UA77120C2 - Device for treating fluid flow by cavitation - Google Patents

Abstract

The invention concerns the devices for treating the fluid flow by cavitation, in particular, hydrodynamic oscillators. A device contains a cylindrical housing, in which are located inlet and outlet branch pipes, a discharge chamber connected with inlet duct, an ultrasonic cavitation device, which is made with internal cavitation chamber connected with initial branch pipe, and it consists of mobile and stationary emitters with end blades located along the spiral, screw insert in the inlet duct and mechanism of axial displacement of mobile emitter. The blades of mobile emitter are tightly located between the blades of fixed emitter and form spiral end channels, which connect pressuring and cavitation chambers. On the frontal surface of mobile emitter a slot divider is installed in the form of annular log with slots, and on the rear end of inlet duct an annular groove is made for insertion in it of the slot divider at displacement of mobile emitter. The invention allows to perform fine adjustment of the pressure differential in the fluid flow at inlet and outlet of ultrasonic cavitation device.

Description

Description of the invention

The invention relates to devices for processing liquid flow by cavitation, in particular to hydrodynamic 2 oscillation generators, which are actuated by the pressure of the flowing medium.

The invention can be used for the processing of technological flows of liquid by cavitation in the chemical, petrochemical, oil refining, coke chemical, food, perfumery industries, as well as in the production of medicines, building materials and industrial wastewater treatment.

From the state of the art, a device for processing a fluid flow (liquid fuel) 70 by cavitation is known, which contains a cylindrical body in which the inlet and outlet nozzles are located, a discharge chamber connected to the inlet nozzle, an ultrasonic cavitator made with an internal cavitation chamber connected with an outlet nozzle, and consisting of a movable and a fixed emitter, made with two end blades arranged in a spiral and connected so that the blades of the movable emitter are tightly located between the blades of the fixed emitter and form spiral end 12 channels connecting the injection and cavitation cameras, and the mechanism of the axial movement of the movable emitter (M/08805497, IPKYA GO2M 33/00, VOTE 5/00, 5/08, 07/28/1988, analogues.

In this device, the cylindrical housing is located vertically, the inlet nozzle is located in the wall of the housing, the outlet nozzle is located in the bottom of the housing, and the mechanism for the axial movement of the movable emitter is made in the form of a screw, which is placed in the threaded hole of the cover fixed in the upper part of the housing.

The screw is connected to a movable emitter with the possibility of rotation with the help of a plate.

This device allows you to perform cavitation treatment of the liquid flow by changing its flow rate and physical and chemical characteristics at the pressure at the outlet of the device, which coincides with the pressure of the consumption system, from 1 to 5 kgf/cm7.

At higher pressure values at the outlet of the device (fuel supply), it is difficult to create conditions for the occurrence of cavitation and high-quality processing of the liquid flow. Gee)

This is due to the fact that in such a device the pressure at which cavitation occurs in the liquid flow depends significantly on the difference between the pressure in the liquid flow to the ultrasonic cavitator (in the injection chamber) and the pressure in the liquid flow after the ultrasonic cavitator (in the cavitation chamber ).

When the pressure at the outlet of the device increases, the value of this difference increases sharply, which causes a 3o increase in energy costs for creating high pressure at the entrance to the device. Gee!

In addition, this device has a low efficiency of homogenization of the liquid flow, due to the large dispersion of the distribution of cavitation bubbles in terms of size and the energy released during their collapse. -

This is explained by the fact that the injection chamber of the device does not provide means for pre-treatment and preparation of the liquid flow before processing it in the cavitation chamber to ensure optimal cavitation modes. -

The disadvantage of this device is also a narrow range of adjustment of the intensity of the cavitation effect on the processed liquid flow.

