WO1999030580A1 - Method and device for improving the efficiency of active agents consisting at least of mineral substances - Google Patents

Abstract

According to the inventive method for improving the efficiency of active agents, said active agents contain at least one mineral substance. Said mineral substances are subjected to a tribomechanical activation process during which the surface of the active agents being treated increases and their structure is destabilised in order to increase the chemical potential. By destabilising the structure, it is possible to increase the capacity of the active agents for exchanging ions with ions of other agents. In order to destabilise their structure, the active agents are subjected to the effects of kinetic energy. They are influenced mutually, non-plastically through the action of the kinetic energy. The invention also relates to a device for improving the efficiency of mineral substances which are destined for human consumption. At least three series of ring elements are driven in mutual opposition in order to tribomechanically activate the mineral substances, blade-type projections being fixed on each of said ring series.

Description

Method and device for improving the effectiveness of active substances which consist at least of minerals

Description:

The invention relates to a method for improving the

Efficacy of active ingredients that consist at least of minerals.

In addition, the invention relates to a device for improving the effectiveness of active ingredients from minerals suitable for human consumption.

The invention also relates to a powder made of zeolites for human consumption.

It has been confirmed by experiments that zeolites have a positive effect on the metabolism of living beings, namely both plants and animals and humans. Such minerals are therefore also used as a food additive for humans. The effect of these food additives clearly shows that their consumption can improve the quality of life.

The object of the present invention is therefore to specify methods, devices and products with the aid of which a replacement of chemical products in the field of human nutrition is possible.

This object is achieved in that, in the process for improving the effectiveness of active ingredients which consist at least of minerals, the active ingredients are subjected to tribomechanical activation, in which the surface of the treated active ingredients is enlarged and their structure is destabilized to increase the chemical potential. In the device for improving the effectiveness of active substances from minerals suitable for human consumption, at least three rows of rings are driven in opposite directions for the tribomechanical activation of the minerals, and blade-like projections are fastened on each ring row.

This device is capable of tribochemically activating minerals so that they have a much wider range of possibilities for interfering with human life processes than before. This activation consists in mechanically interfering with the integrity of the crystal lattice present in the mineral substances. This results in damage which is also noticeable externally in the form of an activation, for example of an electrical type.

According to a further preferred embodiment of the invention, a powder made of zeolites for human consumption has a grain size of less than 20 μm and is activated by tribomechanics. Such a powder has a very far-reaching influence on the well-being of a person. Among other things, it strengthens the immune system against certain types of cancer, for example lung cancer, colon cancer, skin cancer and the like. a. In addition, it stabilizes the blood circulation and leads to a significant improvement in venous tension and the permeability of the veins. It also achieves success in the remediation of rheumatic diseases and has a positive diaretic effect and a revitalization of the kidney function. Finally, it is successfully used in the rehabilitation of periodontitis by adding toothpaste. It eliminates stressful situations, neuroses and sleep disorders. A variety of other fields of application are known.

Further details of the invention will become apparent from the following detailed description and the accompanying Drawings in which preferred embodiments of the invention are exemplified.

The drawings show:

FIG. 1: a side view of an activator,

FIG. 2: a side view of a runner, consisting of three rows of rings,

FIG. 3: a plan view of a rotor according to the section line III-III in FIG. 2,

FIG. 4: an enlarged partial section of three rows of wreaths arranged side by side,

FIG. 5: a system sketch of a silo and wind screening system,

Figure 6: a system sketch of a cross flow classifier and

Figure 7: a system sketch of a classification line with cross flow classifier.

The centerpiece of a system 1 for activating active substances is an activator 2 in which the active substance is mechanically activated by intensive mechanical stress and thus by material breakage (tribomechanical activation). These activations are a result of the action of impact and / or friction, the particles 3 of which are to be activated. These effects result in spatial disturbances and the associated energetic disturbances of atomic and molecular structures, errors in the structure of the crystal lattice, deformations of the crystal lattice, breakage of the connections, installation in the lattice, formation of free radicals and electrons, an increase in displacements etc. Shattering the material body or grain.

Such disturbances occur in a very short time span of 10 ³ to 10 ° sec. In surface layers of the particles 3. Secondary effects penetrate very deeply into the particles. These disturbances put the particles in an activated state. Such activated particles 4 have a free energy that appears to the outside world, which manifests itself in a very wide range in activity, for example as chemical binding energy. This enables the creation of new compositions and reactions that would otherwise only be possible with large pressure applications. The activated state of such particles 4 can be proven both by physical methods as well as by X-ray radiography and by morphological examinations.

Reactions based on such a tribomechanical activity follow different laws than thermodynamically determined transformations. They are largely independent of the temperature. The reaction rate depends rather on the intensity of the mechanical load and the activity achieved thereby.

