RU2301916C2 - Method of action onto rheological properties of fluid medium - Google Patents

Abstract

FIELD: mechanical engineering.

SUBSTANCE: invention relates to method of action onto rheological properties of fluid medium which is in contact through boundary surface with at least one corresponding part of plant or machine. According to proposed method, fluid medium is suspension, and vibrations of different elements of fluid medium are excited selectively and at least one boundary surface has vibration component square to tangential plane of boundary surface of wall/fluid medium. According to other version, fluid medium is polymer or mixture of polymers, and vibrations of different elements of fluid medium are excited selectively also, and at least one boundary surface has vibration component in tangential plane of boundary surface of wall/fluid medium.

EFFECT: provision of purposeful action onto rheological properties of fluid medium for reduction of friction of fluid medium against boundary surfaces of fluid medium/machine.

78 cl

Description

The invention relates to a method for influencing the rheological properties of a liquid medium according to the restrictive part of claim 1.

In many food processing processes in both the food and non-food industries, the rheological properties of the product, in particular during processing, play a decisive role in achieving the quality of the final products.

The impact on the rheological properties of the product masses, for example viscous liquid media, as well as highly elastic pastes or elastomeric mixtures, or on the "rheological properties" of fluidized bulk materials can be achieved, for example, by shearing, stretching or fluidization.

These products are, as a rule, homogeneous mixtures of often different pastes (for example, suspension, emulsion). Especially important in this regard is the mastery of the flows of the product mass. Moreover, problems often arise in certain places of the fluid flow, where part of the fluid behaves differently than the predominant part of the flowing fluid. Noteworthy is, for example, the boundary surface between the flowing liquid medium and the inner surface of the part of the machine or line, where often there is strong friction or a very slow flow of the product. Negative consequences are, for example, too long ranges of residence time, delamination of the mixture, temporary or local temperature peaks, etc.

Often, a given machine, with certain processed liquid media, encounters the limits of its productivity and stability. The usual help was always to build an even more powerful or more stable and, thus, more expensive car.

For numerous purposes, vibrations are introduced into liquid media.

So, for example, in GB 2139734 A, US 4516747 or DE 13703766 C1 describes the impact on the boundary layer formed on a body that moves in a liquid medium or is washed by a liquid medium. For this, vibration sources located on the surface of the body are used in order to introduce mechanical vibrations of a certain frequency into the boundary layer or to create a wave propagating along the surface of the body. Due to this, the force exerted by the flowing liquid medium on the body, and, thereby, the hydraulic resistance, is reduced.

No. 5,797,414 describes a method for controlling turbulence in a wall-limited flow of a liquid medium, and in particular in a boundary layer on a wall. For this, sound waves are introduced at an angle to the direction of flow. As a restrictive measure for influencing turbulence, protrusions directed from the wall into the liquid medium or built-in elements located throughout the flow zone are described.

No. 4,271,007 describes a method in which, by introducing mechanical pressure pulses into a liquid medium flowing through a tubular reactor, the formation of deposits on the inner walls of the reactor is prevented. For this, the frequency and amplitude of the pressure pulse are selected so that a turbulent flow arises in the reactor.

WO 94/08732 A1 has a similar purpose. Here, sound waves are introduced into a bath with a liquid medium into which a body is immersed, cleaned of surface deposits or contaminants.

WO 93/08365 A1 describes a pulsating nozzle through which a liquid medium flows. The nozzle is configured to excite oscillations of a fluid flowing through it. This self-excitation of the flowing fluid occurs due to the repetition of the formation and separation of the vortex from the inner edges of the nozzle.

No. 4,832,500 describes a vibratory mixing device consisting of a cylindrical body in which a liquid medium is located or flows through it. The inner surface of the housing contains sharp-edged obstacles. In addition, using a moving reciprocating piston, a low-frequency oscillation is imparted to the liquid medium. Thus, a powerful mixing action can be achieved.

In these publications, however, there is no deliberate effect on the rheological properties of the liquid medium, taking into account its microscopic structure.

The invention is therefore based on the task of eliminating these drawbacks of known methods and installations for processing fluid products and, in particular, improving the impact on the rheological properties of such products.

This problem is solved by the features of the distinctive part of claim 1 of the formula.