This is due to the fact that the mentioned action is due only to the working course of the mobile emitter of the ultrasonic cavitator and the change of the total cross-section of the four spiral end channels that connect the injection and cavitation chambers, which does not provide fine adjustment and optimization of the cavitation modes. :z" From the state of the art, the device for processing the flow of liquid (liquid fuel) by cavitation, which contains a cylindrical body in which the inlet and outlet nozzles are located, a discharge chamber connected to inlet nozzle, -1 15 ultrasonic cavitator, made with an internal cavitation chamber connected to the outlet nozzle, and consisting of movable and stationary emitters, made with two end blades, - And located in a spiral and connected so that the blades of the movable emitter are tightly located between the blades of the stationary emitter and form the spiral end channels connecting the injection and cavitation chambers, the screw insert installed in the inlet nozzle and the mechanism for the axial movement of the movable ime) 20 emitters (VO2075619 C1, MPK? EgO2M 27/08, 03.20.1997 , the closest analogue is a prototype). o In this device, the cylindrical body is located horizontally, the inlet and outlet nozzles are located along the axis of the body.

The mechanism of the axial movement of the movable emitter is made in the form of a running sleeve installed in the inlet nozzle with the possibility of rotation and connected to it by a threaded connection of the running nut, connected to the moving emitter by means of pins and nuts. (F) A screw insert installed in the inlet nozzle imparts rotational motion to the incoming fluid flow to

Ge his mixing.

The device is equipped with a chamber located after the ultrasonic cavitator, which contains parts that narrow and expand according to the shape of the Laval nozzle, the minimum diameter of which is determined from a mathematical expression.

This chamber provides cavitation in the flow of liquid inside the cavitation chamber when the pressure at the outlet of the device, i.e. in the consumption system, increases.

At the same time, there is a relatively small difference between the pressure in the liquid flow to the ultrasonic cavitator (in the injection chamber) and the pressure in the liquid flow after the ultrasonic cavitator (in the cavitation chamber).

Due to this, the energy costs during the processing of the liquid flow are reduced, and the quality of its processing is also increased.

This device allows you to perform cavitation treatment of the liquid flow by changing its flow rate and physicochemical characteristics at the pressure at the outlet of the device, which coincides with the pressure of the consumption system of more than 5 kgf/cm?.

The disadvantage of this device is the low efficiency of the pretreatment of the liquid flow, which consists only in adding to it a rotational movement for mixing the liquid due to the installation of a screw insert in the inlet nozzle.

In addition, the device lacks the means of simultaneous control of the process of pretreatment of the liquid flow and 70 creation of an optimal pressure drop in the liquid flow at the inlet (in the injection chamber) and the outlet (in the cavitation chamber) of the ultrasonic cavitator using a common drive when the pressure at the outlet of the device changes and physical and chemical characteristics of the treated liquid.

Because of this, the high efficiency of the cavitation effect of the moving and stationary emitters on the flow of the liquid processed in the cavitation chamber of the ultrasonic cavitator is not ensured, as a result of which its high homogenization is not achieved when the pressure at the outlet of the device and the physicochemical characteristics of the liquid being processed are changed.

This is explained by the fact that the device does not provide means for effective pretreatment and preparation of the liquid flow before processing it in the cavitation chamber of the ultrasonic cavitator to ensure optimal cavitation modes.

The technical problem, the solution of which is directed to the solution of the invention, is the improvement of the device for processing the liquid flow by cavitation by introducing into its composition a multi-channel separator of the liquid flow, installed with the possibility of compatible movement with a moving emitter, to ensure, firstly, the separation of the axial flow of liquid into many jet flows , which separately enter the injection chamber, and, secondly, the possibility of simultaneously inversely proportional change of the cross-sections of the multi-channel separator and the spiral end channels of the ultrasonic cavitator using a common drive.

The technical result achieved by the use of the invention is the possibility of fine adjustment of i) the pressure drop in the liquid flow at the inlet (in the injection chamber) and outlet (in the cavitation chamber) of the ultrasonic cavitator with the help of a common drive, which will ensure high efficiency of the cavitation action and homogenization of the processed fluid flow when the pressure changes at the outlet of the device and physico-chemical "from the characteristics of the treated fluid.

The set technical problem is solved, and the technical result is achieved by the fact that in the device for processing the liquid flow by cavitation, which contains a cylindrical body in which the inlet and outlet nozzles are located, "h- a discharge chamber connected to the inlet nozzle, an ultrasonic cavitator made of an internal cavitation chamber, connected to the outlet nozzle, and consisting of movable and stationary radiators, made with end blades arranged in a spiral and connected so that the blades of the movable radiator are tightly located between the blades of the stationary radiator and form spiral end channels, connecting the injection and cavitation chambers, a screw insert installed in the inlet nozzle and the mechanism for axial movement of the movable emitter, according to the invention, a slotted cutter in the form of an annular protrusion with slots is installed on the front surface of the movable emitter, and an annular groove is made on the 70 rear end of the inlet nozzle for deepening of the slotted cutter into it when moving the movable emitter. The given features of the invention are essential, as they are sufficient in total to solve the technical problem and achieve the technical result, and each separately is necessary for the identification of the claimed device.

