RU2166987C1 - Cavitation apparatus - Google Patents

Abstract

FIELD: devices for forming artificial cavitation in liquid media for intensification of physico-chemical processes. SUBSTANCE: proposed apparatus has housing with inlet and outlet holes forming working chamber where rotor and stator are mounted on drive shaft. Rotor and stator consists of alternating disks. First disk of rotor is provided with radial blades whose front portion (in way of rotation) is made in form of wedge and rear portion is made in form of parallelepiped. Second disk of rotor is provided with radial slots and third of rotor is perforated. Disks of stator mounted in between disks of rotor are provided with radial slots. EFFECT: enhanced efficiency; increased capacity of activation of physicochemical processes. 5 cl, 3 dwg

Description

 The invention relates to devices for creating artificial cavitation with the aim of using the resulting cavitation effects to intensify physico-chemical processes in various industries: chemical, food, biochemical, etc.

 The device can be used for disinfection and decontamination of liquids, as well as a compact and highly efficient source of heat in any industry.

 A well-known activator of physical and chemical processes using the effects of hydrodynamic cavitation created in a closed chamber with a fluid working medium flowing through it [1]. A stator is installed in the boat and a rotor is mounted on the drive shaft, during rotation of which, as a result of the interaction of the stator and rotor with the working medium, cavitation phenomena occur, accompanied by local significant increases in temperature and pressure, which are the initiating factors of various physicochemical processes.

 The disadvantages of this device are the low productivity and relatively low activation efficiency, especially for energy-intensive technological processes, due to significant energy losses due to dissipative phenomena - hydraulic friction, overcoming the hydrodynamic resistance of the medium, etc.

 Known cavitation activator, in which the cavitation mode is created in an intense ultrasonic field excited in a liquid working medium [2].

 The known activator consists of at least two working chambers, the first of which has an inlet for supplying a working medium, and in the second an outlet. In each chamber, a rotor is installed on the drive shaft, which is an impeller of a centrifugal pump. A ring with holes is fixed around the circumference of the impeller. The stator is made in the form of a ring concentric with the rotor with holes located opposite the holes in the rotor ring.

 When the rotor rotates, the working fluid is fed to the outlet of the centrifugal pump wheel and passes through the holes in the rotor and stator rings, which periodically overlap. When the openings are closed, the pressure in the chamber rises to a certain maximum value determined by the pressure of the liquid at the inlet and the pressure of the pump, i.e. its power, when opened, drops to the minimum value determined by the required flow rate, i.e. device performance. Thus, when the device is operating in a working environment, an alternating pressure field is excited and propagates, i.e. sound.

 In the known device, the number of holes in the rings of the rotor and stator, the rotation speed and the pressure drop are selected so that ultrasound is excited in the working medium, the intensity of which is sufficient to cause cavitation phenomena in the medium, the effects of which (local pressure and temperature increases, ionization particles of the medium, etc.) activate the necessary physical and chemical processes.

 The disadvantages of the known devices are the limited activation efficiency of physicochemical processes and the performance of the device due to the following reasons.

 It is known (see, for example, L. D. Landau, A.I. Akhiezer, E. M. Lifshits, "The Course of General Physics." - M.-1965), that cavitation limits the intensity of ultrasound in a liquid medium. In the known device, an increase in the intensity of ultrasound is associated with an increase in the pressure drop p (max) -p (min) in the working chamber, which, in turn, leads to an increase in the power of the centrifugal pump or in the number of sequentially operating devices (as suggested by the authors). Both of these methods lead to an increase in the size, weight, power consumption and cost of the device.

 Moreover, the increase in the ultrasound intensity in the known device by these extensive means is limited by the fact that when it is working in the gap between the rotor and stator rings, hydrodynamic cavitation occurs even at relatively low rotor speeds, which limits the intensity of the generated ultrasound. The specified limitation leads to the fact that the intensity of cavitation phenomena and, accordingly, the activation efficiency in the known device do not exceed the efficiency of hydrodynamic activators.

 In addition, in the known device, the ultrasound intensity is unstable and significantly depends on the pressure of the working fluid at the inlet and the speed regime of the rotor, which impairs the quality of activation and creates certain operational problems associated with the need to control and adjust the operating modes.

 The aim of the present invention is to provide a highly efficient cavitation apparatus for activating various physicochemical processes in liquid media, devoid of these disadvantages.

