WO2012057738A1 - Sifting apparatus - Google Patents

Abstract

Sifting apparatus, for sifting solid particles from a gaseous or liquid fluid, having a rotating conical filter 10 and fan blade assembly 28 connected to the filter exterior, both rotated together by a motor /pulley assembly, the fan blades 39 slanted in a direction opposite the rotation direction, so that air is drawn through the filter 10 from its interior to its exterior, having an inlet 12 for admission of air only at the narrow end of the filter, and having a receptacle 16 for collection of the particles at the broad end 14 of the filter. Applications include cleaning of particle contaminants from air; cleaning beach sand by sifting out broken glass, sea weed or other debris; extraction of mineral particles from water slurry; collection of soil samples picked up by an air stream; lawn maintenance collection of weeds, leaves and burrs; biohazard removal operations; and an alternative to auger food particle transport in food processing.

Description

SIFTING APPARATUS BACKGROUND OF THE INVENTION

The present invention pertains to apparatus for sifting out solid particles contained in a gaseous or liquid fluid, having fan or pumping fluid impeller means for causing the fluid to flow through a filter which collects particles larger than the filter aperture size while allowing smaller particles to pass with the fluid out of the apparatus. In this application the word "particle" shall mean any fragment of a solid substance, of whatever size, contained in the gaseous or liquid fluid, so as to be siftable out from the fluid by such apparatus if the particle is larger than the filter aperture size.

There are numerous and quite varied possible applications for such sifting apparatus, as further discussed below, including, for example, cleaning of particle contaminants from air or other gases; cleaning beach sand by sifting out broken glass or other debris which could harm the feet of bathers or detract from the appearance of the beach; extraction of valuable mineral particles contained in a water slurry; collection of soil samples which could be picked up by an air stream; lawn maintenance collection of weeds, leaves and burrs; radiation hazard removal operations, such as removal of a plutonium fragment or dust spill at a nuclear facility; biohazard removal operations, such as removal of spilled anthrax particles; an alternative to auger type transport of food particles in food processing operations; and undersea collection of coins or other small treasure items found around a shipwreck.

The present invention may in various embodiments be useful for any such applications, among others, and employs an approach, detailed below, which synergistically combines two distinct physical means for sifting particles from a fluid.

SUMMARY OF THE INVENTION

As a summary, this section of course does not explicate the invention in all the detail of the subsequent detailed description and claims. It is intended that the relative brevity of this summary shall not limit the scope of the invention, which scope is to be determined by the claims, properly construed, including all subject matter encompassed by the doctrine of equivalents as properly applied to the claims.

In the summary and detailed description, "fluid of interest" will be used generally to denote air or any other any gaseous or liquid fluid of interest for use of the apparatus in sifting particles which may be contained within said fluid.

The basic approach of the present invention synergistically combines a rotating filter, tapered in diameter between a narrow fluid inlet end to a broader particle collection end having a connected particle collection receptacle, the filter wall containing numerous filter apertures; an impeller drawing fluid of interest into the filter's fluid inlet and outward through the filter wall, the wall stopping particles larger than the filter apertures, and the filter rotation causing the trapped particles to move along the wall to the particle collection receptacle, as a result of the centrifugal force on each particle from the filter rotation, which force has a component along the surface of the filter wall in the direction of the particle collection receptacle, because of the narrowing or tapering filter wall geometry. Thus sifting is synergistically accomplished by the combination of the filtering and rotation-induced motion of the trapped particles into the collection receptacle.

