RU2568347C1 - Continuous loose material drying unit - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: in continuous loose material drying unit comprising heat insulated chamber, loose materials unloading and loading devices, drying agent supply and removal devices. The trays located in chamber by tiers one above another are connected with each other, the heat insulated chamber has vibrator and resilient elements secured on then base, and chamber is installed with possibility of spatial movement in three mutually perpendicular planes, and trays connected rigidly in single process train are made as hollow helical surfaces out of guide elements in form of three rectangular straps, twisted in vertical plane in the longitudinal direction relatively to its own axis of symmetry, then bent along the helical lines in transverse direction and bent at angle alternatively to opposite sides along notches made at angle 60° to each other , and to longitudinal edges of straps with creation along the strap length of the equiangular triangles located alternatively to opposite sides.

EFFECT: expansion of manufacturing capabilities.

16 dwg

Description

The invention relates to a device for drying bulk materials, for example, granular and bulk materials, in particular building bulk materials and may find application in chemical, pharmaceutical, food, animal feed and other industries.

A drying cabinet is known (AS USSR No. 1035365, class F26B 9/06, 1983) containing a heat-insulating chamber equipped with an unloading unit with a sealed pivot door and pallets for drying material installed in the chamber in a tiltable manner, while the chamber has unloading windows at the level of the bottoms of pallets.

A disadvantage of the known device is the low quality of drying and limited technological capabilities.

Closest to the proposed invention is a device for continuous drying of bulk materials (RF patent No. 2259526, publ. 08/27/2005. Bull. No. 24) containing a thermally insulated chamber, a device for loading and unloading the processed material, supply and output of a drying agent and installed in tiers the chamber pallets mounted for rotation under each other, communicated with each other and made in the form of drums in the form of tetrahedral columns mounted from individual perforated equilateral triangles.

A disadvantage of the known device is the complexity of manufacture and operation, limited technological ability.

The technical solution to the problem is to simplify manufacturing and operation, expand technological capabilities.

This object is achieved by the fact that in the installation for continuous drying of bulk materials containing a thermally insulated chamber, devices for loading and unloading bulk materials, supply and withdrawal of a drying agent, and pallets half-tucked in the chamber, mounted one under the other and communicated with each other, the thermally insulated chamber is provided a vibrator and elastic elements fixed to the base, and is installed with the possibility of spatial movement in three mutually perpendicular planes, and set in tier pallets connected one under the other and connected rigidly into a single technological chain are made in the form of hollow screw surfaces, rigidly mounted one under the other and communicated with each other, made of guide elements in the form of three rectangular strips twisted in a vertical plane in the longitudinal direction with respect to their own axis of symmetry , then bent along helical lines in the transverse direction and bent at an angle alternately in opposite directions along cuts made at an angle of 60 ° to each other y and to the longitudinal edges of the strips with the formation along the length of the strip of equilateral triangles located alternately in opposite directions, while the strips are connected at an angle to one another on the longitudinal edges at an angle with the formation along the inner perimeter of three broken helical surfaces and three broken helical grooves of the main directions for moving bulk materials from loading to unloading, as well as two broken curved helical surfaces and two helical grooves in the opposite direction, and three broken helical lines of the main direction and two broken helical lines of the opposite direction with a step four times smaller than the step of the broken helical lines of the main direction are formed along the outer diameter of the pallet, at the break points of the helical lines there are places of convergence of the sides of six equilateral triangles, while along the entire length pallets are mounted to move bulk materials from loading to unloading coil springs with a flat section of coils, which are equipped with a device for changing yeah turns by stretching or compressing them.

According to the patent literature not found a technical solution similar to the claimed, which allows to judge about the inventive step of the proposed design of the installation for continuous drying of bulk materials.

The novelty lies in the fact that the insulated chamber is equipped with a vibrator and elastic elements fixed to the base, and is installed with the possibility of spatial movement in three mutually perpendicular planes, which extends the technological capabilities and simplifies operation.

The novelty also lies in the fact that the pallets, which are mounted on one under one another and connected rigidly into a single technological chain, are made in the form of hollow hollow surfaces and are rigidly installed under each other and communicated with each other, made of guide elements in the form of three rectangular strips, which simplifies the manufacture and operation.

