RU68924U1 - INSTALLING LIQUID CLEANING - Google Patents

Abstract

The utility model relates to installations for the separation of suspensions and emulsions in the field of action of centrifugal forces and can be used to purify mineral, synthetic, vegetable oils, water, fuels and other liquids from mechanical impurities in engineering, energy, gas and oil refining and other industries industry in the production and operation of machines. The objective of the utility model is to increase the reliability of the installation, its service life, while improving the quality of liquid purification. The technical result of the utility model is to ensure the working process of cleaning the liquid with a centrifuge in a vibration-free mode of rotation of the rotor, which eliminates the process of deterioration of the quality of cleaning and the possibility of breaking the centrifuge from increasing vibration of the rotor from excessively accumulated contaminants on the inner surface of the hood. The liquid purification unit includes a centrifugal liquid purifier, suction and discharge lines, and a microcontroller. A centrifugal liquid cleaner is equipped with a drive and is mounted on its base through a rubber seal on a tank for collecting sludge. The cavity of the tank for collecting sludge and a centrifugal cleaner made interconnected. The suction and discharge lines are connected to the inlet and outlet of the centrifugal cleaner, respectively. The discharge line is equipped with means for controlling the flow of liquid, pressure and temperature sensors. The microcontroller is connected to the drive. The installation is also equipped with a vibration sensor located in the housing, a threshold device connected to the vibration sensor, while the sensor housing is rigidly connected to the base of the centrifuge, and the threshold device is connected to the microcontroller.

Description

The utility model relates to installations for the separation of suspensions and emulsions in the field of action of centrifugal forces and can be used to purify mineral, synthetic, vegetable oils, water, fuels and other liquids from mechanical impurities in engineering, energy, gas and oil refining and other industries industry in the production and operation of machines.

A well-known stand for cleaning liquids of the SOG-913KT1M brand, manufactured by Tesar-SO CJSC, includes a housing with a compartment for the liquid to be cleaned and sediment collection, on which a centrifugal cleaner is installed tightly through a rubber seal, which is simultaneously a flexible isolation between the compartment and the cleaner. The cleaner includes a rotor with a thin-layer conical dish-shaped insert, which is mounted on a hollow axis with a pressure disk in its upper part, which serves to drain the cleaned liquid through a groove with grooves and sliding bearings. The rotor is hermetically closed by a cap, the cylindrical inner surface of which is a accumulator of sediment discharged from the deposition surfaces of the disk insert during the operation of the centrifuge, and the lower conical part serves to supply the liquid to be cleaned and to drain during the centrifuge stops the dirt accumulated during cleaning on the inner surface of the cap - in a hermetically coupled compartment for collecting sediment. The stand also includes a centrifuge rotation drive from the electric motor, a suction and discharge line, equipment that regulates the capacity that controls pressure and temperature, a microcontroller that, when the operating parameters of the installation deviate (pressure, temperature) from the set ones, gives the command to turn off the centrifuge motor. (Passport 75302.969.00.000 PS, Development of CJSC Tesar SO, 2005, p. 9, fig. 4.1 and p. 14, fig. 4.4).

However, this stand is characterized by insufficient reliability and does not provide high quality of the cleaned liquid. This is due to the following reasons. In the manufacture of a centrifugal cleaner, the centrifuge assembly, which includes all the elements that rotate during operation: the cap, the rotor inside it with a thin-layer conical insert, the sleeve with grooves and sliding bearings pressed into its upper and lower parts, are subjected to complex joint balancing (metal selection or hanging of weights on belt of the outer diameter of the centrifuge hood) in an unfilled state, i.e. in the absence of sediment on the inner diameter of the cap. At the same time, any centrifuge after manufacture

possesses a certain imbalance due to some eccentricity of the inner surface of the cap relative to the axis of rotation, the presence of hidden pores in the body of the rotating centrifuge units, etc. Thus, the balancing process is carried out in the presence and taking into account these deviations, and, therefore, is “dry”, not filled with liquid and a centrifuge that does not yet have a sediment on the surface of the hood, despite a certain eccentricity relative to the axis of rotation, will rotate without beats. However, when the centrifuge is filled with the liquid to be cleaned, due to the eccentric rotation, a slight beating appears, which will increase all the more, the greater the amount of contaminants deposited on the inner surface of the hood. This causes an increasing vibration of the centrifuge, which not only causes deterioration in the quality of liquid cleaning, but can also lead to jamming of the rotor on the axis or to other breakdowns.