This set of general and basic essential features different from the prototype, characterized by the improved device, unknown from the prior art, is new and sufficient for all cases to which the scope of legal protection is extended.

Cause-and-effect relationship between a set of essential features of the device, in particular, distinctive ones in their interaction

The general features of solving the technical problem and achieving the technical result are as follows.

Installation on the front surface of the mobile emitter of a slot splitter in the form of a ring-shaped protrusion with slots and the execution of an annular groove on the rear end of the inlet nozzle for deepening into it about the slot splitter during the movement of the movable emitter allows splitting the axial flow of liquid into many radial jet streams.

These jet streams enter the injection chamber in the form of partially overlapping torches.

This significantly improves the mixing and homogenization of the liquid in the injection chamber before its cavitation

F, processing in the cavitation chamber of the ultrasonic cavitator. In addition, this improvement makes it possible to make an inversely proportional simultaneous change of the cross-sections of the slit splitter (multi-channel splitter) and the spiral channels of the ends of the ultrasonic cavitator. When deepening the slot cutter into the annular groove of the inlet nozzle by any amount, the moving emitter moves away from the fixed emitter of the ultrasonic cavitation by the same amount, as a result of which the cross-sections of the spiral end channels between them increase and vice versa,

Due to this, it is possible to fine-tune the pressure drop in the fluid flow at the inlet (in the injection chamber) and outlet (in the cavitation chamber) of the ultrasonic cavitator using a common 65 drive, which will ensure high efficiency of the cavitation action and homogenization of the processed fluid flow when the pressure at the outlet changes from the device and physical and chemical characteristics of the treated liquid.

The device also has additional distinctive features that characterize it in individual cases of modification of the design of the constituent elements and are used to improve the technical result.

In the device for processing the flow of liquid by cavitation, according to the invention, the slit splitter of the moving emitter is made of 20-30, preferably 24, slits evenly spaced around the circle.

The choice of the mentioned number of slots in the slot splitter is due to the need for the maximum possible location of them in a circle, which is necessary for effective splitting of the axial flow of liquid into many radial jet streams.

At the same time, the mixing and homogenization of the liquid in the injection chamber is significantly improved and the efficiency of its cavitation treatment in the cavitation chamber of the ultrasonic cavitator increases.

The selected range of the number of slots (20-30) in the slotted cutter is optimal, determined experimentally and due to the technological possibilities of their execution in a circle with an angular step from 189 to 125.

The selection of the number of slits in the slit splitter is less than the lower limit (20) is impractical, since this significantly reduces the efficiency of liquid mixing and the degree of its homogenization in the injection chamber.

Choosing the number of slots in the slotted cutter greater than the upper limit (30) is also impractical, since it will be technologically difficult to perform them with an angular step of less than 122,

The predominant number of slots in the cutter is 24.

This is explained by the best possible combination of the efficiency of splitting the axial flow of liquid into 24 radial jet streams and the manufacturability of their manufacture with an angular step of 159.

In the device for processing the liquid flow by cavitation, according to the invention, the slits in the slotted splitter of the moving emitter can be made in the form of end cuts of a triangular shape, the tops of which are directed towards the frontal surface of the moving emitter.

This execution of the slits in the slotted splitter of the mobile emitter (option 1) ensures the expansion of the slots to the end part of the slotted splitter. Ge

With a slight movement of the movable emitter and the deepening of the slit cutter into the annular groove of the inlet nozzle, there is an intense decrease in the area of the cross-sections of the slits from the maximum value to the minimum value.

This provides operational fine adjustment of the cavitation mode in the cavitation chamber when the physicochemical characteristics of the processed liquid stream change. (av)

In the device for processing the liquid flow by cavitation, according to the invention, the slits in the slotted dissection of the moving emitter can be made in the form of longitudinal end cuts of a rectangular shape. see

This execution of the slots in the slotted dissection of the moving emitter (option 2) ensures the same h-- width of the slots along the entire length.