The novelty of the invention lies in the fact that during the operation of the vibration exciter, particles of bulk materials circulate inside the pallets rigidly fixed in the vibrating heat-insulating chamber, made in the form of hollow screw surfaces in planes perpendicular to their horizontal axes, receive additional movement from the inner surfaces of a polygonal shape, which intensifies the drying process of bulk materials, expands technological capabilities.

The novelty also lies in the fact that under the influence of the perturbing forces of the vibrator through the walls of the heat-insulating chamber, the particles of bulk materials rotate in planes perpendicular to the axis of symmetry of the pallets, made in the form of screw surfaces, while the screw surfaces change and give additional movement to the particles of bulk materials, provide increase productivity, and also move them from loading to outlet openings, expand technological capabilities.

The novelty is that the twisting of each strip along the cuts with beveled walls in the transverse-longitudinal direction, arranged in pairs at an angle to one another on both sides of the strips, provides additional surface curvature along the perimeter of the surface of the screw surfaces, which increases the difference between the angles of inclination of the vectors the movement of particles of bulk materials in adjacent sections of the surfaces of the helical surfaces, so the particles move along complex paths, increasing the number of collisions with each other and with the walls of the surface of the screw surfaces, which intensifies the drying process of bulk materials

The novelty is due to the fact that thanks to the internal helical surfaces of a polygonal shape around the perimeter of the helical surface, not only is the movement of particles of bulk materials from loading to unloading at a horizontal installation, but also expanding technological capabilities.

The novelty of the invention lies in the fact that when the exciter is operating, particles of particles of bulk materials that circulate inside screw surfaces that are rigidly fixed in the vibrating housing in planes perpendicular to their horizontal axes receive additional movement from the inner surfaces of a triangular shape, which increases the drying performance of bulk materials expands technological capabilities.

The novelty also lies in the fact that under the influence of the perturbing forces of the vibrator through the walls of the box, the particles of bulk materials rotate in planes perpendicular to the axis of symmetry of the screw surfaces, while the helical surfaces of a triangular shape change and give additional movement to the particles of bulk materials, provide improved heat transfer, increase productivity, and also move them from loading to unloading.

The novelty lies in the fact that such a design of pallets in the form of a helical surface allows for the axial movement of particles of bulk materials from loading to unloading with a horizontal axis of the screw surface, which simplifies operation.

The novelty lies in the fact that thanks to the broken inner screw pockets of a triangular shape, the vectors of the particle velocity of the components of bulk materials during their transportation from loading to unloading change, which increases productivity and expands technological capabilities.

The novelty of the proposal also lies in the fact that inside the screw surface there are formed helical surfaces in the form of broken perforated pockets of a triangular shape, which increases the drying performance of bulk materials and expands technological capabilities.

The novelty also lies in the fact that with the same diameters of the screw surfaces in the proposed design, the length of the path of the particles of the components of bulk materials, compared with the known designs of the screw surface is much larger, which makes it possible to reduce the dimensions of the screw surface, both in length and in diameter, it also improves productivity and expands technological capabilities.

The novelty is also due to the fact that the area and cross-sectional shape of the helical surface changes from loading to unloading, which changes the speeds and trajectories of the movement of particles of bulk materials as they move from loading to unloading, expanding technological capabilities.

The novelty is due to the fact that the helical surface is equipped with three broken helical lines of the main and two broken helical lines of the opposite direction, the pitch of which varies along the length of the screw surface and, accordingly, three broken helical grooves of the main and two helical grooves of the opposite direction inside the screw surface, which increases the frequency of interaction of particles of loose materials with each other and with the walls of the screw surface, increases the energy intensity and frequency of contacts action of the particles of bulk materials and expanding technological capabilities.

The novelty of the invention also lies in the fact that due to the fact that the shape and dimensions of the cross section having the shape of a polygon change repeatedly over the length of the screw surfaces, which provides multiple periodic compression of the masses of bulk materials, which increases the intensity of mixing, the energy intensity of the collisions and the intensity of heat transfer, expands technological capabilities provides a rational thermal regime of drying.