Closest to the proposed utility model is a liquid purification unit, including a centrifugal liquid purifier installed on the sediment collector and in communication with it, its drive, a first suction line connected to a centrifugal cleaner, a discharge line equipped with liquid flow control means and a liquid pressure sensor, as well as a source of hydraulic pressure mounted on the suction line. The installation is also equipped with a second suction line with additional means for regulating the flow of liquid connected to the first suction line between the pump and the centrifugal cleaner, a temperature sensor located on the discharge line, a microcontroller, which is capable of visually displaying information about the pressure and temperature values and shutting down the unit in case of deviation operating parameters of temperature and pressure in the discharge line from specified values. The source of hydraulic pressure is a self-priming electric pump. The installation can be equipped with an additional pressure sensor installed on the suction line in front of the centrifugal cleaner (Utility Model Patent of the Russian Federation No. 57149, IPC: IPC: V04V 1/04).

However, this installation also has all of the above disadvantages.

The objective of the utility model is to increase the reliability of the installation, its service life, while improving the quality of liquid purification.

The technical result of the utility model is to provide a working process for cleaning a liquid with a centrifuge in a vibration-free mode of rotation of the rotor,

which excludes the process of deterioration of the quality of cleaning and the possibility of breakdown of the centrifuge from the increasing vibration of the rotor from excessively accumulated contaminants on the inner surface of the hood.

To solve this problem, a liquid purification installation, including a centrifugal liquid purifier, equipped with a drive and mounted on its base through a rubber seal on the sediment collecting tank, while the cavities of the sediment collecting tank and centrifugal cleaner are made interconnected, the suction and discharge lines connected to the inlet and outlet of the centrifugal cleaner, respectively, while the discharge line is equipped with means for controlling the flow of liquid, pressure sensors temperature, a microcontroller, coupled to the drive, according to the utility model is provided with a vibration sensor placed in the case, a threshold device connected to the vibration sensor, wherein the sensor housing is rigidly connected with the base of the centrifuge, and a threshold device connected to the microcontroller.

The vibration sensor can be made in the form of a piezoelectric element.

A rigid connection of the housing of the vibration sensor with the base of the centrifuge is carried out using the bracket.

The installation can be equipped with an additional pressure sensor mounted on the suction line in front of the centrifugal cleaner.

The suction line is equipped with an integrated pump.

The claimed technical result is achieved by introducing into the design of the installation of the vibration sensor, which through a threshold device with a certain degree of vibration of the centrifuge housing gives the command to turn off the centrifuge drive.

The utility model is illustrated by drawings, in which Fig. 1 is a hydraulic diagram of a liquid purification installation, and Fig. 2 is a design of a centrifugal liquid purifier (centrifuge). The positions in the drawing indicate: 1 - centrifugal liquid cleaner (centrifuge); 2 - the base of the centrifugal cleaner (flange); 3 - sealing element; 4 - cover; 5 - a tank for collecting sediment (sump); 6 - plate insert; 7 - sleeve; 8 - a longitudinal groove; 9 - hollow axis; 10 - pressure disk; 11 - a delivery highway; 12 - a cap; 13 - impeller; 14 - conical annular layer; 15 - suction line; 16 - pressure sensor; 17 - valve for regulating fluid flow; 18 - temperature sensor; 19 - an arm; 20 - vibration sensor (in the form of a piezoelectric element located in the housing); 21 - threshold device; 22 - microcontroller.

The installation consists of a supporting body, in front of which there is a tank for collecting sediment (sump) 5, hermetically sealed with a lid 4 and provided with upper and lower holes with plugs for draining the liquid, as well as an indicator of the level of sediment. A centrifugal liquid cleaner 1 is installed above the sludge collection tank 5 through a rubber sealing element 3, made, for example, in the form of an annular membrane, while the annular membrane is attached to the installation casing and at the same time serves as a flexible decoupling between the sediment collection tank and the centrifugal cleaner liquids.

The centrifugal cleaner consists of two parts - fixed and rotating (rotor). The fixed part consists of a base 2, equipped with inlet and outlet fittings, a hollow axis 9, along which the purified liquid is discharged, and a pressure disk 10. At the base there is a channel for the passage of liquid through which the cavities of the container for collecting sediment and a centrifugal liquid cleaner are communicated. The rotor consists of an impeller 13, a sleeve 7 with bearings, a disk insert 6, and a cap 12 with a catchment cup in the upper part, a stopper, and valves (plugs). The cork is equipped with a valve to release air when filling the centrifuge with liquid. The dish insert 6 is a bag assembled from plastic plates worn alternately on the sleeve 7. The sleeve 7 is provided with longitudinal grooves 8 for collecting and draining the purified liquid. The sleeve 7 through the bearings is mounted on a hollow axis 9, in the upper part of which a pressure disk 10 is mounted, with which the liquid cleaned in the disk insert 6 is pumped through the hollow axis 9 into the discharge line 11. The centrifugal cleaner 1 is closed by a cap 12 connected to the impeller 13. Internal the cylindrical surface of the cap is the accumulator of sediment isolated in the dish-shaped insert 6. During operation, the sediment layer takes the form of a conical annular layer 14 located between the outer diameter of the dish-shaped inserts 6 and the inner surface of the shell 12. During the stop contamination accumulated on the inner surface of the centrifuge drain cap in a hermetically conjugated with a centrifugal cleaner tank for collecting sludge. The impeller is a single part, the lower part of which is a pulley for the V-ribbed belt of the centrifuge drive. Vertical blades are installed on the inner conical surface of the impeller, the ends of which are pressed into the sleeve 7, pressing the lower metal plate. On the periphery of the impeller there is a seating surface for joining with the cap 12. Between themselves, the impeller and the cap are connected by a retaining ring that holds the cap from axial