The particles 3 to be activated and thus also the activated particles 4 are mostly of mineral origin. Zeolites are particularly suitable for the production of active ingredients for human consumption. In the agricultural sector, calcite is very often activated and used for the production of fertilizers.

When the minerals are activated, the surface of the treated active ingredients is enlarged and their structure destabilized to increase the chemical potential. This increases the capacity of the active substances to exchange ions with ions of other substances. When the kinetic energy is applied to the individual particles 3, these mutually influence one another by means of non-plastic deformation. This converts the kinetic energy into an energy of molecular motion.

In order to achieve this effect optimally, the active ingredient has a granolometry of 0 to 20 μ. This granolometry depends on at least one influencing variable. It can be determined depending on a size of the starting grain 3. In addition, it can be dependent on the degree of acceleration with which the active substance is acted on. Further influencing variables for the granolometry are the collision angle at which the particles 3 collide. Finally, the granolometry also depends on the intensity of the friction with which the individual particles 3 rub against one another. In addition, the granolometry can also depend on the number of collisions with which particles 3 meet each other.

The particles 3 have a grain size of 0 to 4.0 mm and enter an inlet funnel 5 into a central part 6 of the activator 2. This consists of two rotors 7, 8, of which the rotor 7 is smaller than the rotor 8. The large rotor 8 has two rings 9, 10 arranged parallel to one another, of which the ring 9 as the inner ring is directly adjacent to the central part 6 in the direction of a circumference 11 of the rotors, while the outer ring 10 is adjacent to the outer circumference 1 of the rotor 8 is.

Arranged between the inner ring 9 and the outer ring 10 is a ring 12 fastened to the smaller rotor 7, the inner edge 13 of which is directly adjacent to an outer edge 14 of the inner ring 9. In a corresponding manner, an outer edge 15 of the ring 12 adjacent to the outer ring 10 is an inner edge facing the central part 6

16 facing the outer ring 10. Only very close fits are provided between the individual edges 13, 14, 15, 16, so that the particles 3 to be activated can be passed without difficulty from the central part 6 via the individual rings 9, 10, 11 to the outer circumference 11 of the large rotor 8 can reach.

The large rotor 8 is fastened on a shaft 17, by means of which it is rotated. In contrast, the small rotor 7 is fixed on a shaft 18 which is connected to the shaft

17 escapes. The two shafts 17, 18 are driven that the rings 9, 10 rotate in a different direction of rotation than the ring 12. This ensures that the particles 3 coming from the central part 6 onto the ring 9 of the large rotor 8 are accelerated in the direction of rotation 19. This gives them, among other things, a centrifugal acceleration in the direction of the ring 12 of the small rotor 7. As soon as they cross the inner edge 13 of the ring 12 during their migration, they are initially at a speed within a very short time of 10 ^" to 10 seconds 0 braked and then accelerated in the direction of rotation 20 due to the rotational speed inherent in the crown 12. This gives them, among other things, centrifugal acceleration in the direction of the crown 10 of the large rotor 8. As soon as they pass the crown 12 of the small rotor 7 exceed inner edge 16 of the ring 10, they are in turn decelerated to a speed 0 within very short periods of time and then accelerated in a very short time in the direction of rotation 19 of the ring 10.

During this movement of the particles 3 via the rotors 7, 8, not only considerable accelerations occur in the individual particles 3, but also collisions of the individual particles 3 with one another. Despite the very small mass of the particles 3, they meet with a large force in view of the high accelerations, so that non-plastic deformations occur in the particles 3. These lead to the desired activation of the particles 3, so that they finally leave the outer ring 10 of the large rotor 8 on the circumference 11 as activated particles 4.

Fan blades 21 are attached to the rings 9, 12, 10, each of which favors acceleration of the particles 3 to be activated in the desired direction. Thus, the fan blades 21 each run in the longitudinal direction 22, in which in the direction of rotation of the individual rings 9, 12, 10 the longitudinal direction 22 is arranged obliquely to the direction of rotation 23 of the individual rings 9, 12, 10, specifically in the manner that a rear edge 24 provided on the rear of each fan blade 21 in the direction of rotation 23 faces an area smaller and an opposite front edge 25 faces an area of higher rotational acceleration. In this way, the particles 3 passing between two fan blades 21 adjacent to one another on a ring 9, 11, 10 receive an acceleration in the direction of the next larger ring 11, 10. Depending on the desired activation of the particles 3, there is a rotation between 19, 20 of the respective ring 9, 12, 10 and a direction 26 an angle 27 is fixed, with the aid of which the appropriately aligned fan blades 21 bring about an optimal acceleration of the particles 3.