Due to the excitation of vibrations of at least part of the elements of the liquid medium forming the liquid medium, it is possible to purposefully influence the rheological properties of at least part of the liquid medium. In particular, it is possible to achieve a reduction in the internal and external friction of the liquid medium against the boundary surfaces of the liquid medium / machine. This allows you to reduce the energy input into the liquid medium, due to which, on the one hand, the service life of the machine is significantly increased, and, on the other hand, the design of large-sized machines is also ensured, without encountering the limits of the force / power created by the machine and its stability. In other words, an increase in throughput can be achieved with the same volumetric flow.

The excitation of oscillations is also an effect on the liquid medium, with the help of which the rheological properties themselves are changed into effective rheological properties. Instead of trying to determine the complex rheological properties of a real liquid medium and manage them, it turned out to be preferable to change the real rheological properties due to the excitation of vibrations in the elements of a liquid medium forming a liquid medium into effective rheological properties that are easier to control than the real rheological properties underlying them. In other words, the liquid medium is “artificially” altered by the introduced vibrations in such a way that it is easier to control, at least in this altered state.

Mostly excite vibrations of the elements of the liquid medium in perfectly defined areas of the liquid medium. So, for example, due to the targeted excitation of oscillations, it is possible to reduce the increased residence time of the liquid medium in niches and dead volumes, or to reduce friction against the boundary surfaces of the wall / liquid medium, in particular in highways for transporting liquid media. This causes a reduction in the residence time range of the liquid medium processed in the machine or transported in the line and also leads to the already mentioned material and energy savings.

The liquid medium may be a mixture of at least one gaseous, liquid or solid phase, with each phase consisting of different phase elements (finite elements). The phase elements can be, in particular, particles, bubbles or agglomerates, so that the liquid medium is a suspension, emulsion, fluidized powder or mixture of powders, foam or a mixture of foams or colloid or a mixture of colloids. In particular, the liquid medium may also be a polymer or a mixture of polymers. For all of these liquid media, the aforementioned preferred embodiment provides both local and global effects on the liquid medium.

It is advisable to excite vibrations of selectively different types of elements of a liquid medium. So, here problem areas can be processed locally and / or globally. Such problem areas are, for example, nozzles or dead volumes. For nozzles, for example, when using an untreated liquid medium with its real rheological properties, i.e. not changed due to vibration into effective rheological properties, a high pressure gradient arises, which can be significantly reduced when using a liquid medium with effective, i.e. Rheological properties altered by vibration. As another example, dead volumes in the fluid to be treated can be revitalized by the targeted action of vibrations.

Mostly selective excitation of vibrations occurs in a whole group of elements or in several groups of elements.

In accordance with one particularly preferred implementation of the invention, the excitation of vibrations occurs through at least one source of mechanical vibrations, which acts on a liquid medium. This ensures that various vibrations with different amplitudes and different frequencies are introduced into the liquid medium. Thus, in the selected zones due to the imposition of various vibrations, extremely high vibration amplitudes can be achieved in a liquid medium.

The oscillations can be created in this case partially pneumatically and / or partially hydraulically. In particular, mechanical oscillation due to jerk excitation, in particular several successive jog excitations, is also preferable. Shock jitter excitation corresponds to the superposition of so many different vibrational frequencies, so that due to jog excitation, resonance oscillations can be excited in a very wide frequency range, which can also be maintained for a long period of time due to successive jog excitations.

Particularly preferably, if the source of mechanical vibrations is at least one boundary surface of the part of the installation or machine. Thus, less detail is required, and nevertheless, a targeted effect on the liquid medium can occur.

Advantageously, the at least one oscillatory boundary surface comprises at least one oscillation component in the tangent plane of the wall / liquid medium boundary surface.

Thus, it is possible to reduce or control the friction of the liquid medium against the wall due to the fact that they cause a targeted sliding effect. The required, if necessary, change or adjustment of the wall material to special liquid media therefore disappears. Instead, by selecting the frequency and / or amplitude of the vibration component, a controlled coefficient of friction can be created between the wall and the fluid.

It is also particularly advantageous if at least one boundary surface has an oscillation component perpendicular to the tangent plane of the wall / liquid medium boundary surface. Due to this perpendicular component, the oscillations of the boundary surface can introduce a lot of vibrational energy into the volume of the liquid medium. Thus, in particular, due to the combination of the tangent and normal components of the oscillation of the boundary surface of the wall / liquid medium, it is possible to create an extremely targeted and specific input of vibrational energy into the liquid medium.