In addition, the novelty is due to the fact that the elements from which the screw surfaces are assembled are mounted at certain angles to each other, so the mixing intensity increases, since these elements, working as shelves, capture portions of bulk material, direct them towards each other, on moving on the opposite side of the wall of the screw surfaces, violating, thus, not only the stationarity of their movement, but also providing intensive heat transfer and the expansion of technological capabilities.

The novelty is seen in the fact that the area and cross-sectional shape of screw surfaces varies in each of its cross-sections from loading to unloading, which intensifies the mixing process, increases the energy intensity of the interaction of material particles with each other and with the walls of screw drums, and expands technological capabilities.

The novelty is also due to the fact that the triangles of the sides of the screw surfaces are mounted at certain angles to each other with the formation of broken helical lines, which increases the miscibility, energy intensity and changes the frequency of interaction of the particles of the material with each other and with the surface walls of the screw surfaces, which intensifies heat transfer, expands technological capabilities.

The novelty also lies in the fact that the cross-sectional cross-section of the helical surface has the shape of a polygon, the area of which varies many times in length from loading to unloading, providing periodic compression of the masses of bulk materials, which increases the intensity of mixing and heat transfer, expands technological capabilities.

The novelty of the invention lies in the fact that along the perimeter the surface of the screw drums along the entire length has a variable not only transverse, but also longitudinal section, which intensifies heat transfer processes and expands technological capabilities.

The novelty of the invention lies in the fact that such a design around the surface of the screw surfaces allows for a sequence of gradual compaction and discharge of flows of bulk materials as they move from loading to unloading, which increases the heat transfer process, providing an increase in the drying speed and an increase in technological capabilities.

The novelty is also seen in the fact that the cross-sectional and longitudinal cross-sectional areas of screw surfaces change over their entire length many times from loading to unloading, which changes the speeds and trajectories of the movement of particles of bulk materials, expands technological capabilities, and increases the intensity of heat transfer.

The novelty also lies in the fact that along the perimeter of the surface of the screw surfaces, planar triangles are formed that are directed towards each other at an angle, but also towards its axis of rotation, which provides a violation of the stationary flow of bulk materials, expands technological capabilities.

The novelty lies in the fact that along the perimeter of the surfaces of the screw surfaces, broken helical lines are formed, directed towards each other, which intensifies the processes of movement of bulk materials towards each other, extends the technological capabilities.

The invention is illustrated by drawings, where: in FIG. 1 shows an installation for continuous drying of bulk materials, general view; in FIG. 2 is a section Α-A in FIG. one; in FIG. 3 is a view A in FIG. one; in FIG. 4 is a view B in FIG. one; in FIG. 4 - design of one of the pallets, made in the form of a helical hollow surface, General view; in FIG. 6 is a view B in FIG. 5; in FIG. 7 - part of one of the three strips with the marking of straight fold lines; in FIG. 8 is a cross-section TT in FIG. 7; in FIG. 9 - part of one of the three strips after twisting in a vertical plane in the longitudinal direction relative to its own longitudinal axis; in FIG. 10 is a view of a portion of one of the three strips curved along a helical line in the transverse direction after bending on a mandrel, and bent along notches with beveled walls; in FIG. 11 is a section FF in FIG. 10; in FIG. 12 - remote element 1 in FIG. 5; in fig. 13 is a cross-section E-Ε in FIG. 5; in FIG. 14 is a section FJ in FIG. 5; in FIG. 15 is a section 3-3 in FIG. 5; in FIG. 16 is a section KK in FIG. 5.

Installation for continuous drying of bulk materials (Fig. 1, Fig. 2, Fig. 3, Fig. 4) contains a heat-insulating chamber 1, devices for loading 2 and unloading 3 bulk materials, a drying chamber 4, an exhaust pipe 5, air ducts 6 of the fan ( not shown) through which the heat agent is supplied to the drying chamber 4. The heat-insulating chamber 1 is made of two sheets of material with packing insulated inside the heat insulation 7. In the heat-insulating chamber 1, pallets 8,9,10 are mounted one under the other, rigidly mounted one under the other and connected rigidly in one technological chain. The output end hole 11 of the pallet 8 is closed by a heat-insulating cover 12, which simultaneously covers the inlet 13 of the pallet 9 and allows the bulk material to move from the upper pallet 8 to the middle pallet 9, more precisely, from the outlet 11 of the pallet 8 to the inlet 13 of the pallet 9.

