RU32005U1 - Ultrasonic Liquid Processing Device - Google Patents

Description

Ultrasonic Liquid Processing Device

2005 1, |

MPKV06V1 / 20

The proposed utility model relates to devices for producing mechanical vibrations of supersonic frequency using vibrations of a flowing medium for dispersing and mixing fluid flows, and can be used in various industries for mixing and emulsifying liquids of various physical and chemical properties and intensifying various technological processes, for example in oil refining, chemical, paint and varnish and other industries. In particular, it can find application for the processing of liquid fuels with improved performance and increase the efficiency of their use in power plants. For example, for processing fuel oil in order to improve its performance, as well as when cleaning storage tanks for fuel oil in order to obtain mixtures suitable for burning in boilers and industrial furnaces by dispersing and homogenizing illiquid fuel.

The closest technical solution (prototype) is a device for processing liquids and gases, containing a housing with a series of sequentially installed jet ultrasonic emitters with inlet nozzles bounded by blades made in the shape of an Archimedes spiral. (AS USSR No. 316482, IPC B06B 1/20, publ. 1971).

The disadvantage of this device is the low intensification of the process of dispersion and homogenization.

The objective of the proposed technical solution is to increase the efficiency and productivity of the device by providing

high quality homogenization, dispersion and mixing of fluid flows, different in physical and chemical properties. The problem is solved in the following way. In the known device containing a cylindrical body, inside which are sequentially placed jet ultrasonic emitters with inlet nozzles bounded by blades made in the shape of an Archimedes spiral, each ultrasonic jet emitter is coupled with a cavitator made in the form of a diffuser with an annular swirler equipped with tangential windows that are communicated with the input nozzles of the aforementioned jet ultrasonic emitters, and in the inner cavity of the cavitator mounted diffuser flow liquid.

In addition, the flow diffuser is made in the form of a cone, the top of which is directed towards the moving fluid flow, and the device is equipped with at least two jet ultrasonic emitters and, accordingly, two cavitators. The proposed device provides high quality homogenization, fine dispersion during processing, for example, fuel oil, thereby increasing the efficiency and productivity of the installation.

In FIG. 1 shows a General view of the device in section.

Pa figure 2 shows the location of the tangential windows on the annular swirler of the cavitator in the section (section aa)

Pa fig. Figure 3 shows the input nozzles with blades of jet ultrasonic emitters made in the form of a spiral of Archimedes (section BB).

The device consists of a cylindrical body 1, two inkjet ultrasonic emitters 2 installed in series in it, sequentially docked with cavitators 3, made in the form

diffusers with circular swirls, tangential windows 4 are made around the circumference of the latter 4. In the inner cavity of the cavitators 3, liquid flow diffusers 5 are mounted. The input nozzles of the jet ultrasonic emitters 2, made in the form of an Archimedes spiral, have blades 6 located periodically around the circle, forming between the input and output the edges of the interscapular channels 7. Between the cavitators 3, and the inner surface of the housing 1 is formed a peripheral chamber 8. The diffusers of the fluid flow 5 are made in the form of a cone vertices directed towards the process stream fluid and are arranged in the inner cavities 9 cavitators 3 in tangential location area 4 windows.

The device operates as follows. The fluid flow, moving inside the housing 1, enters the internal cavity 9 of the cavitator 3 and flows onto the flow diffuser 5, as a result of which the flow rate of the fluid increases due to the narrowing of the passage section of the cavitator 3. Then, the fluid flow rate, which passes through the tangential windows 4 of the recorder, due to an even greater narrowing of the flow area, increases sharply, and the pressure drops. This leads to the fact that in the peripheral chamber 8 behind the tangential windows 4 there are zones of intense cavitation. The collapse of cavitation bubbles occurring in the peripheral chamber 8 is accompanied by high-velocity microflows and hydraulic shock pressures, which contribute to the dispersion and homogenization of solid asphalt-resinous products and various mechanical impurities in fuel oil. Leaving the tangential windows 4, the fluid flow acquires a rotational movement and, moving along the peripheral chamber 8, under pressure enters the interscapular channels 7 of the jet inlet nozzle

ultrasonic emitter 2. In this case, the fluid flows passing through the indicated channels 7 of a profiled shape are directed at an acute angle to curvilinear obstacles in the form of the walls of the blades 6, which ensures the conversion of the energy of the fluid flow into the energy of ultrasonic vibrations. The acoustic vibrations generated by the jet ultrasonic emitters 2 also contribute to high-quality dispersion and mixing of liquids. In addition, under certain conditions, acoustic cavitation occurs under the action of ultrasonic waves. After passing the first processing cycle, the fluid flow, moving inside the housing 1, enters the internal cavity 9 of the second cavitator 3. The cycle of work is repeated. In the presence of three or more inkjet ultrasonic emitters 2, coupled with cavitators 3, the fluid flows pass the treatment cycle three or more times. All this leads to even better cleaning of fuel oil storage tanks during the processing of illiquid fuels in order to obtain mixtures suitable for burning in boilers and industrial furnaces, as well as processing of fuel oil during long-term storage or immediately before burning to improve its performance. In addition, the cavitational and acoustic effects allow the device to be used both for dispersing and homogenizing and for mixing and emulsifying various liquids, including those differing in physical and chemical compositions, as well as for intensifying various technological processes. Sources of information taken into account:

1.A.S. USSR No. 316482, IPC V06V 1/20, publ. 1969

2.Arzumanov E.S. Cavitation in local hydraulic

resistance.;:;. Energy, 1978.

Claims (3)

1. An ultrasonic device for processing liquid, comprising a cylindrical body and a series of sequentially installed jet ultrasonic emitters with inlet nozzles bounded by blades made in the shape of an Archimedes spiral, characterized in that each inkjet ultrasonic emitter is coupled with a cavitator in the form of a diffuser with an annular swirler equipped with tangential windows that are in communication with the input nozzles of the aforementioned ultrasonic emitters, and in the internal cavity of the cavitator mounted en diffuser fluid flow. 2. The device according to claim 1, characterized in that the diffuser flow is made in the form of a cone, the top of which is directed towards the moving fluid stream. 3. The device according to claim 1 or 2, characterized in that at least two ultrasonic emitters with cavitators are installed in it.