In another preferred embodiment of the method according to the invention, the excitation of vibrations occurs through at least one source of electromagnetic waves that act on a liquid medium. Due to the excitation of electromagnetic vibrations, a milder effect on the liquid medium occurs, and the excitation of vibrations occurs mainly at the molecular level or at the level of small agglomerates, if they are talking about temporary or permanent dipoles, such as water molecules or surfactant molecules. When using several sources of electromagnetic waves, excitation with several frequencies or frequency ranges is also possible, and rotational vibrations in a liquid medium can be excited purposefully in various particles with a dipole character.

For a liquid medium, the boundary surface of the liquid medium / wall may be a wall for transporting the liquid medium of the line or the surface of the processing element of the liquid-processing machine.

In particular, we can talk about the boundary surface, which in addition to its oscillatory motion does not make any other movement. This is, for example, the case of a static mixer.

The boundary surface can, however, in addition to its oscillatory motion, perform at least one more movement, for example translational and / or rotational. Also, friction against the wall due to fluctuations in the boundary surface is reduced here. This is particularly advantageous in pipelines for transporting viscous liquid media or in dynamic mixers.

The method according to the invention can be applied in various flows of a liquid medium. So, the flow of a liquid medium can be an inertial flow, a pressure flow, a combination of inertial and pressure flows, an expanding flow, a shear flow, and also a cavitation flow.

A combination of expansion flow and vibration is particularly preferred. Already caused by the expanding course, deagglomeration is supported by vibration of the agglomerates. This synergism is particularly preferably realized in a vibrating splitting mill by superimposing expansion and vibration. Also, during deagglomeration by means of shear flow, the superimposed vibration is extremely useful, since this vibration counteracts the stratification of the deagglomerated particles along different layers of the flow in the laminar flow zones and thereby also prevents re-agglomeration of the crushed particles.

In another preferred embodiment of the method according to the invention, the excitation of oscillations occurs with the selected frequencies or frequency ranges, in particular in combination with the excitation of oscillations with the selected amplitudes or ranges of amplitudes. Due to this, you can cause a targeted and selective effect on various phase elements, such as particles, bubbles, aggregates, etc. by size, type, composition, form, etc. In particular, the selected excitation frequencies and amplitudes can also be brought into correspondence with a given degree of processing of a liquid medium, i.e. to this state of phase elements. So, for example, with the deagglomeration of particles, the excitation of ever smaller particles with increasing frequencies continues.

In particular, it is also preferable here to excite oscillations due to successive strokes, since a wide range of frequencies is introduced due to strokes in the liquid medium.

Advantageously, successive strokes can also be separated from each other by an interval of time of constant duration. Thus, after attenuation caused by the shock of the oscillations of the phase elements, this again ensures the excitation of the same oscillations of the phase elements with a larger initial amplitude.

Advantageously, successive strokes can also be separated from each other by a time interval of stochastic duration. Thus, this prevents the imposition of a fluid on the outside of periodic behavior. On the contrary, the excitation of oscillations caused by stochastic time intervals of consecutive impacts prevents the flow of a liquid medium into a steady state. This is especially preferred to prevent delamination. Instead of time intervals of stochastic duration, successive strokes can also be separated from each other by time intervals, the duration of which is normally distributed. Thus, it is possible to achieve a similarity of a compromise between actions with time intervals of constant duration and actions with time intervals of purely stochastic duration.

It is advisable that the selected frequencies or frequency ranges of the excited oscillations are the eigenfrequencies of certain types of phase elements corresponding to certain types of oscillation. As already mentioned, in this way it is possible to purposefully act on the phase elements of a certain type of quantity, composition or form.

As a support measure, at least one surfactant can also be introduced into the liquid medium in the method according to the invention. Due to this, it is possible, for example, to stabilize the deagglomeration of phase elements caused by the excitation of oscillations. It is especially preferred if at least one surfactant is added to it for various phase elements of the liquid medium. Thanks to the accompanying process, coordinated by place and time, the use of various types of excitation of vibrations and various surfactants, it is possible to optimize a variety of processes.

