VORTEX TUBE DRYER

Abstract

A vortex dryer for fibrous material utilizes a helical inlet to the base of a central vortex tube to separate fiber from debris by abruptly changing direction of the conveying air flow. The dryer combines the helical input with helical shaping of the air flow through the central vortex tube to induce greater drying for the fiber which is continued at the top of the vortex tube through a separate drying chamber.

Description

FIELD OF THE INVENTION

This invention relates to a novel drying system for fiber or other light-weight material such as seed cotton. The invention further relates to separating rocks or other heavy foreign matter from the light weight material in the process. In particular, this invention relates to the construction of a separator with unique features incorporated to achieve these objectives, while minimizing the energy losses traditionally associated with each.

BACKGROUND

The process of picking cotton and thereafter removing seeds, trash and other foreign materials from the seed cotton is well known and understood by those familiar with the art. After seed cotton is harvested, it is then transported from the field to a cotton ginning facility. This facility has apparatus for receiving the seed cotton, drying and cleaning the seed cotton, removing the seeds from the cotton fiber or lint, cleaning the lint, and pressing the lint into bales for transport to warehousing, and later sold, commonly processing into yarn, thread, and fabric.

It is important to note that seed cotton is normally conveyed pneumatically through much of the drying process with many systems including more than one stage in the drying process. Another point to consider is whether the conveying air is of a positive pressure, a negative pressure, or some combination of the two. Those familiar in the art commonly refer to positive pressure systems as push systems, and negative pressure systems as pull systems or pull-through systems.

It is well understood cotton can be processed more easily and safely at certain levels of humidity, or moisture content. It is also well understood by those skilled in the art that the exchange of moisture into or out of seed cotton is promoted when there is a relative movement between the seed cotton and the heated conveying air.

Early in the mechanical stages used in the type of cotton ginning facility wherein the present invention might be useful is a device known as a rock trap or rock catcher, which separates rocks, green cotton bolls, and heavy foreign material from the pneumatically conveyed seed cotton as seen in FIG. 1. As seen in FIG. 1, the seed cotton is pneumatically conveyed through a conduit to an area where this separation is traditionally achieved with a hopper-type rock trap 10 which operates by abruptly expanding the cross-sectional area of the conduit and thus the negative-pressure conveying air stream and placing a deflector panel 11 in the direct path of the seed cotton and hot air stream. The deflector panel 11 directs the rocks and other heavy matter downward to an air-lock 12 and out of the system. Most of the seed cotton is light enough to be picked back up by the negative-pressure air stream as it passes around the deflector panel 11, and is then accelerated back into a conduit of similar cross-sectional area as was employed before the seed cotton entered the rock trap 10. A relatively small amount of seed cotton does not get picked back up by the hot air stream and falls down toward the air-lock. The air-lock is commonly either of a rotary design 13 or of a double-door design 14, with one door 14a separated by a small chamber over another door 14b where only one door opens at a time. Those in the industry often refer to rotary air locks as either vacuum droppers or vacuum wheels.

In an effort to minimize the amount of seed cotton lost in this process, an adjustable air inlet 15 is employed allowing ambient, cold air to reclaim the seed cotton and send it upward away from the air-lock and back into the conveying air stream. Energy is lost in this process in multiple ways. First the deflector panel creates a significant pressure drop; secondly the ambient air introduced to reclaim lost seed cotton dilutes the heat of the conveying air, thus reducing the drying capacity, and finally the energy required to pull in and accelerate this ambient air creates yet another pressure drop.

It must be acknowledged that in an effort to reduce the losses at the hopper-type rock trap, an innovative system was successfully developed wherein a secondary hot air stream was introduced immediately after the deflector to keep the conveying air warm and introduce additional turbulence to enhance the drying process. This approach was applied in many installations and helped improve the system efficiency, but all of the other losses described above remained. This approach also introduced the need for additional ductwork and complexity regarding air-balance, and introduced the opportunity for compromising the conveying air stream velocity by virtue of the pull air coming in through the secondary hot air stream inlet at the rock trap. That is to say, the air intake at the secondary inlet can reduce the effectiveness of the upstream air flow by reducing the pressure differential upstream of the rock trap.