The outlet 14 of the pallet 9 is closed by a heat-insulating cover 15, which simultaneously covers the inlet 16 of the pallet 10, allowing bulk materials to be transferred from the middle pallet 9 to the lower pallet 10. A discharge device 3 is mounted under the outlet 17 of the pallet 10.

The heat-insulated chamber 1 is equipped with a vibrator 18 and elastic elements 19, mounted on the base 20, and is installed with the possibility of spatial movement in three mutually perpendicular planes.

Pallets 8, 9.10 are made in the form of hollow screw surfaces (Fig. 1, Fig. 2, Fig. 5, Fig. 6) and each is made (Fig. 6) of three rectangular strips 21, 22, 23 with the formation along the outer the perimeter of the helical surface, for example 8 (Fig. 5) of three helical lines 24-25-26-27-28; 29-30-31-32-33; 34-35-36-37-38 and along the inner perimeter of the helical surface 8 (Fig. 6,) of three broken helical grooves K ₁ , K ₂ , K ₃ . On all strips 21,22,23 (Fig. 7)) at an angle of 60 ° to the longitudinal edges 39 and 40, cuts 41 and 42 with beveled walls are alternately made from opposite sides with beveled walls, for example, on strip 21 (Fig. 8), located in pairs under angle to one another by milling, pressure machining, etc. with the formation of equilateral triangles 43.

, ψ, φ, β скосов надрезов 41 и 42 (фиг. 8) и их взаимное расположение определяют углы наклона равносторонних треугольников 43 друг к другу по периметру поддона 8-винтовой поверхности 8. Полосы 21, 22, 23 свернуты в вертикальной плоскости (фиг. 9) в продольном направлении относительно собственной оси симметрии полосы, а затем изогнуты по винтовым линиям в поперечном направлении (фиг. 10) и согнуты по надрезам 41 и 42 со скошенными стенками в поперечно-продольном направлении, расположенными попарно под углом один к другому с обеих сторон полос, как, например, полоса 21 на фиг. 9 и фиг. 10. На рис. 9 показана одна из полос, например 21, скрученная в вертикальной плоскости вдоль своей продольной оси с боковыми кромками 39 и 40. Предварительно скрученную в вертикальной плоскости относительно продольной оси полосу, например 21, помещают на оправку 44 (фиг. 10, фиг. 11) и изгибают так, чтобы кромки 39 и 40 разместились по винтовым линиям и в поперечном направлении. После изгиба в поперечном направлении каждая из полос 21, 22, 23 повернута относительно продольной оси винтовой поверхности 8 так, что их кромки образуют и в поперечном направлении полос винтовые линии с одинаковым шагом для всех полос. После этого полосу 21 снимают с оправки 44 либо фиксируют на оправке 44. Аналогичным образом обрабатывают остальные полосы, например 22 и 23. После сгиба полос, например, полосы 21 (фиг. 9) надрезы 25-34, 34-26, 26-35, 35-27, 27-36, 36-28, 28-37 сваривают и в результате образуются ребра жесткости. После сгиба полосы 21, 22, 23 соединяют одна с другой по продольным кромкам 39 и 40 с образованием винтовой поверхности-поддона. Такое соединение трех полос 21, 22, 23, становится возможным, так как после сгиба полос 21,22,23 по прямым линиям сгиба 41 и 42 под углом попеременно друг к другу в противоположные стороны (фиг. 9, фиг. 10) на полосе образуются грани в виде равносторонних треугольников 43 (фиг. 7), расположенных на полосе попеременно в противоположные стороны с образованием по продольным кромкам полос 21.22,23, точнее по наружному периметру винтовой поверхности 8 трех ломанных винтовых линий основного направления 24-25-26-27-28; 29-30-31-32-33; 34-35-36-37-38 с шагом S, одна из которых показана на фиг. 5 утолщенной линией 24-25-26-27-28 и двух ломанных винтовых линий противоположного направления 33-37-27-31-35-25 и 38-28-32-36-35-30-34, одна из которых на рис. 8 показана утолщенной линией 33-37-27-31-35-25 с шагом 0,25 S. На фиг. 5 показана утолщенной линией 24-25-26-27-28 одна из трех ломанных винтовых линий основного направления с шагом S, в каждой из точек излома которой в вершинах ломанных винтовых линий основного направления (фиг. 5, фиг. 12) расположены места схождения сторон шести равносторонних треугольников T₁, Т₂, Т₃, Т₄, Т₅, Т₆. Например, в точке 27 (фиг. 12 сходятся стороны 45, 46, 47, 48, 49, 50 шести равносторонних треугольников T₁, Т₂, Т₃, Т₄, Т₅, Т₆. Соединение полос 21, 22, 23.может быть осуществлено известными методами, например, сваркой.Geometry and angles λ, φ, $$\stackrel{/}{\omega }$$