Claims (78)

1. A method of influencing the rheological properties of a liquid medium, which is a mixture of at least one gaseous, liquid or solid phase, which consists of various phase elements and is in interaction with at least one corresponding part of the installation or boundary machine surface, and excite vibrations of at least part of the liquid medium forming elements of the liquid medium, characterized in that the liquid medium is a suspension, and the vibrations of various types of elements of the liquid medium in Selectively excite, and at least one boundary surface has an oscillation component perpendicular to the tangent plane of the wall / liquid boundary surface. 2. The method according to claim 1, characterized in that the oscillations of the elements of the liquid medium are excited in certain areas of the liquid medium. 3. The method according to claim 1, characterized in that the phase elements are at least one type of elements from the group consisting of elements of particles, bubbles and agglomerates. 4. The method according to claim 3, characterized in that the oscillations of one or more groups of elements excite selectively. 5. The method according to claim 1, characterized in that the excitation of the vibrations occurs through at least one source of mechanical vibrations acting on the liquid medium. 6. The method according to claim 5, characterized in that the oscillations create at least partially pneumatically. 7. The method according to claim 5 or 6, characterized in that the oscillations create at least partially hydraulically. 8. The method according to claim 5, characterized in that the mechanical oscillation occurs due to shock excitation. 9. The method according to claim 7, characterized in that the mechanical vibration occurs due to shock excitation. 10. The method according to claim 8 or 9, characterized in that there are several consecutive jogging excitations. 11. The method according to one of paragraphs.5, 6, 8 and 9, characterized in that the source of mechanical vibrations is at least one boundary surface of the part of the installation or machine. 12. The method according to claim 7, characterized in that the source of mechanical vibrations is at least one boundary surface of a part of the installation or machine. 13. The method according to claim 10, characterized in that the source of mechanical vibrations is at least one boundary surface of a part of the installation or machine. 14. The method according to claim 1, characterized in that the excitation of the oscillations occurs through at least one source of electromagnetic waves acting on the liquid medium. 15. The method according to claim 1, characterized in that the boundary surface for the liquid medium is the wall of the line for transporting the liquid medium. 16. The method according to claim 1, characterized in that the boundary surface for the liquid medium is the wall and / or surface of the processing element of the liquid processing machine. 17. The method according to claim 1, characterized in that the boundary surface performs only oscillatory motion. 18. The method according to p. 15 or 16, characterized in that the boundary surface in addition to its oscillatory movement makes at least one more movement. 19. The method according to p, characterized in that at least one additional movement of the boundary surface is a translational movement. 20. The method according to p. 18, characterized in that at least one additional movement of the boundary surface is a rotational movement. 21. The method according to claim 19, characterized in that at least one additional movement of the boundary surface is a rotational movement. 22. The method according to p. 18, characterized in that the boundary surface in addition to its oscillatory motion performs both translational and rotational motion. 23. The method according to claim 20 or 21, characterized in that the boundary surface in addition to its oscillatory movement performs both translational and rotational movements. 24. The method according to p. 15, characterized in that they create an inertial flow of a liquid medium. 25. The method according to clause 15, characterized in that create a pressure flow of the liquid medium. 26. The method according to clause 15, characterized in that they create a combination of inertial and pressure flows of a liquid medium. 27. The method according to p. 15, characterized in that they create an expanding flow of a liquid medium. 28. The method according to clause 15, characterized in that it creates a shear flow of a liquid medium. 29. The method according to p. 15, characterized in that they create a cavitational flow of a liquid medium. 30. The method according to claim 1, characterized in that the excitation of oscillations occurs with the selected frequencies or frequency ranges. 31. The method according to claim 1, characterized in that the excitation of oscillations occurs with the selected amplitudes or ranges of amplitudes. 32. The method according to claim 1, characterized in that the excitation of oscillations occurs due to successive strokes. 33. The method according to p, characterized in that successive strokes are separated from each other by time intervals of constant duration. 34. The method according to p, characterized in that successive strokes are separated from each other by time intervals of stochastic duration. 35. The method according to p, characterized in that successive strokes are separated from each other by time intervals of a normally distributed duration. 36. The method according to claim 1, characterized in that the excitation of vibrations occurs with the selected amplitudes or ranges of amplitudes. 37. The method according to p. 30, characterized in that the selected frequencies are corresponding to certain types of oscillations of the natural frequencies of certain types of phase elements. 38. The method according to claim 1, characterized in that at least one surfactant is introduced into the liquid medium. 