When moving the movable emitter and deepening the slit cutter into the annular groove of the inlet pipe, the area of the cross-sections of the slits gradually decreases from the maximum value to the minimum value as they are overlapped by the walls of the said annular groove.

This ensures a smooth and fine adjustment of the cavitation mode in the cavitation chamber when the physicochemical characteristics of the treated liquid stream change. "

In the device for processing the liquid flow by cavitation, according to the invention, the movable and stationary emitters can be made with three end blades each. - c This execution of the moving and stationary emitters ensures the formation of six spiral end channels, through which six jet streams of liquid enter the cavitation chamber. "» At the exit from the end channels, the jet streams collide, causing ultrasonic pulsations.

The mentioned six end channels provide a high frequency of oscillations and, accordingly, an increased number of cavitation bubbles per unit volume of the processed liquid, when they collapse, a more efficient and energetic effect on the components of the liquid flow and their final mixing at the molecular level occurs. -1 Thus, additional distinguishing features that characterize the device provide the possibility of fine adjustment of the pressure drop in the liquid flow at the inlet (in the injection chamber) and outlet (in the cavitation chamber) of the ultrasonic cavitator using a common drive. yuyu 50 At the same time, a high efficiency of cavitation action and homogenization of the processed liquid flow is achieved when the pressure at the outlet of the device and the physical and chemical characteristics of the processed liquid change. (42) Further, the invention is explained by a detailed description of an example of its implementation and operation with references to the attached drawings.

Fig. 1 shows a device for processing a liquid flow by cavitation, general view, longitudinal section.

Fig. 2 shows a section A-A in Fig. 1.

Fig. 3 shows a section B-B in Fig. 1. o Fig. 4 shows a section B-B in Fig. 1. i.e.) Fig. 5 shows a movable emitter with a slotted cutter, a longitudinal section (option 1).

Fig.b6 shows a movable emitter with a slit cutter, longitudinal section (option 2). 60 The device for processing the liquid flow by cavitation (Fig. 1-6) contains (Fig. 1) a cylindrical body 1, in which the inlet and outlet nozzles 2, 3 are located, the injection chamber 4, connected to the inlet nozzle 2, the ultrasonic cavitator 5, made with an internal cavitation chamber 6 connected to the outlet 3.

Ultrasonic cavitator 5 consists of movable and stationary emitters 7, 8. 6E Movable and stationary emitters 7, 8 are made with end blades 9, 10 arranged in a spiral (Fig. 2-4).

The movable and stationary radiator 7, 8 are connected by end blades 9, 10 so that the blades 9 of the movable radiator 7 are tightly located between the blades 10 of the stationary radiator 8 and form spiral end channels 11, 12, connecting the injection and cavitation chambers 4, 6.

The device also includes a screw insert 13 (Fig. 1) installed in the inlet pipe 2 and a mechanism 14 for axial movement of the movable radiator 7.

On the front surface 15 of the movable radiator 7, a slotted splitter 16 is installed in the form of a ring protrusion with slots 17.

The slot cutter 16 can be made separately and fixed on the front surface 15 of the movable 7/0 Emitter 7, for example, by welding.

The slit cutter 16 can be made on the front surface 15 of the movable emitter 7 in the form of a single part.

An annular groove 19 is made on the rear end 18 of the inlet pipe 2 for the insertion of the slit cutter 16 into it when moving the movable emitter 7.

The housing 1 is made in the form of a glass and is located horizontally, and the inlet and outlet nozzles 2, C are located along the axis of the housing 1.

The mechanism 14 of the axial movement of the movable emitter 7 is made in the form of a running sleeve 20, installed on the inlet pipe 2 with the possibility of rotation.

The running sleeve 20 is fixed from axial movement on one side by the body 1, and on the other side by the retaining ring 21.

The locking ring 21 is inserted into the annular groove 22 of the inlet nozzle 2.

A running nut 24 is mounted on the running sleeve 20 with the help of a threaded connection 23.

In the running nut 24, pins 25 are installed, which are passed through the holes 26 made in the housing 1.