, ψ, φ, β of the bevels of the notches 41 and 42 (Fig. 8) and their relative position determine the angles of inclination of equilateral triangles 43 to each other along the perimeter of the pallet of the 8-screw surface 8. The strips 21, 22, 23 are folded in a vertical plane (Fig. .9) in the longitudinal direction relative to the axis of symmetry of the strip, and then bent along helical lines in the transverse direction (Fig. 10) and bent along notches 41 and 42 with beveled walls in the transverse-longitudinal direction, arranged in pairs at an angle to one another both sides of the strips, such as TVOC 21 in FIG. 9 and FIG. 10. In fig. 9 shows one of the strips, for example 21, twisted in a vertical plane along its longitudinal axis with side edges 39 and 40. A strip, for example 21, previously twisted in a vertical plane relative to the longitudinal axis, is placed on the mandrel 44 (Fig. 10, Fig. 11) and bend so that the edges 39 and 40 are placed along helical lines and in the transverse direction. After bending in the transverse direction, each of the strips 21, 22, 23 is rotated relative to the longitudinal axis of the screw surface 8 so that their edges also form helical lines in the transverse direction of the strips with the same pitch for all strips. After that, the strip 21 is removed from the mandrel 44 or fixed on the mandrel 44. The remaining strips, for example 22 and 23, are processed in a similar way. After the bands are folded, for example, the strip 21 (Fig. 9), cuts 25-34, 34-26, 26-35 , 35-27, 27-36, 36-28, 28-37 are welded and stiffeners are formed as a result. After bending, the strips 21, 22, 23 are connected to each other along the longitudinal edges 39 and 40 with the formation of a helical surface-pallet. Such a connection of the three strips 21, 22, 23 becomes possible, since after bending the strips 21,22,23 along the straight lines of the fold 41 and 42 at an angle alternately to each other in opposite directions (Fig. 9, Fig. 10) on the strip faces are formed in the form of equilateral triangles 43 (Fig. 7) located on the strip alternately in opposite directions with the formation along the longitudinal edges of the strips 21.22,23, more precisely along the outer perimeter of the helical surface of 8 three broken helical lines of the main direction 24-25-26-27 -28; 29-30-31-32-33; 34-35-36-37-38 in increments of S, one of which is shown in FIG. 5 with a thickened line 24-25-26-27-28 and two broken helical lines of the opposite direction 33-37-27-31-35-25 and 38-28-32-36-35-30-34, one of which is in fig. . 8 is shown by a thickened line 33-37-27-31-35-25 in increments of 0.25 S. FIG. Figure 5 shows the thickened line 24-25-26-27-28 one of the three broken helical lines of the main direction with step S, at each of the break points of which at the vertices of the broken helical lines of the main direction (Fig. 5, Fig. 12) there are places of convergence sides of six equilateral triangles T ₁ , T ₂ , T ₃ , T ₄ , T ₅ , T ₆ . For example, at point 27 (Fig. 12, the sides 45, 46, 47, 48, 49, 50 of six equilateral triangles T ₁ , T ₂ , T ₃ , T ₄ , T ₅ , T ₆ converge. Connection of the bands 21, 22, 23 . may be carried out by known methods, for example by welding.

