary (flat capillary gap), ρ is the density of the fluid and g is the acceleration of free fall. The value of the coefficient of shear viscosity can be obtained by measuring the instantaneous values

meniscus lift heights followed by approximation by a nonlinear function, which for a flat capillary can be written as

where is the characteristic time:

directly proportional to the coefficient of shear viscosity η.

In the experimental implementation of this method, the manual movement of the camera that records the movement of the meniscus was used, which is necessary to improve the measurement accuracy. Further information was obtained by post-processing of instant digital images of meniscuses. This method of measurement requires improved positioning accuracy of the camera, improved camera performance at the same time with high resolution, since the movement of fluid in the capillary can be quite fast and the photos will be fuzzy. When registering video frames, they need to be synchronized, otherwise the movement of the LCD meniscus in the capillary will be determined with low accuracy. This is due to the fact that the camera does not always register frames with the same time interval, and when using special cameras with external synchronization leads to a significant increase in the cost of the system as a whole. Also, this approach imposes a number of requirements on the quality of personnel processing.

The proposed utility model allows to solve problems associated with low measurement accuracy and complex processing of the resulting images.

Thus, the technical result is to improve the accuracy of measurements and simplify the processing of the resulting images.

The technical result is achieved in that the device for measuring the viscoelastic parameters of liquid crystals by the rheological method contains a motorized table, the platform of which is designed to fix a controlled sample - a liquid crystal capillary, an optocoupler installed to transmit a signal to the microcontroller, which is adapted to transmit the processed signal to a computer, a stepper motor driver that drives a motorized table platform, and a laser sensor p distance, measuring the movement of the platform of the motorized table, corresponding to the movement of the meniscus of the liquid crystal in the capillary, with the specified laser distance sensor configured to transmit a signal to the said microcontroller.

The achievement of the technical result is based on the use of a motorized table, the movement of the platform which is provided in a given plane (vertical or horizontal), the driver of a stepping motor operating in microstep mode and ensuring the division of 1 step (1.8 °) by 16, a laser distance sensor for measuring displacement the platform of the motorized table on which the sample is fixed (a capillary with a liquid crystal). The signals received from the optocoupler and laser distance sensor are processed on the microcontroller, the received information can be transmitted to the computer or displayed on the indicator.

The combination of these elements will allow to obtain the desired technical result and are essential features of the utility model.

The utility model is illustrated by the block diagram of the device (Fig. 1).

FIG. 1 shows a block diagram of a utility model. On the platform of the motorized table 4, controlled by the driver of the stepping motor 5, a sample 2 is fixed, which represents a flat capillary with two open ends. The movement of the platform of the motorized table begins at the moment of time corresponding to the partial overlapping of the laser radiation 1 by the liquid crystal, which leads to a change in the intensity of the laser radiation detected by the photodiode 1 '. The amount of movement can be recorded using a micrometer screw to which the shaft of the stepping motor is attached, or in automatic mode with a laser distance sensor 3, the accuracy of which can reach 0.01 mm.

To increase the change in the intensity of laser radiation 1 caused by the overlapping of the laser beam with a liquid crystal, mutually crossed polaroids 7 are fixed at the output aperture of the laser and the input aperture of the photodiode 7. The photodiode operates in the photodiode mode, the signal from its output is amplified by the standard amplifier non-inverting amplifier. The amplified signal is fed to an analog-to-digital converter (ADC) embedded in the microcontroller (MC) 6, according to the conversion results, a decision is made to shift sample 2. The conversion frequency of the ADC is 100 kHz, while digital filtering is performed using a median filter. Stepper motor can be controlled by using a standard stepper motor driver, or by using a stepper motor driver implemented in a bridge circuit using transistors.

To increase the measurement accuracy, the initial positioning function of the sample is implemented. When the start button is pressed, such a boundary position of the motorized table 4 platform is selected, at which the minimum possible displacement leads either to complete overlap of the laser radiation (offset from the sample) or to full enlightenment (shift towards the sample). The width of the laser spot is controlled by the aperture 8, which allows you to change the sensitivity of the system.