According to one aspect of the present invention, a sifting apparatus, for sifting solid particles from a fluid, comprises: (a) a filter, having a filter wall with an interior surface and an exterior surface, having a principal longitudinal axis and narrowing or tapering between a broader open particle collection end and a narrower open fluid inlet end, and having numerous small filter apertures extending through the filter wall from the interior surface of the filter wall to the exterior surface of the filter wall; wherein the filter has a geometric narrowing or tapering form to cause captured particles to travel along the interior surface towards the particle collection end in response to rotation of the filter; (b) a rotation means, connected to the filter, for rotating the filter in a rotation direction about the axis of the filter; and (c) a fluid impeller means, connected to the filter, for causing the fluid to flow into the fluid inlet end of the filter and to flow out of the filter through the filter apertures. A particle collection receptacle can be operably connected to the filter at the particle collection end of the filter. The particle collection receptacle can be fluid tight and in fluid tight connection with the filter.

According to another aspect of the present invention, a method for sifting solid particles from fluid, the method comprises providing a filter, the filter having a filter wall with an interior surface and an exterior surface, a longitudinal axis, a diameter tapering or narrowing between a broader open particle collection end and a narrower open fluid inlet end, numerous small filter apertures extending through the filter wall from the interior surface of the filter wall to the exterior surface of the filter wall; and having a geometric form to cause captured particles to travel along the interior surface towards the particle collection end in response to rotation of the filter; drawing fluid into the fluid inlet end of the filter and out of the filter through the filter apertures; rotating the filter in a rotation direction about the longitudinal axis of the filter to cause particles captured in the filter to travel along the interior surface towards the particle collection end in response to rotation of the filter; and collecting particles leaving the particle collection end of the filter. Collecting particles leaving the particle collection end of the filter can comprise collecting the particles leaving the particle collection end into a fluid tight particle collection receptacle in fluid tight connection with the filter

In one other aspect, the invention comprises a filter, having a filter wall with an interior surface and an exterior surface, having a principal longitudinal axis and having the shape of a surface of revolution about the axis, the filter tapering in diameter between a broader open particle collection end and a narrower open fluid inlet end, and having numerous small filter apertures extending through the filter wall from the interior surface of the filter wall to the exterior surface of the filter wall; a motor means, connected to. the filter, for rotating the filter in a rotation direction about the axis of the filter; a fluid impeller means, connected to the filter, for causing the fluid of interest to flow into the fluid inlet end of the filter and to flow out of the filter through the filter apertures; and a particle collection receptacle connected to the filter at the particle collection end of the filter.

In some embodiments the invention comprises the elements as described above in which the filter is at least substantially of the shape of a frustum of a cone extending between the fluid inlet

end and said particle collection end.

In some embodiments the invention comprises the elements as described above in which said fluid impeller means comprises a rotating cylindrical fan blade assembly surrounding and coaxial with said filter, connected to and rotating with said filter, said fan blades being slanted in a direction opposite said rotation direction.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings, which all relate to the same embodiment of the invention:

Fig. 1 is a perspective view of the fan blade assembly surrounding the cone shaped filter, with the filter position shown in phantom, for simplicity and clarity omitting the apparatus housing shown in fig. 2.

Fig. 2 is a side elevational sectional view of the apparatus in a housing, through the principal axis of the filter and fan blade assembly.

Fig. 3 is a sectional view as indicated by the lines 3-3 in fig. 2, omitting the apparatus housing, motor and pulley belt assembly.

Fig. 4 is a sectional view as indicated by the lines 4-4 in fig. 2, at the intake end of the filter, omitting the housing, motor and pulley belt assembly.

Fig. 5 is a sectional view as indicated by the lines 5-5 in fig. 2, at the particle collection end of the filter, omitting the housing, motor and pulley belt assembly.. Fig. 6 illustrates a portion of fig. 2 showing the centrifugal force acting upon a trapped particle on the filter wall, and the components of that force; and

Fig. 7 illustrates a flow chart outlining a method of sifting particles from a fluid according to one embodiment .

DETAILED DESCRIPTION

Referring now to the drawings, in which like reference numbers denote like or corresponding elements, an embodiment designed for removal of particles from air as the fluid of interest is shown in figs. 1-6. The apparatus has a filter 10, of the form of a frustum of a 10 cone, open at a fluid intake end 12 and at a particle collection end 14, having a fluid tight particle collection receptacle 16 connected to particle collection end 14 of filter by a fluid tight connector 18. The filter wall 20, having an interior surface 22 and an exterior surface 24, has numerous filter apertures 26 extending through filter wall 20, connecting interior surface 22 with exterior surface 24, which are small enough to allow filter 10 to capture particles of interest contained in the fluid of interest.