Pins 25 have landing necks 27 and threaded shanks 28.

The movable radiator 7 is made with holes 29, with the help of which it is placed on the landing necks 27 of the pins 25 and fixed on the threaded shanks 28 of the latter with nuts 30. i)

Channels 31, 32 of the inlet and outlet nozzles 2, C have a cylindrical shape.

Channels 31, 32 of the inlet and outlet nozzles 2, C can have sections that narrow and widen in the shape of a Laval nozzle. о о о Inlet and outlet nozzles 7, 8 are equipped with flanges 33, 34 for connection to the inlet main and consumption main. with

The stationary radiator 8 is attached to the housing 1 with the help of bolts Z5. "-

The inlet pipe 2 is installed in the bore 36 of the body 1 and is connected to it, for example, by welding.

The output nozzle C is installed in the boring 37 of the stationary emitter 8 and is connected to it, for example, by welding. Cha

The slit splitter 16 of the movable emitter 7 is made of 20-30, preferably 24, slits 17 evenly spaced around the circle (Fig. 1-4).

The slits 17 in the slit splitter 16 of the movable emitter 7 are made in the form of end cuts of a triangular shape 38 (option 1), the tops of which are directed towards the frontal surface 14 of the movable emitter 7 (Fig. 5). "

The slits 17 in the slit splitter 16 of the movable emitter 7 are made in the form of longitudinal end cutouts ev) with a rectangular shape 39 (option 2) (Fig. b).

Movable and stationary radiators 7, 8 are made with three end blades 9, 10 each (Fig. 2-4). ;" The device for processing the liquid flow by cavitation works as follows.

The processed liquid flow under pressure is supplied through the channel 31 of the inlet pipe 2 to the screw insert 13, passing through which it acquires a rotational movement. -I The rotational movement of the liquid flow ensures preliminary mixing of the components of the processed environment.

Ш- Next, the liquid flow falls on the frontal surface 15 of the slotted cutter 16, which, with the help of slots - 17, made in the form of triangular or rectangular end cuts 38, 39, ensures the distribution of the axial 5r liquid flow into 20-30 radial jet streams. These radial jet streams enter the injection chamber 4 in the form of partially overlapping torches and mix, as a result of which the liquid flow components are averaged.

Due to this, the mixing and homogenization of the liquid in the injection chamber 4 before its cavitation treatment in the cavitation chamber 6 of the ultrasonic cavitator 5 is improved.

From the injection chamber 4, a pre-processed flow of liquid passes through three spiral end channels 11 and three spiral end channels 12 formed by the blades 10, 11 of the moving and stationary emitters 7, 8

F) of the ultrasonic cavitator 5, the liquid enters the cavitation chamber 6 of the latter in six spiral jet streams (5).

At the exit from the mentioned spiral end channels 11, 12, jet streams of liquid collide with high speed, forming pulsations.

With a certain pressure drop in the liquid flow at the inlet (in the discharge chamber 4) and the outlet (in the cavitation chamber 6) of the ultrasonic cavitator 5, the ratio of frequency and intensity of oscillations creates conditions for the appearance of cavitation bubbles in the liquid flow in the cavitation chamber 6.

Due to the fact that the spiral end channels 11, 12 are oriented to the axis of the cavitation chamber 6, 65, the flow is swirled, and the cavitation bubbles formed are concentrated near the mentioned axis, forming a cavitation bundle.

The high frequency of pulsations and the homogeneity of the processed liquid flow create favorable conditions for the emergence of a large number of cavitation bubbles, and their concentration near the axis of the liquid flow ensures an intense energy effect on its components and their final mixing at the molecular level during the collapse of cavitation bubbles.

The parameters of the cavitation effect on the flow are selected depending on the pressure at the outlet of the device and the physical and chemical characteristics of the treated liquid.

The parameters of the cavitation effect on the flow are selected by changing the ratio between the total cross-section of the slots 17 (triangular or rectangular end cuts 38, 39) of the slot cutter 16 and the 7/0 boomer cross-section of the spiral end channels 11, 12 of the ultrasonic cavitator 5.

This is achieved by moving the movable emitter 7 using the mechanism 14 of its axial movement.

The movement of the movable emitter 7 is carried out by rotating the running sleeve 20 of the axial movement mechanism 14 clockwise or counterclockwise.