The measurement of the offset of the platform of the motorized table 4 is carried out using a laser distance sensor 3 operating in the range up to 50 mm and usually the measurement error does not exceed 2% of the range. The signal from this sensor can be digital or analog. In the case of an analog signal, it is fed to the input of the ADC MK 6 (through an amplifier, if necessary), in the case of a digital signal - to the digital input of the microcontroller 6. The signal frequency is 4 times higher than the shaft speed of the stepper motor. Such a conversion frequency corresponds to the full restoration of the platform movement profile. The offset measurements start in advance before the offset of the platform of the motorized table 4, which allows you to register the starting position and accurately record the moment when the platform of the motorized table begins to move.

показаны на фиг. 2. При этом использовался плоский капилляр с зазором h, закрепленный на платформе горизонтального столика. В этом случае, соотношение (3) упрощается, и величина перемещения

описывается выражением:The efficiency of the device was tested on a model and showed its suitability for measuring the rheological parameters of liquid crystals. The results of measurements of the movement of the platform of the motorized table L, equal to the movement of the meniscus

shown in FIG. 2. A flat capillary with a gap h, mounted on the platform of the horizontal table, was used. In this case, relation (3) is simplified, and the magnitude of the displacement

described by the expression:

The nematic liquid crystal pentyl-cyanobiphenyl (5CB) with previously measured material parameters was used as the control object of the study [Stewart IW The Static and Dynamic Continuum Theory of Liquid Crystals. London: Tayor & Francis, 2004, 351 p.]. The measurements were carried out at room temperature T = 23 ° C. The solid line in FIG. 2 shows the theoretical dependence (5), which approximates the experimental data well. The calculated value of the coefficient of shear viscosity η = 0.025 Pa⋅s correlates well with the minimum value η _min = 0.023 Pa⋅s [Belyaev V.V. Viscosity of nematic liquid crystals. Moscow. FIZMATLIT, 2002, 224 pp.] At a similar temperature, which is explained by the phenomenon of the director orientation of the liquid crystal in the direction of flow. Thus, the efficiency of the device is demonstrated when measuring the shear viscosity of liquid crystals.

The device was implemented on a Stm32f051r8t6 microcontroller with a clock frequency of 48 MHz and an ATC clock frequency of 14 MHz. In the microcontroller, a stepper motor driver control module, an ADC measurement module and a computer data processing and transmission module (or indicator) were implemented. A standard TB6560 chip was used as a driver for a stepper motor, in which the corresponding control mode is implemented - microstepping mode with dividing the step by 16. ADC for converting the signal from a photodiode with a conversion frequency of 100 kHz. When the signal threshold (setpoint) is exceeded, the platform of the motorized table moves. In this case, the initial position and the time of the beginning of the movement of this platform are recorded in memory. The movement of the platform is carried out until the signal level falls below the setpoint. To ensure a smoother movement and continuity of movement of this platform, it is possible to use a PID speed controller. Using this method of controlling the movement of the platform will allow you to get a more smooth its displacement, and also will ensure the continuity of its movement. The distance sensor was an Optex CD33-50NV / PV with an analog interface and an output voltage range from 0 to 10 V. A passive attenuator on resistors is used to match the levels with the microcontroller, the resistance matching is performed using a voltage follower on the operational amplifier.

Claims (1)

A device for measuring viscoelastic parameters of liquid crystals by a rheological method, containing a motorized table, the platform of which is designed to fix a controlled sample — a liquid crystal capillary; an optocoupler installed to transmit a signal to a microcontroller, which is adapted to transfer the processed signal to a computer, stepper driver motor driving the motorized platform platform and laser distance sensor measuring movement of the platform rmy motorized stage corresponding to movement of the meniscus of the liquid crystal in the capillary tube, wherein said laser distance sensor configured to transmit a signal to said microcontroller.

Images