FIG. 2 shows another type of rock trap known generically as a conveyor-belt suction-duct-type 20 which can be employed at the point where the seed cotton initially enters the air stream. In the better versions of this arrangement, hot air is pulled into a plenum chamber integrated into the suction-duct. In worst cases, the cotton is picked up with ambient air much like a large vacuum cleaner and almost immediately dropped into an elevated feed hopper without the benefit of any heating at all, thus adding to the overall system energy requirements. In the former case, ambient air is also pulled into the system, thus diluting the hot conveying air in such a way as to normally be less efficient than the previously described hopper-type rock trap 10.

While the number and type of components in drying systems vary from one facility to the next, some common system components can be seen in FIG. 3 and FIG. 4. It is not uncommon for the device following the rock trap to be either a shelf-type tower dryer 30 as taught by Bennett in U.S. Pat. No. 2,189,099 or some other type of large vessel 40 as taught by Jackson in U.S. Pat. No. 4,845,860, with either being designed to slow down the velocity of the seed cotton and allow slippage of the hot conveying air over and through the seed cotton. In many cases there is a necessary change in elevation between the outlet of the rock trap 10 and the inlet of the dryer. As a result, the ductwork between these two devices commonly contain at least two or three elbows 41 and some straight sections 42, each creating additional pressure drops.

It should also be noted the rock traps described above all operate primarily in drying systems using a negative pressure conveying air stream, or pull-through designs. By virtue of the need for the introduction of the reclaiming air above the air-lock, these systems do not easily lend themselves to positive pressure conveyance, or push designs.

SUMMARY OF THE INVENTION

An object of the present invention is to offer a simple, novel device for removal of rocks and green cotton bolls that can be used in systems employing either positive or negative conveying air streams.

It is another object of this invention to incorporate the rock trap and dryer into one device, thereby removing the connecting ductwork and elbows between these two functions and reducing the energy losses introduced by such ductwork and elbows connecting the two. This also reduces the footprint for both of these functions.

A further object of this invention is to devise a means for separating the rocks and green cotton bolls using a cyclonic inlet, thus reducing the energy requirements for this step of the process as compared to the traditional hopper-type rock trap.

Yet another object of this invention is to convey the seed cotton out of the rock trap and into the dryer chamber without, or essentially without the need for the introduction of reclaiming air, reducing the energy losses as compared to traditional systems.

It is another object of this invention to introduce a spiraling motion for the seed cotton throughout the entire device to promote a tumbling action for each individual lock of seed cotton, thereby exposing multiple faces of each lock of seed cotton to the hot conveying air stream, thereby increasing the relative motion between the seed cotton and the conveying air stream, thus improving drying efficiency. This spiraling motion begins at the inlet of the rock catcher, continues through a central vortex equipped with spinner vanes, and is encouraged to continue in a spiral path due to the unique ceiling of the dryer chamber, and also at the exit of the dryer.

A further object of this invention is to create a central, rotating vertical column of conveying air within the dryer chamber with the vertical column eventually being separated by a centrally suspended cone to create a distribution of seed cotton around the perimeter of the chamber prior to its downward path; the ceiling of the dryer chamber being of a curved shape such that it encourages the seed cotton path to take on the shape of a torus, or doughnut, thereby inducing a compound direction of spin for each lock of seed cotton, thus further improving drying efficiency in the manner described previously. By virtue of the centrally rising column of conveying air and seed cotton piercing the path falling down around the perimeter, a cylindrically shaped pneumatic sheer zone is created where the two pass each other, one inside the other as seen from above, this sheer zone further increasing turbulence at the boundary layer between the two and furthering the encouragement of the continuation of a torus-shaped path of the descending seed cotton.