In addition, a deflector part 28 can also be fastened to the fan blades 21 of the outer ring 10, said deflector part being connected to the corresponding fan blade 21 in a predetermined direction. The deflector part 28 has a direction directed towards the circumference 11, which maintains an angle 29 to be defined with the direction of the fan blade. In addition, the deflector part 28 has a precisely defined length 30, which either extends to the circumference 11 of the outer ring 10 or even beyond. The length of a part 31 projecting beyond the circumference 11 can be calculated such that at its end 32 projecting beyond the circumference 11 the activated particles 4 each have the desired signs of detachment.

The fan blades 21 can consist of one or more parts 33, depending on the desired activation. In this case, angles 34 can be provided between several parts 33 of a fan blade 21, the size of which influence the acceleration of the particles 3 to be achieved on a ring 9, 11, 10. Constellations are conceivable in which higher accelerations on the inner rings 9, 12 due to the fan blades 21 fastened there Particles are brought in as by the fan blades 21 which are fixed on the outer ring 11. This can achieve a streamlined guide 35 by multiple kinks, so that the mediated impact energy is comparatively low along these fan blades 21 fastened on the outer ring 11, but the acceleration of the particles 3 before leaving the outer circumference 11 is very high.

Especially in the case of the fan blades 21, which consist of several parts 33 arranged at an angle to one another, a stock 36 of particles accumulates between the individual parts 33 in the course of the rotation, which hardens there under the influence of the centrifugal acceleration constantly acting on them. This stock 36 forms a homogeneous sliding surface on which particles are deflected little but accelerated to a very high degree.

The activated particles 4 leaving the outer ring 10 via the circumference 11 collect in a housing 37 of the activator 2 surrounding the rotors 7, 8 and pass through an outlet 38 provided in this housing 37 to a foot station 39 of an elevator 40, in which the activated parts are sucked in due to a negative pressure generated in a negative pressure generator 41. They arrive in a distribution room 42, from which they can be called up as required.

The two shafts 17, 18 are each driven by motors 43, 44 in opposite directions of rotation. The motors are connected to the activator 2 via couplings 45, 46 and gears 47, 48. The rotors 7, 8 are overhung on the shafts 17, 18, which are each mounted in bearings of the gears 47, 48. The speed of at least one of the rotors 7, 8 can be changed by a controller 49, so that the rotors 7, 8 can be operated at the same as well as at different speeds. The activated particles 4 pass from the distribution space 42 via a funnel 50 into a classifier 51, in which they are classified according to their size. The use of a cross-flow classifier 52 has been found to be particularly favorable, in which the activated particles 4 are classed for coarse particles 53 and for finest-grain particles 54. The activated particles 4 enter this cross-flow classifier 52 in a mixture 55 of particles of all fractions through an inlet 56. They are sucked in an air stream 57 in the direction of a worm-like housing 58. This air flow 57 enters through an air tube 59. The mixture 55 loosens into the finest grain 54 and coarse grain 53. In addition, secondary air is blown into the housing 58 through a third inlet 60, which separates out the fine grain fractions 54. Finally, tertiary air 62 enters through a further opening 61, which again separates out fine particles 54 from the coarse fraction 53. The coarse particles 53 drop out of a lower opening 63 towards a collecting station.

In the housing 58, the fine fraction freed from the coarse particles 53 is accelerated upwards in a spiral. A further separation of the fractions takes place under the influence of centrifugal forces. Coarse particles circle along walls 64 of the housing 58 and finally reach the lower opening 63. In the process, parts of the fine fraction are carried along by the air flows of the air pipe 59 and the access 60 and passed to a centrifugal classification field 65. From there they reach its opening 66, from which they exit in the direction of cyclones 67, 68, 69, in which the finest particles are extracted from the fine fraction and transported in the direction of a filter bag 70. They are sucked into this by a vacuum pump 71, the pressure side of which is connected to the air pipe 59, the access 60 and to the opening 61. In this way, the cross-flow classifier 62, together with the cyclones 67, 68, 69 and the filter bag 70, forms a micro-classifier for separating the fine-grain particles 54. Tribomechanical excitation of calcites also creates a highly energetic active ingredient.