displacement and rotation relative to the impeller. The installation is equipped with a suction line 15, the free end of which is immersed in a container with a cleaned liquid. A pressure sensor 16, a fluid flow control valve 17, a temperature sensor 18 are installed on the discharge line 11. A vibration sensor 20, for example, in the form of a piezoelectric element located in the housing, is mounted on the bracket 19, rigidly connected to the flange 2 (or directly on the flange 2). The piezoelectric element 20 is connected by means of conductors to a threshold device 21, which in turn is connected to a microcontroller 22 (or a control panel) to which information on the pressure in the pressure line (from pressure sensor 16) and on the temperature of the liquid (from the temperature sensor) are received through appropriate sensors eighteen).

Thus, the signal from the piezoelectric element through the threshold device enters the microcontroller (or control panel), which, when the precipitate overflows the inner cylindrical surface of the centrifuge hood and, accordingly, its unbalance, gives the command to turn off the centrifuge's drive (electric motor). Thus, the proposed design of the installation provides automatic rotation stop of the centrifuge when it is unacceptably large filling it with sediment, causing increased vibration of the centrifuge.

When the centrifugal cleaner 1 is in the process of dropping sediment from the disk insert 6 onto the inner surface of the hood 12, it gradually accumulates in a uniform layer around the circumference. Due to the eccentric location of the inner surface of the cap relative to the axis of rotation as the sediment layer accumulates on the inner cylindrical surface of the cap 12, its imbalance with respect to the axis of rotation occurs, the larger the larger the layer of accumulated sediment. As a result, the cap vibrates the greater, the larger the sediment layer. The vibration from the cap 12 is transmitted to the flange 2 and, accordingly, to the bracket 19 rigidly mounted on it, as well as to the body of the piezoelectric element 20 fixed on it. The piezoelectric element 20 is deformed under the influence of accelerations created due to vibrations of its body. Depending on the magnitude of the deformation of the piezoelectric element, the magnitude of the electrostatic potential on its surface changes. When the magnitude of the deformation of the oscillations of the piezoelectric element increases, the amplitude of the electrostatic oscillations on its surface increases, which is fixed by the threshold device 21. At a certain critical value of the electrostatic oscillations, the signal from the threshold device 21 passes through the corresponding sensor to the microcontroller 22, which gives the command to turn off the centrifuge 1 drive.

An example of a specific implementation.

The inventive device was manufactured, in which a centrifuge of the MCC brand with a capacity of up to 50 l / min was used as a centrifugal cleaner, an asynchronous motor with a power of 4 kW, 3000 rpm was used as a drive.

The utility model provides more reliable - trouble-free operation of the installation in connection with the prevention of unbalance of the centrifuge rotor by automatically terminating its operation.

Claims (5)

1. Installation for cleaning liquids, including a centrifugal liquid cleaner, equipped with a drive and mounted on its base through a rubber seal on the tank for collecting sludge, while the cavity of the tank for collecting sludge and a centrifugal cleaner are made interconnected, suction and discharge lines connected to the inlet and the output of the centrifugal cleaner, respectively, while the discharge line is equipped with means for controlling the flow of liquid, pressure and temperature sensors, microcontrol Coupled to the actuator, characterized in that it is provided with a vibration sensor placed in the case, a threshold device connected to the vibration sensor, wherein the sensor housing is rigidly connected with the base of the centrifuge, and a threshold device connected to the microcontroller. 2. Installation according to claim 1, characterized in that the vibration sensor is made in the form of a piezoelectric element. 3. Installation according to claim 1, characterized in that the rigid connection of the housing of the vibration sensor with the base of the centrifuge is carried out by means of an arm. 4. Installation according to claim 1, characterized in that it is equipped with an additional pressure sensor mounted on the suction line in front of the centrifugal cleaner. 5. Installation, according to claim 1, characterized in that the suction line is equipped with a built-in pump.