BRIEF DESCRIPTION OF THE DRAWINGS

Referring to the drawings which are appended hereto and which form a portion of this disclosure, it may be seen that:

FIG. 1 is a side cross section view of a traditional prior art hopper-type rock and green boll trap;

FIG. 2 is a sectional view of a traditional prior art conveyor-belt suction-duct-type rock and green boll trap;

FIG. 3 is a sectional view of a traditional prior art shelf-type tower dryer;

FIG. 4 is a sectional view of a hopper-type rock trap followed by a traditional open-cavity dryer;

FIG. 5 is a front sectional showing the overall view of a first embodiment of present invention;

FIG. 6 is an orthographic view of the tangential inlet outlet, and vortex tube of the embodiment of FIG. 5;

FIG. 7 is an orthographic view showing the vortex tube with the diffuser nozzle removed of the first embodiment;

FIG. 8 is a sectional view of a second embodiment of the inlet of the vortex tube, the lower end of the cylindrical body, and the cone above the air lock of the present invention;

FIG. 9 is a bottom view of the dished head and splitter cone;

FIG. 10 is a partial perspective view of the dryer;

FIG. 11 is a perspective view of the separating chamber of the third embodiment;

FIG. 12 is an upper perspective view of the separating chamber of the third embodiment showing the conic scroll extension of the inner wall;

FIG. 13 is an upper perspective view of the separating chamber of the third embodiment;

FIG. 14 is a partial sectional view of the drying chamber of the third embodiment; and

FIG. 15 is a diagrammatic view of a fourth embodiment.

DETAILED DESCRIPTION

One or more of the above objects can be achieved, at least in part, by providing a vortex tube dryer 50 including a cylindrical body 51 with a head 52 of dished or concave shape containing a suspended splitter cone 53. An inlet 54 allows seed cotton and air to enter the cylindrical body 51 in a tangential manner into a ductwork with a rectangular cross section defined by an upper wall 57, a lower wall 59, an inside wall 55a, and an outside wall 60, This ductwork causes the airflow and entrained seed cotton to follow a downward spiraling path. The inside vertical wall of this rectangular cross section wraps around a central vertical vortex tube 55. As the inlet path wraps downward around the vortex tube 55, the cross section enlarges thus reducing the velocity of the hot air and seed cotton. This enlargement can be achieved in more than one way. One means of enlargement by the upper wall 57 of said rectangular inlet duct leveling out to form the lower floor of the superjacent outlet 58, thereby increasing the vertical height of the rectangular inlet duct. Another means of enlargement by the introduction of a gradually tapered spiral opening 56 in the inner wall 55a coincident with the outer wall of the vortex tube 55. The tapered opening 56 or vortex tube inlet creates a sharp turn for the hot air and seed cotton. The lower wall 59 of the rectangular inlet duct continues downward in the same spiral fashion until terminating near the bottom of the cylindrical body 51. FIG. 6 further illustrates several of these components.

The separation of rocks, green bolls, and heavy foreign matter takes place below the inlet 54 by virtue of two actions; first the heavier-than-seed-cotton material tends to follow the outer wall 60 of the tangential inlet and such that the inlet duct acts like a cyclone tending to sling the heavy material outward as the air follows a circular path, and secondly the difference in the mass of the individual locks of seed cotton and the basic momentum formula for an object of p=my, where p represents momentum, m represents mass of the object and v represents velocity of the object. The smaller mass seed cotton has less momentum and tends to follow the air stream into the tapered spiral opening 56, thus, the seed cotton is peeled away from the trajectory of any more massive materials, such as rocks and green bolls, which are unable to make the sharp turn due to their higher momentum. The separation action of a cyclone is well understood by those familiar with the art.

A cone 65 is attached to the bottom of the cylindrical body 51, and below the cone 65 is a round to rectangular transition 61. Below the transition is an air lock 12 either of a rotary design 13 or of a double-door design 14. The rocks and green bolls are then dropped out of the system into a barrel 43, some other suitable container, or some other means of conveyance.