Claims

Claims: 1. A method for improving the effectiveness of active ingredients which consist of at least one mineral, characterized in that the active ingredients are subjected to a tribomechanical activation in which the surface of the treated active ingredients is enlarged and their structure is destabilized to increase the chemical potential. 2. The method according to claim 1, characterized in that the capacity of the active substances for the exchange of ions with ions of other substances is increased by the destabilization of the structure. 3. The method according to claim 1 or 2, characterized in that the destabilization of the structure with kinetic energy is acted on the active ingredients. 4. The method according to any one of claims 1 to 3, characterized in that the active ingredients are mutually unplastic influenced by the application of the kinetic energy. 5. The method according to claim 4, characterized in that the kinetic energy is converted into energy of the molecular movement. 6. The method according to any one of claims 1 to 5, characterized in that the active ingredient has a granolometry of 0 to 2 μ depending on at least one influencing variable. 7. The method according to claim 6, characterized in that the granolometry is determined as a function of a size of the starting grain. 8. The method according to claim 6 or 7, characterized in that the granolometry is determined depending on a degree of acceleration of the active ingredient. 9. The method according to any one of claims 6 to 8, characterized in that the granolometry is determined depending on a planned collision angle. 10. The method according to any one of claims 6 to 9, characterized in that the granolometry is determined depending on an intensity of friction. 11. The method according to any one of claims 6 to 10, characterized in that the granolometry is determined depending on the number of collisions. 12. The method according to any one of claims 7 to 11, characterized in that a grain size of 0.0 to 4.0 mm is determined for the starting material. 13. The method according to any one of claims 1 to 12, characterized in that active ingredients of human consumption are activated in an activator (2) equipped with four rotor rings (9, 10, 12). 14. The method according to claim 12 or 13, characterized in that at least one further component is added to the active ingredient as required. 15. The method according to any one of claims 12 to 14, characterized in that the active ingredient is sucked in by an air flow generated in the activator (2), taken over by a first ring (9) provided with fan blades (21), accelerated and accelerated for further acceleration to subsequent ones Wreaths (12, 10) is transferred, each subsequent one acting on the active ingredient by reversing the direction of movement (19, 20, 23). 16. The method according to claim 15, characterized in that on each ring (9, 12, 10) for reversing a movement direction inherent in the active ingredient (19, 20, 23) a longitudinal direction (22) of the fan blade (21) is fixed. 17. The method according to claim 16, characterized in that the longitudinal direction (22) of the fan blade (21) is determined in accordance with the respectively desired acceleration. 18. The method according to claim 16 or 17, characterized in that the direction of movement of the active ingredients on each wreath (9, 12, 10) is influenced according to a desired acceleration. 19. The method according to any one of claims 15 to 18, characterized in that from the active ingredient activated in the activator (2) is screened a portion suitable for further processing. 20. The method according to claim 19, characterized in that the screened portion has a grain size of at most 20.0 μ. 21. The method according to claim 19 or 20, characterized in that the screened portion is calmed in a cyclone. 22. The method according to any one of claims 19 to 21, characterized in that the screened portion is fed to a package. 23. The method according to any one of claims 20 to 22, characterized in that constituents with a particle size of greater than 20 μ are supplied for a further activation. 24. The method according to any one of claims 13 to 23, characterized in that zeolites are activated tribomechanically. 25. The method according to claim 24, characterized in that Klinoptilolythe are tribomechanically activated. 26. The method according to claim 24 or 25, characterized in that the activated active ingredients are packaged as a powder in capsules. 27. The method according to claim 24 or 25, characterized in that the activated active ingredients are packed mixed with liquid in capsules. 28. Device for improving the effectiveness of minerals suitable for human consumption, characterized in that for the tribomechanical activation of the minerals at least three rows of rings (85, 86, 87) are driven in opposite directions and on each of the rows of rings (85, 86, 87) blade-like projections are attached. 29. The device according to claim 28, characterized in that the blade-like projections depending on the direction of rotation of the respective row of rings (85, 86, 87) in the direction of the resulting on the ring row (85, 86, 87) centrifugal acceleration to the outside. 30. The device according to claim 28 or 29, characterized in that on at least one row of rings (85, 86, 87) the projections consist of fan blades (21) arranged at an angle to one another. 31. The device according to claim 30, characterized in that at least one of the fan blades (21) is oriented outwards in the direction of centrifugal acceleration and is set steeply with respect to this direction. 32. Apparatus according to claim 31, characterized in that the steeply adjusted fan blade (21) in the area of small centrifugal accelerations on the respective row of rings (9) is arranged. 33. Device according to one of claims 29 to 31, characterized in that the fan blades (21) at their respective large centrifugal accelerations exposed front edges (25) are angled several times against a direction of rotation of the row of rings (9, 12, 10). 34. Apparatus according to claim 33, characterized in that one of the parts (31) provided on the outer ends protrude beyond a circumference (11) of the row of rings (10). 35. Device according to one of claims 28 to 34, characterized in that the activator (2) consists of stainless steel. 36. Zeolite powder for curative consumption for humans, characterized in that it has a grain size smaller than 20 μ and is activated tribomechanically. 37. Powder according to claim 36, characterized in that it has a wide range of uses, ranging from the improvement of quality of life to the healing of ailments. 38. Powder according to claim 36 or 37, characterized in that it cures some cancers. 39. Powder according to one of claims 36 to 38, characterized in that it has a wide range of cosmetic applications. 40. Powder according to one of claims 36 to 39, characterized in that it serves to remedy stressful situations, neuroses and sleep disorders.