Automatic Liquid Level Research Articles

Empirical study of robust/developed PID control for nonlinear time-delayed dynamical system in discrete time domain

In addition to the high nonlinearity of liquid dynamics inside a tank, a study was conducted to overcome loading/unloading liquid storage tank control problems. In this study, the author developed a nonlinear control system to conquer both nonlinearity and the significant time delay arising from using a pressure-difference-based level sensor. To this end, this study proposes the implementation of nonlinear state dependent (SDP-PID+) control using the SDP transfer function model as a class of nonlinear descriptions of dynamical systems. By incorporating additional robust (plus) compensators alongside the traditional P-, I-, and D-compensators, the robust SDP-PID controller utilizes the complete state feedback to create a time-varying state variable feedback (SDP-SVF) control law. This approach effectively mitigates the effects of the discrete-time SDP-TF. It introduces the pole placement tuning approach, which renders significant performance using the laboratory test rig TPS8.2.2.4, for automatic liquid level control.

Research on Dynamic Liquid Level Detection Technology in Workover Operation

In this paper, an automatic liquid level monitoring device is designed, its working principle and technological process are described, and a workover dynamic liquid level testing scheme is established. In view of the factors affecting the sound velocity in the annular space of the oil jacket, the calculation formula and mathematical model of the sound velocity and the depth pressure temperature density are established. The sound velocity changes caused by the changes in temperature, pressure and the composition of the well gas are accurately corrected. It is confirmed that the modified model provides a method that can not only ensure accuracy but also greatly reduce the calculation amount, greatly simplifying the real-time calculation amount of the system. The obtained liquid level depth is approximate, but it is sufficiently accurate to meet the requirements of the technical indicators of the project.

"AN AUTOMATIC LIQUID LEVEL CONTROL SYSTEM WITH THE USE OF THE ARDUINO MICROCONTROLLER AND STRAIN GAUGES - ANALYSIS OF APPLICATION POSSIBILITY IN MANUFACTURING PROCESSES "

The aim of the work was to present the possibility of automatic regulation of the liquid level in the tank with the use of the Arduino platform, strain gauge measurements and pump operation regulation by means of a PID controller. The possibility to program the Arduino and implementing the algorithm of the PID controller was presented. To be able to use the PID controller, the controller was tuned using the II Ziegler-Nichols method and the manual method. To check how the applied controller works in automatic liquid level control and how its settings affect the operation of the system, tests were carried out comparing the operation of various configurations of the PID controller in various operating conditions. The work carried out showed the possibility of developing a low-cost automatic liquid level control system, which can be successfully used in manufacturing processes.

Implementation of Contactless Liquid Level Sensing

Usually, the arises to measure liquid levels in containers, in large industries; where large volumes of liquids are stored, in small scale industries and residential buildings in developing countries that sees many households implementing their own domestic water supply system. Measurements by humans may be influenced by sentiments, fatigues, lack of concentration, and so on, which has led to economic losses due lost liquid and wasted electric power. Therefore, researches have been directed toward development of automatic liquid level sensing technologies. This paper will assist instrumentation researchers to know the state of the art in level sensing technology, and practitioners in selecting the right kind of level sensors for a particular application.

Автоматический уровнемер жидкости для взрывоопасных зон

The purpose of this work is to develop an automatic liquid level meter for hazardous zones. The analysis of currently known level meters, which are widely used in the oil and oil refining industry, showed that their cost is very high. The proposed level gauge cost is significantly lower than that of industrial analogues for manufacture and operation. This paper describes the capabilities and operating principles of the developed liquid level meter for hazardous zones. The proposed level gauge is designed to measure the level of petroleum products for technological accounting and control of petroleum products. The flowchart and algorithm of the level gauge operation are given. This paper presents the "upper" level of automatic process control on personal computers. This level is based on the Trace Mode software package by AdAstrA Research Group, Ltd (Russia). The software package provides for the transmission of target setpoints from a computer, preliminary alarm, archiving of data of technological parameters, and a mnemonic diagram for passing technological parameters in real time. The level meter is designed to measure various levels with appropriate settings, the measurement accuracy ranges from 0.5–1 %.

The Design of a Microcontroller-based Automatic Liquid Level Control System

In this paper, a liquid level control system was designed and fabricated. Control of the liquid level was accomplished by adjusting the sup-ply voltage to a centrifugal pump that is delivering the liquid from a reservoir tank to an upper tank. The liquid level control system was implemented on an ATmega328 microcontroller. Three control strategies are implemented, manual mode, ON/OFF controller, and PID controller. Serial communication is used to establish the communication between the ATmega328 and a computer running MATLAB soft-ware. A graphical user interface was constructed to allow users to interact with the system. The system model is obtained using an experi-mental approach. The obtained model is then used for the design of the PID controller. Experimental results are provided to highlight the performance of the implemented controllers.

System two-position control of liquid level in industrial tanks

Design of the automatic liquid level control was performed for the tank rectangular type with the presence of self-regulation. Were found settings of two-position automatic controller with a zone of ambiguity with symmetric static characteristic. Settings meet the specified requirements for the automatic control system. Opportunities and stability of self-oscillations of the controlled variable were assessed by the method of harmonic balance. Was created a virtual model of single-circuit system two-position control of liquid level and estimates the quality of regulation.