The velocity of the hot air and seed cotton entering the vortex tube 55 increases due to the decrease in cross sectional area. The inside of the vortex tube 55 can be seen in FIG. 7. The vortex tube 55 contains helical spinner vanes 62 extending inwardly and diagonally relative to the vortex tube, which will encourage the continued spiral path of the hot air and seed cotton. Above the vortex tube is a diffuser nozzle 63 designed to reduce the pressure drop as the hot air and seed cotton enter the relatively larger cross section created by the cylindrical body 51. As the rising column of seed cotton reaches the splitter cone 53 and dished head 52 it will spread around the perimeter wall of the cylindrical body prior to falling back down onto the spiral exit ramp floor 64 created by virtue of being the other side of the material used to make up the upper wall 57 of the rectangular inlet 54. The concomitant motion of the centrally rising column of conveying air and seed cotton exiting the vortex tube and the descending air moving toward the tangential outlet 58 create a cylindrically shaped pneumatic sheer zone where the air moving in opposite vertical directions pass each other, one inside the other as seen from above, thereby further increasing turbulence at the boundary between the two and furthering the encouragement of the continuation of a torus-shaped path of the descending seed cotton. The rectangular tangential outlet 58 is formed on the bottom by the spiral exit ramp floor 64, on the outside by the wall of the cylindrical body 51, and on the inside wall by the vortex tube 55. Optionally, a series of spinner vanes 75 can be affixed to the surface of the splitter cone 53 arranged in a spiral pattern, as seen in FIG. 9, thus encouraging the seed cotton to continue in spiraling path as it traverses the dished head 52. It is understood the head 52 can be dished, spherical, elliptical, or flat and still maintain the spirit thereof.

A second embodiment of the present invention can best be seen in FIG. 8 where the inlet of the vortex tube 55 does not have a tapered spiral opening. The vortex tube inlet can optionally include an inlet nozzle 71. Directly below the vortex tube inlet is an optional vortex breaker 72 that can be conical, spherical, elliptical or flat in cross section. This vortex breaker 72 can be supported from beneath, and this support 73 can also be adjustable to place the vortex breaker 72 in an optimal position. It is to be understood that support 73 can include hydraulic or mechanical actuators to move the vortex breaker horizontally and vertically in a known manner. The vortex breaker 72 adjustment can include not only a change in elevation, but can include provision for a location change bringing the vortex breaker into a position no longer central to the cylindrical body 51 or the cone 65 or the vortex tube 55. This adjustment can also allow for a change in angular position of the central axis of the vortex breaker 72 relative to the cylindrical body 51 or the cone 65 or the vortex tube 55. It is understood all or some features unique to the second embodiment can be combined or included with features described in the first embodiment and still maintain the spirit thereof.

It is understood the cylindrical body or housing 51 in any of the embodiments described herein can be made up of a multi-faceted wall with as few as four facets instead of having a smooth, curving surface wall and some components could also be faceted in a similar manner and still maintain the spirit thereof.

A third embodiment of the present invention can be seen in FIG. 10 and FIG. 14 where the tangential inlet 54 and tangential outlet 58 are at significantly differing elevations. The inlet section 86 of this embodiment is separated from the outlet section 87 by a solid divider sheet 88 with a central hole of the same diameter as the vortex tube 55. This divider sheet 88 forms the roof of the inlet section 86 and serves as the origination of the inlet point of the vortex tube 55. A tangential inlet 54 enters the cylindrical body 51 near the bottom and the spiral inlet path points upward. As seen in FIG. 11 this upward directionality is achieved by combining an involute scroll-type vertical wall 80 and radially upward ramping floor 81 in order to encourage the seed cotton to begin the spiraling motion immediately prior to entry into the central vortex tube as shown in previous embodiments. By radially upward ramping, we mean that the portion of the floor closest to the involute scroll is higher than the distal portion closest to the axis of the vertical tube. Further the angle of inclination of the upwardly ramping floor increases as the involute spiral wall curves toward the vortex tube. Thus, the upward ramping floor 81 increases in angular pitch from the central axis of the vortex tube such that as the path of the involute wall 80 approaches completion of 180 degrees of rotation around the central axis, the floor angle becomes parallel to the wall forming a partial near-cylindrical area immediately beneath the vortex tube. In addition to inducing the spiraling motion of seed cotton, this shape creates a somewhat gradual transition in cross-sectional area between the tangential inlet of the cylindrical body and the inlet at the bottom of the vortex tube in order to accelerate the seed cotton in such a manner as to minimize the energy losses associated with abrupt pressure drops and undesirable eddy currents.