 To this end, in a well-known cavitation apparatus containing a housing with inlet and outlet openings for the working fluid, forming a working chamber in which the rotor is located on the drive shaft and the stator, the latter consist of alternating disks mounted perpendicular to the axis of symmetry of the chamber, the first of which the input of the rotor disk has at least two radial blades located in its plane uniformly around the circumference, the front part of which is made in the form of a wedge, the rear is a parallelepiped with a radial The grooves on its lateral faces, in the second rotor disk and in the stator disks installed between the rotor disks, made radial slots evenly spaced around their circumferences, the last rotor disk made perforated.

 In FIG. 1 shows an axial section of a cavitation apparatus.

 In FIG. 2 - rotor cavitation apparatus.

 Figure 3 - two projections of the stator disk.

 The inventive cavitation apparatus includes a housing 1, forming a working chamber 2 with input 3 and output 4 holes, a drive shaft 5, a first rotor disk 6 with blades 7, a first stator disk 8, a second rotor disk 9, a second stator disk 10, slots 11 in the disks 8, 9, 10, the third rotary disk 12 with perforation 13, the grooves 14.

 The device operates as follows. When the rotor rotates, the cutting blades 7 of the disk 6 cut through the working fluid in the chamber 2. Due to the action of the wedge of the blade, the stresses arising in the liquid significantly exceed the tensile strength of the liquid, as a result of which the continuity of the liquid breaks on the cutting edge of the blade 7 and a large cavitation cavity forms behind the blade . At the same time, the beveled face of the wedge is discarded in the direction of exit 4 from chamber 2, i.e. fluid flows in the right direction. With the next oncoming blade, the resulting cavitation cavity is crushed into smaller cavitation cavities, which pass through the slots 11 of the stator disk 8 with a fluid flow to the next pair of cavitator - rotor disk 9 and stator disk 10, where the process of formation and crushing of cavitation cavities continues. In the zone of the second 9 and third 12 rotor disks, cavitation bubbles of optimal sizes are intensively formed, which, when collapsed, initiate powerful cavitation effects that activate physicochemical processes in the working medium.

 Thus, the rotor blades simultaneously perform two functions: they initiate cavitation bubbles and create the necessary flow of working fluid through the chamber. This made it possible to exclude the elements of the injection pump from the apparatus and thereby reduce the unproductive energy costs, i.e., increase the efficiency of the cavitation apparatus. The use of the second rotor disk with slots and the last perforated disk made it possible to intensify the formation of cavitation bubbles of optimal sizes in the zone of action of these disks, i.e. further increase activation efficiency. In addition, in the proposed device, it is possible to use the same type of stator disks with slots of arbitrary section, for example, rectangular, which reduces the cost of its manufacture.

 Tests of the prototype cavitation apparatus showed that its efficiency is 4 times higher than the known one. This device in the manufacture of more technologically advanced prototype, uncritical to the accuracy of assembly and, ultimately, requires less cost for its production and operation.

 Cavitation apparatus can be used as a heat generator. Currently, a prototype is used on Rechflot ships for water disinfection.

List of references:
1. Copyright certificate N 1358140, MKI B 01 F 11/02. Cavitation mixer.

 2. PCT N 94/09894, MKI B 01 F 7/00, 11/00. Ultrasonic activator.

Claims (5)

 1. Cavitation apparatus, comprising a housing with inlet and outlet openings, forming a working chamber in which a rotor is mounted on the drive shaft and a stator, characterized in that the rotor and stator consist of alternating disks, while the first rotor disk from the input has in its plane there are radial blades, the front part of which is made in the form of a wedge, the rear part is a parallelepiped, in the second rotor disk and stator disks installed between the rotor disks, radial slots are made, and the third disk otorrhea perforated.  2. The cavitation apparatus according to claim 1, characterized in that the plane of the rotor and stator disks are installed perpendicular to the axis of symmetry of the chamber.  3. The cavitation apparatus according to claim 1, characterized in that the first rotor disk has at least two blades.  4. The cavitation apparatus according to claim 1, characterized in that the rotor blades, the slots of the rotor and stator disks are located uniformly around the circumference of their disks.  5. The cavitation apparatus according to claim 1, characterized in that radial grooves are made on the side faces of the parallelepiped.

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