39. The method according to p. 27, characterized in that for various phase elements of the liquid medium, at least one surfactant is introduced into it. 40. A method of influencing the rheological properties of a liquid medium, which is a mixture of at least one gaseous, liquid or solid phase, which consists of various phase elements and is in interaction with at least one corresponding part of the installation or boundary machine surface, and excite vibrations of at least part of the liquid medium forming elements of the liquid medium, characterized in that the liquid medium is a polymer or a mixture of polymers, and vibrations of various types of eleme comrade selectively excite liquid medium, wherein at least one boundary surface of a component of oscillations in the tangential plane boundary wall / fluid surface. 41. The method according to p, characterized in that the oscillations of the elements of the liquid medium are excited in certain areas of the liquid medium. 42. The method according to p, characterized in that the phase elements are at least one type of elements from the group consisting of elements of a particle, bubbles and agglomerates. 43. The method according to § 42, wherein the oscillations of one or more groups of elements excite selectively. 44. The method according to p, characterized in that the excitation of the vibrations occurs through at least one source of mechanical vibrations acting on the liquid medium. 45. The method according to item 44, wherein the oscillations create at least partially pneumatically. 46. The method according to item 44 or 45, characterized in that the oscillations create at least partially hydraulically. 47. The method according to item 44, wherein the mechanical oscillation occurs due to shock excitation. 48. The method according to item 46, wherein the mechanical oscillation occurs due to shock excitation. 49. The method according to claims 47 or 48, characterized in that several consecutive jerky excitations occur. 50. The method according to one of paragraphs.44, 45, 47 and 48, characterized in that the source of mechanical vibrations is at least one boundary surface of the part of the installation or machine. 51. The method according to item 46, wherein the source of mechanical vibrations is at least one boundary surface of a part of the installation or machine. 52. The method according to 49, characterized in that the source of mechanical vibrations is at least one boundary surface of the part of the installation or machine. 53. The method according to p, characterized in that the excitation of vibrations occurs through at least one source of electromagnetic waves acting on a liquid medium. 54. The method according to p, characterized in that the boundary surface of the liquid medium is the wall of the line for transporting the liquid medium. 55. The method according to p, characterized in that the boundary surface of the liquid medium is the wall and / or surface of the processing element of the liquid processing machine. 56. The method according to p, characterized in that the boundary surface performs only oscillatory motion. 57. The method according to item 54 or 55, characterized in that the boundary surface in addition to its oscillatory movement makes at least one more movement. 58. The method according to clause 57, wherein the at least one additional movement of the boundary surface is translational motion. 59. The method according to clause 57, wherein the at least one additional movement of the boundary surface is a rotational movement. 60. The method according to p, characterized in that at least one additional movement of the boundary surface is a rotational movement. 61. The method according to clause 57, wherein the boundary surface in addition to its oscillatory motion performs both translational and rotational motion. 62. The method according to p. 59, characterized in that the boundary surface in addition to its oscillatory motion performs both translational and rotational movements. 63. The method according to item 54, wherein creating an inertial flow of a liquid medium. 64. The method according to item 54, wherein creating a pressure flow of a liquid medium. 65. The method according to item 54, wherein creating a combination of inertial and pressure flows of a liquid medium. 66. The method according to item 54, wherein creating an expanding flow of a liquid medium. 67. The method according to item 54, wherein creating a shear flow of a liquid medium. 68. The method according to item 54, wherein the cavitational flow of a liquid medium is created. 69. The method according to p, characterized in that the excitation of vibrations occurs with the selected frequencies or frequency ranges. 70. The method according to p, characterized in that the excitation of the vibrations occurs with the selected amplitudes or ranges of amplitudes. 71. The method according to p, characterized in that the excitation of oscillations occurs due to successive strokes. 72. The method according to p, characterized in that successive strokes are separated from each other by time intervals of constant duration. 73. The method according to p, characterized in that successive strokes are separated from each other by time intervals of stochastic duration. 74. The method according to p, characterized in that successive strokes are separated from each other by time intervals of a normally distributed duration. 75. The method according to p, characterized in that the excitation of oscillations occurs with the selected amplitudes or ranges of amplitudes. 76. The method according to p, characterized in that the selected frequencies are corresponding to certain types of oscillations of the natural frequencies of certain types of phase elements. 77. The method according to p, characterized in that at least one surfactant is introduced into the liquid medium. 78. The method according to p, characterized in that for various phase elements of a liquid medium, at least one surfactant is introduced into it.