While the seed cotton is carried immediately upward into the accelerating air stream entering the vortex tube, the relatively heavier items like rocks or green bolls tend to follow the outer wall of the involute scroll, in an ever-tightening path toward the center where it will tend to reduce in velocity, drop out of the conveying air stream, fall into a cone 82 attached to the floor at the bottom of the cylindrical body, drop into air lock 12, and exit the system as demonstrated in previously described embodiments.

The vertical walls of the tangential inlet are defined on the outside by the involute scroll 80, and on the inside by a vertical wall 83 that ends near the point where the plane defined by this inside wall meets at or near the tangent point 89 of the downward imaginary cylindrical projection of the wall of the vortex tube immediately above. This inner wall 83 can stop abruptly at this tangent point 89 as best seen in FIG. 13, or can be fitted with a variety of scroll extensions as best seen in FIG. 12 so shaped to prevent the separated matter like rocks and green bolls from being reintroduced into the air stream entering the vortex tube. One such scroll extension could be described as a portion of a cylinder or as the continuation of the ever-tightening involute scroll. Another shape could be described as a portion of a cone whose defining axis runs parallel or nearly parallel with the vortex tube. A cone version of this scroll extension 84 could be designed pointing up or down. It is understood portions of the above described scroll extensions could be cut away or extended as required to obtain the desired results described herein.

The outlet section 87 can best be understood as seen in FIG. 14 and is formed with the floor of the outlet being defined by a single or compound diagonal plane whose lower end terminates immediately prior to the rectangular tangential outlet 58, with said plane forming a singular canted disc 85 whose center is removed in such a way as to allow the cylindrical path of the vortex tube 55 to pass through this plane, and sealed both to the vortex tube and the inner walls of the cylindrical body 51 in order to maintain air pressure isolation between the inlet and outlet of the dryer.

Alternatively for this third embodiment, the outlet section 87 could be replaced and rectangular tangential outlet 58 formed as best shown in FIG. 6. with the spiral exit ramp floor 64 as demonstrated in a previously described embodiment.

A fourth embodiment of the present invention can be seen in FIG. 15 wherein the inlet 54 of the dryer is coincidental with the inlet point of the vortex tube 55. The spiral exit ramp floor 64 and dryer tangential outlet 58 remain as demonstrated in previously described embodiments and shown in FIG. 6 and FIG. 14.

Alternatively for this fourth embodiment, the outlet section could be formed with the floor of the outlet being defined by a single or compound diagonal plane whose lower end terminates immediately prior to the tangential outlet 58, with said plane forming a singular canted disc 85 whose center is removed in such a way as to allow the cylindrical path of the vortex tube 55 to pass through this plane as best shown in FIG. 14. While in the foregoing specification this invention has been described in relation to certain embodiments thereof, and many details have been put forth for the purpose of illustration, it will be apparent to those skilled in the art that the invention is susceptible to additional embodiments and that certain of the details described herein can be varied considerably without departing from the basic principles of the invention.

Claims

1. A vortex dryer for fluid conveyed fiber and the like wherein a tubular housing contains a vertical central tube partially circumscribed by a spiraling inlet housing in fluid communication with the bottom of said central tube superjacent a discharge for heavier trash and debris, said central tube including a plurality of helical vanes about its interior to promote helical flow of fluid conveyed fiber upward through the vertical central tube, wherein said tubular housing includes a head forming a diverter dish for directing fluid conveyed fiber outwardly and downwardly to a tangential fiber discharge outlet.

2. A dryer for fiber entrained in an airstream wherein a central vertical tube defines an air passage from lower separating chamber to an upper drying chamber said lower separating chamber including a spiraling intake guide delivering said airstream and entrained fiber to an inlet to said vertical tube, said central vertical tube including a plurality of helical vanes extending inwardly to promote helical flow of air entrained fiber upwardly there through, said drying chamber including an upper deflector head positioned above said central vertical tube and a tangential fiber discharge outlet positioned below said deflector head such that airflow through said central vertical tube to said tangential outlet is directed downwardly toward said tangential fiber discharge outlet.

3. A dryer as defined in claim 2 wherein said spiraling intake conduit is defined by an inner wall defining said vertical tube, an outer wall of said separating chamber, downwardly spiraling lower wall, a connecting wall extending tangentially from said vertical tube between said vertical tube and said outer wall, and a downwardly spiraling partition spaced above said spiraling lower wall and separating said drying chamber from said separating chamber and defining a base of said tangential discharge outlet.