In the heat-insulating chamber, the screw surfaces 8, 9, 10 are fixed rigidly without the possibility of rotation, while the direction of the three helical lines of the main direction of the underlying screw surfaces is opposite to the direction of the three helical lines of the main direction above the fixed helical surfaces. For example, the direction of three helical lines of the main direction of the pallet 9 is opposite to the direction of three helical lines of the main direction of the pallet 8, respectively, the direction of three helical lines of the main direction of the pallet 10 is opposite to the direction of three helical lines of the main direction of the pallet 9.

In such a construction, along the length of the pallet — screw surface, each cross section — the passage section differs from the previous one not only in the shape of the section (FIG. 13, FIG. 14, FIG. 15, FIG. 16), but also in their location relative to each other, the cross-sectional area also changes, which violates the stationary motion of particles of bulk materials, increases the intensity of their interaction, and expands technological capabilities. In this design of the helical surface, three broken helical grooves of the main direction Κ ₁ - (24-25-26-27-28) are formed along the inner perimeter; K ₂ - (29-30-31-32-33; K ₂ - (34-35-36-37-38) with step S (Fig. 13, Fig. 14, Fig. 15, Fig. 16) and two broken screw grooves of the opposite direction K ₄ - (33-37-27-31-35-25) and K ₅ - (38-28-32-36-35-30-34) with a step of 0.25 S, one of which K _{4 is} shown in Fig. 5 by a thickened line 33-37-27-31-35-25.These grooves not only prevent the movement of particles of bulk materials from loading to unloading, but also provide intensive mixing, increase the intensity of their interaction, expand technological capabilities .

Moreover, along the entire length inside the pallets of screw surfaces 8, 9, 10 (Fig. 1), coil springs 51, 52, 53 with a flat section of coils are mounted to move bulk materials from loading to unloading, which are equipped with a device for changing the pitch of the coils by stretching them or compression (not shown in the drawings).

Installation for continuous drying of bulk materials works as follows.

By known methods and devices, a heat agent is supplied through air ducts 6 to the drying cabinet 4. After heating the drying chamber 4, the bulk material enters the charging device 2, from where it flows continuously into the internal cavity of the pallet 9. Under the influence of vibration, the particles of the bulk materials rotate along circular paths and along the helical lines of the main direction, and using the turns of the spring 51, the bulk material is transported from the load to the outlet 11. From the outlet 11 cut the space closed by the heat-insulating cover 12, the bulk material enters the hole 9 of the pallet 10 and through the helical grooves of the pallet 10, and also by means of the spring 52 is transported to the outlet 14. From the outlet 14 through the space closed by the heat-insulating cover 15, the bulk material is fed through the inlet 16 into the pallet 10. In the pallet 10, the bulk material is transported along the helical lines of the main direction and using a spring 53 to the outlet 17, and then unloaded through the unloading device of 3 outside the oven 4. In this case, the bulk material to be dried, makes a complex spatial movement along helical trajectories, is its intense mixing. Since the surface faces of the screw surfaces 8, 9, 10 are mounted one to the other at different angles, the particles of the dried bulk material moving under the influence of vibration and meeting with them change their motion path, which lengthens their path and intensifies the drying process, while the velocity vectors material change, which contributes to the intensification of the mixing and drying process. In addition, since the shape and dimensions of the sides of the cross section vary along the length of the screw surfaces 8, 9, 10, the disturbance in the ordering of the process of movement of bulk material is aggravated, i.e. intensive mixing takes place, which leads to an increase in the drying efficiency of materials in screw surfaces 8, 9, 10, increases the speed of movement of the material, creates a complex spatial movement of the flows of bulk materials and intensifies the drying process. Holes can be made in the side walls 8, 9, 10, the sizes of which are smaller than the minimum particle size of the bulk materials, however, sufficient for the heat agent to pass through these holes. Installation of air ducts 6 and supply of heat agents at a distance of 2/3 of the transport path of a single technological chain of the path of the material to be dried provides an optimal transport route with smooth heating of bulk material coming through the charging device 2 to the drying chamber 4 to maximum temperatures and then a gradual decrease in the temperature of the bulk material when passing the remaining distance 1/3 of the entire transport path to the unloading device 3.