At the same time, the running nut 24, connected to the running sleeve 20 by a threaded connection 23, moves forward or backward along the axis of the device compatible with the pins 25 and the movable radiator 7 fixed to them with the help of nuts 30.

When the slotted cutter 16 is deepened into the annular groove 19 of the inlet nozzle 2, the movable emitter 7 moves away from the stationary emitter 8 of the ultrasonic 2o Cavitator 5 by any amount by the same amount.

As a result, the total cross-section of the spiral end channels 11, 12 between them increases or decreases,

Due to this, it is possible to fine-tune the pressure drop in the fluid flow at the inlet (in the injection chamber 4) and outlet (in the cavitation chamber b) of the ultrasonic cavitator 5 with the help of the General drive - the mechanism 14 of the axial movement of the movable emitter 7.

This makes it possible to create optimal conditions under which cavitation occurs, which ensures high efficiency of i) cavitation action and homogenization of the processed liquid flow when the pressure at the outlet of the device and physico-chemical characteristics of the processed liquid change.

The proposed device for treating a liquid flow by cavitation meets the criterion of "industrial suitability", because it can be manufactured industrially at any machine-building enterprise using universal equipment, modern technology and existing materials, and can be used many times for cavitation treatment of technological flows liquids in various industries. "-

List of designations 1. Body і- 2. Inlet nozzle ч 3. Outlet nozzle 4. Discharge chamber 5. Ultrasonic cavitation chamber 6. Cavitation chamber " 7. Movable emitter with c 8. Stationary emitter 9. Blades of a movable emitter 7 ;" 10. Blades of a fixed emitter 8 11. Spiral end channels 12. Spiral end channels -I 13. Screw insert 14. Mechanism of axial movement of a mobile emitter 7

Ш- 15. Frontal surface of the moving radiator 7 - 16. Slotted splitter 17. Slotted splitter slots 17 and 18. Rear end of inlet nozzle 2 o 19. Annular groove in rear end 17 of inlet nozzle 2 20. Running sleeve 21. Retaining ring 22. Annular groove in the inlet pipe 2 23. Threaded connection (Ф) 24. Running nut 25. Stud 26. Holes in the housing 1 in 27. Landing neck of the stud 24 28. Threaded shank of the stud 25 29. Holes in the movable radiator 7 30 .Nut 31. Channel of inlet nozzle 2 65 32. Channel of outlet nozzle C 33. Flange of inlet nozzle 2

34. Flange of the outlet pipe Z 35. Bolt 36. Boring in the housing 1 37. Boring in the fixed radiator 8 38. End cut of triangular shape 39. End cut of rectangular shape

Claims (5)

The formula of the invention 1. A device for processing a liquid flow by cavitation, containing a cylindrical body in which the inlet and outlet nozzles are located, a discharge chamber connected to the inlet nozzle, an ultrasonic cavitator, which is made with an internal cavitation chamber connected to the outlet nozzle, and consists of /5 of moving and stationary radiators, made with end blades arranged in a spiral and connected in such a way that the blades of the mobile radiator are tightly located between the blades of the stationary radiator and form spiral end channels connecting the injection and cavitation chambers, a screw insert installed in the inlet nozzle , and the mechanism of the axial movement of the movable emitter, which is distinguished by the fact that on the front surface of the movable emitter there is a slotted cutter in the form of a ring 20r protrusion with slits, and on the rear end of the inlet pipe there is an annular groove for sinking the slotted cutter into it when moving the movable nozzle heat exchanger 2. The device according to claim 1, which is characterized by the fact that the slot cutter of the moving emitter is made of 20-30, preferably 24, slots evenly spaced around the circle. C. The device according to claim 1 or 2, which differs in that the slits in the slotted splitter of the movable emitter are made in the form of end cutouts of a triangular shape, the tops of which are directed towards the front surface of the movable emitter. at 4. The device according to claim 1 or 2, which is characterized by the fact that the slits in the slotted splitter of the moving emitter are made in the form of longitudinal end cutouts of a rectangular shape. 5. The device according to claim 1 or 2, which differs in that the movable and stationary emitters are made with three end blades each. with "- in and - - and? -i -i - ime) (42) ime) 60 b5