The Effects of P, I and D Parameters in Automatic Liquid Level Control Using UniTrain Module

The research discusses some experiments to control the level of liquid inside a tank by using PID controllers which can be divided into four categories. The experiments describe the effect of P, I, and D element. It also discusses the best possible controller, which is a PI controller, for the liquid level tank system. The liquid level controlling is done by adjusting the voltage pump which will further regulate the flow rate of the fluid entering the inlet valve. The liquid that flows through the outlet valve is considered as the disturbance variable to the system. The liquid tank sensor needs to be calibrated prior to the experiments. Calibration can be done manually by using a digital multimeter or by using the computer sofware that is connected directly to the plant system. Set point and PID parameters are determined by the UniTrain and the computer interface. In these experiments, PI controller has the best result with a medium proportional gain (KP = 5) and a small integral gain (TN = 0.2).

THE DEVELOPMENT OF MONITORING AND CONTROLLING SYSTEM OF FLUID LEVEL USING LABVIEW BASED ON MBED NXP LPC1768 MICROCONTROLLER

Based on retrieval and data processing need of an increasingly complex and varied, required for a device that can handle these needs, the computer-based system. The retrieval and processing of data to be read by computer must have a data acquisition system, one of them is a MBED NXP LPC1768 microcontroller. System monitoring and control of liquid levels use mbed NXP LPC1768 microcontroller as the data acquisition system and LabVIEW software as human machine interface (HMI). Data acquisition system between mbed NXP LPC1768 microcontroller using serial communication with the computer. Programming with LabVIEW software built with the blocks into a system program. The control and monitoring with LabVIEW microcontroller based can be implemented by serial communication with LabVIEW software that responds from sensor and equator can be monitoring and controlled in real time. The liquid level control was done in two ways: manually and automatically. two ways: manually and automatically. Automatic liquid level control is by setting the value to the desired level then it will work itself appliance reaches the set value. Keywords: Data acquisition system, Mbed NXP LPC1768, LabVIEW, Human machine interface, manual, automatic.

The Automatic Liquid Level Monitor for Pumping Wells

The Automatic Liquid Level Monitor digitally measures and records the depth to the liquid, the time of the measurement, and the casing pressure of a well at preselected time intervals. These data are used to calculate the bottom-hole pressure to obtain the buildup and drawdown characteristics of a pumping well. Introduction Pressure measurements in producing wells have been Pressure measurements in producing wells have been performed since the early 1920's. Since that time, much performed since the early 1920's. Since that time, much has been published on the importance of pressure tests and methods of analysis in oil and gas wells. Detailed analyses of pressure buildup and drawdown tests are used primarily to determine pump efficiency, formation primarily to determine pump efficiency, formation permeability, reservoir pressure, productivity index, and permeability, reservoir pressure, productivity index, and skin factor. The bottom-hole pressure in flowing wells is relatively easy to obtain with the use of a wireline bottom-hole pressure gauge. However, it is much more difficult to obtain accurate bottom-hole pressure data on pumping wells because of the production tubing and pumping wells because of the production tubing and pump in the well. In an attempt to overcome this pump in the well. In an attempt to overcome this problem, pressure gauges have been developed that mount on problem, pressure gauges have been developed that mount on the bottom of the production tubing. The pressure then is recorded on the surface by means of a cable that is clamped to the tubing. These gauges yield accurate data, but their expense for obtaining information on only one well at a time has limited their use. Some effort also has been made to lower a wireline bottom-hole pressure gauge through the casing annulus, but this, too, generally has proved to be impractical Acoustic well sounding of the liquid level in producing wells has received wide acceptance in the field and can be used to calculate the actual bottom-hole pressure. Several different types of manually operated well sounders presently are available. Each of these devices requires the presently are available. Each of these devices requires the operator to initiate the acoustic pulse into the well casing and to interpret a resultant strip chart, which records the reflections from the tubing collars and the liquid interface. The distances between the collar reflections are measured and are used to determine the depth to the liquid level. To define the shape of a buildup curve, it is necessary to obtain a large number of soundings over a long period of time. Because of the excessive operator time period of time. Because of the excessive operator time required to obtain these readings, the manually operated sounder seldom is used in this way. The Automatic Liquid Level Monitor, developed by Mobil Research and Development Corp., overcomes this difficulty so that the liquid level during buildup and drawdown tests can be measured automatically often enough and long enough to provide an accurate measure of the shape of the bottom-hole pressure curves. This is a digital system that prints out not only the actual depth to the liquid level in feet, but also the time of the sounding and the casing pressure, These measurements are made automatically on a preselected schedule without having an operator in attendance. Description of the Automatic Liquid Level Monitor The Automatic Liquid Level Monitor uses the same method of acoustic well sounding as do the manually operated devices. However, instead of determining the liquid depth by counting tubing collars, the travel time of the acoustic pulse is measured accurately by counting the number of pulses from a very precise 1-MHz crystal-controlled oscillator. This system yields a high degree of sensitivity to the liquid movement in a well with a precision limited only by the initial calibration of the monitor and the stability of the oscillator. JPT P. 1019

An automatic liquid level controller for use with liquid nitrogen

An automatic liquid level sensing device for liquid nitrogen has been devised. The alterations necessary to convert a commercially available refrigeration temperature controller for proper operation are described.