Technical and economic advantages arise due to the fact that the thermally insulated chamber is equipped with a vibrator and elastic elements fixed on the base, and is installed with the possibility of spatial movement in three mutually perpendicular planes, and the pallets are belt-mounted one under the other and connected rigidly into a single technological chain in in the form of screw hollow surfaces, rigidly mounted under each other and communicated with each other, made of guide elements in the form of three straight nyh strips, which simplifies the fabrication and operation of the plant for the continuous drying of granular materials, expands technological possibilities.

Technical and economic advantages also arise due to the fact that the pallets are made in the form of screw hollow surfaces, rigidly mounted under each other and communicated with each other, made of guide elements in the form of three rectangular strips twisted in a vertical plane in the longitudinal direction relative to their own axis of symmetry then bent along helical lines in the transverse direction and bent at an angle alternately in opposite directions along cuts made at an angle of 60 ° to each other and to along the edges of the strips with the formation along the length of the strip of equilateral triangles located alternately in opposite directions, while the strips are connected at an angle to one another along the longitudinal edges at an angle with the formation along the inner perimeter of three broken helical surfaces and three broken helical grooves of the main direction for movement bulk materials from loading to unloading, as well as two broken curved helical surfaces and two screw grooves in the opposite direction, moreover three broken helical lines of the main direction and two broken helical lines of the opposite direction with a step four times smaller than the step of the broken helical lines of the main direction, at the break points of the helical lines there are places of convergence of the sides of six equilateral triangles, while along the entire length of the pallets mounted to move bulk materials from loading to unloading coil springs with a flat section of coils, which are equipped with a device for changing the pitch of the coil s by stretching or compressing, which not only simplifies the manufacture and operation, but also expands technological capabilities, since the shape and dimensions of the cross section, having the shape of a polygon, change repeatedly over the length of the screw surfaces, which ensures multiple periodic compression of the masses of bulk materials, which increases mixing intensity, energy intensity of collisions and heat transfer intensity, expand technological capabilities, provide a rational thermal drying regime, while The creation of flows of bulk materials directed towards each other with a maximum frequency of particle collisions with each other and with the surface walls of the screw surfaces at different angles is increased, which increases the frequency of interaction of the particles of bulk materials with each other and with the walls of the pallets, increases the heat transfer intensity and extends technological capabilities.

Claims (1)

Installation for the continuous drying of bulk materials, containing a thermally insulated chamber, devices for loading and unloading bulk materials, supply and output of a drying agent and pallets mounted in a chamber under each other and communicated with each other, characterized in that the thermally insulated chamber is equipped with a vibrator and elastic elements, fixed on the base, and installed with the possibility of spatial movement in three mutually perpendicular planes, and belt mounted under each other and connected rigidly in a single technological chain, the pallets are made in the form of screw hollow surfaces, are rigidly installed under each other, communicated with each other, made of guide elements in the form of three rectangular strips twisted in a vertical plane in the longitudinal direction relative to their own axis of symmetry, then curved along helical lines in the transverse direction and bent at an angle alternately in opposite directions along notches made at an angle of 60 ° to each other and to the longitudinal edges of the strips along the length of the strip of equilateral triangles located alternately in opposite directions, while the stripes are connected at an angle to one another along the longitudinal edges with the formation along the inner perimeter of three broken screw surfaces and three broken screw grooves of the main direction to move bulk materials from loading to unloading as well as two broken curved helical surfaces and two screw grooves in the opposite direction, and three broken lines are formed along the outer diameter of the pallet helical lines of the main direction and two broken helical lines of the opposite direction with a step four times smaller than the step of the broken helical lines of the main direction, the points of convergence of the sides of six equilateral triangles are located at the break points of the helical lines, while along the entire length of the pallets they are mounted to move loose materials from loading to unloading coil springs with a flat section of coils, which are equipped with a device for changing the pitch of the coils by stretching or compressing them.

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