4. A dryer as defined in claim 3 wherein said downwardly spiraling lower wall extends below said vertical tube into said separating chamber.

5. A dryer as defined in claim 3 wherein said vertical tube extends below said downwardly spiraling wall into said separating chamber.

6. A dryer as defined in claim 5 wherein a conic vortex breaker is disposed beneath the central vertical tube.

7. A dryer as defined in claim 6 wherein said conic vortex breaker is mounted on an adjustable support to allow selective positioning of said vortex breaker in said separation chamber.

8. A dryer as defined in claim 2 wherein an air lock communicates with said separating chamber and is positioned subjacent said separating chamber to remove matter dropped from said airstream.

9. A dryer as defined in claim 2 wherein said upper diverter head includes a plurality of downwardly extending diverter vanes to direct the airstream from the outlet of the vertical tube.

10. A dryer as defined in claim 2 wherein a conic vortex breaker is disposed beneath the central vertical tube.

11. A dryer as defined in claim 10 wherein said conic vortex breaker is mounted on an adjustable support to allow selective positioning of said vortex breaker in said separation chamber.

12. A dryer as defined in claim 2 wherein said spiral intake guide is an involute scroll positioned subjacent said vertical tube and diminishing in radius towards said tube with said involute scroll affixed to a bottom wall with said bottom wall having a radially upward inclination increasing as said involute scroll radius diminishes.

13. A dryer as defined in claim 12 wherein a tangential inlet for said airstream is defined by the inner wall of said involute scroll and a vertical wall spaced from said involute scroll and extending to a point immediately below the wall of said vertical tube.

14. A dryer as defined in claim 13 wherein said vertical wall extends below said vertical tube as a conic section.

15. A dryer as defined in claim 12 wherein said separating chamber and said drying chamber are separated by a partition with said vertical tube passing through said partition and sealed to said partition.

16. A dryer as defined in claim 12 wherein said drying chamber includes a floor inclined relative to said vertical tube upwardly from said tangential fiber discharge outlet.

17. A dryer as defined in claim 12 wherein said tangential discharge outlet is formed by the outer wall of said vertical tube, an outer wall of said drying chamber, a floor spiraling downwardly about said vertical tube, and a connecting wall extending tangentially from said outer wall of said vertical tube.

18. A dryer as defined in claim 3 wherein said tangential fiber discharge outlet is formed by the outer wall of said vertical tube, an outer wall of said drying chamber, said downwardly spiraling partition forming a floor about said vertical tube, and a connecting wall extending tangentially from said outer wall of said vertical tube to said outer wall of said drying chamber.

19. A dryer as defined in claim 1 wherein said spiraling inlet housing is defined by an inner wall defining said vertical tube, the inner wall of said tubular housing outer wall of said separating chamber, a downwardly spiraling lower wall, a connecting wall extending tangentially from said vertical tube between said vertical tube and said outer wall, and a downwardly spiraling partition spaced above said spiraling lower wall and separating said tubular housing into an upper drying chamber and a lower separating chamber.

20. A dryer as defined in claim 1 wherein said spiraling inlet housing is defined by an involute scroll positioned subjacent said vertical tube and diminishing in radius towards said tube with said involute scroll affixed to a bottom wall with said bottom wall having a radially upward inclination increasing as said involute scroll radius diminishes and a vertical wall spaced from said involute scroll and extending tangentially from a point immediately below the wall of said vertical tube to the wall of said tubular housing.

21. A vortex dryer for fluid conveyed fiber and the like wherein a tubular housing contains a vertical central tube including a plurality of helical vanes about its interior to promote helical flow of fluid conveyed fiber upward through the vertical central tube, wherein said tubular housing includes a head forming a diverter dish for directing fluid conveyed fiber outwardly and downwardly to a tangential fiber discharge outlet.

22. A vortex dryer as defined in claim 21 wherein tubular housing defines there within a drying chamber which includes a floor inclined relative to said vertical tube upwardly from said tangential fiber discharge outlet.