In the embodiment of the apparatus of figs. 1- 6, the filter 10 is surrounded by fan blade assembly 28, of a type commonly known as a squirrel cage type also commonly known as a centrifugal fan, with filter 10 and fan blade assembly 28 being coaxial and rotatably mounted on ring bearings 30, and with filter and fan blade assembly 28 being also securely fastened to one another by annular baffle plates 32 which extend between filter 10 25 and fan blade assembly 28 at the ends of filter 10, so that filter and fan blade assembly 28 are rotatable together. Rotation of filter 10 and fan blade assembly 28 may conveniently be accomplished by a rotation means in the form of a motor 34 and a conventional pulley belt assembly 36 connecting motor 34 to fan blade assembly 28, as indicated in fig. 2.

As also indicated in fig. 2, the filter 10, fan blade assembly

28, ring bearings 30, baffle plates 32, motor 34 and pulley belt assembly 36 are contained and supported by a housing 38.

As indicated in fig. 3, the fan blades 39 of fan blade assembly 28 are inclined in a direction opposite to the direction 40 of rotation of the filter 10 and fan blade assembly 28, so that the motion of fan blade assembly 28 causes the fluid of interest to be drawn outward through filter 10 and fan blade assembly 28, as indicated by the fluid flow arrows 42 in figs. 2 and 3.

Thus the combination of motor 34, pulley belt assembly 36, and fan blade assembly 28, constitutes a fluid impeller means, connected to filter 10, for causing fluid of interest to flow into fluid intake end 12 of filter 10 and to flow out of filter 10 through filter apertures 26.

Because of baffle plates 32 extending between filter 10 and fan blade assembly 28 at the ends of filter 10, and because of the fluid tight connection of particle collection receptacle 16 at particle collection end 14 of filter 10, the apparatus provides baffle means to assure that the operation of fan blade assembly 28 can draw fluid of interest only from the fluid intake end 12 of filter 10. Applicant believes that for operations of practical interest in removal of particles from air, this geometry is necessary to allow practical operation of the unit; particularly were the baffle plates 32 to be removed, some air would also be drawn in though the ends of the unit, outside exterior surface 24 of filter 10 and pass out though fan blade assembly 28, without even passing through filter wall 20 of filter 10 so as to allow particle collection.

The two physical processes involved in sifting particles from the fluid of interest drawn into the apparatus through rotation of fan blade assembly 28, are best understood with reference to figures 2 and 6. The particles 44 to be sifted from the fluid of interest initially travel on paths parallel with the flow paths for air molecules indicated by the fluid flow arrows 42. But when the particles 44 reach interior surface 22 of filter 10, the particles larger than the filter apertures 26 are stopped at interior surface 22. Because of the rotation of filter 10, particles stopped on interior surface 22 rotate with filter 10 about its axis 46, and are thus subject to an outward centrifugal force 48, in a direction directly outward from and perpendicular to the filter axis 46. Because of the cone shaped geometry of filter 10, the interior surface 22 of filter 10 is not at right angles to this centrifugal force, but is instead inclined at an angle to it. As is readily apparent from figs. 2 and 6, the outward centrifugal force 48 acting on each of the captured particles 44 will thus have a component 50 parallel to interior surface 22, in the direction of particle collection receptacle 16, as seen in fig. 6, as well as a component 52 perpendicular to interior surface 22. The component 50 parallel to interior surface 22 will cause the captured particle 44 to travel along interior surface 22 into particle collection receptacle 16. So the path of captured particles 44, while parallel to the gas flow path until the interior surface 22 is reached, will have a sharp break, with a later portion of the path then leading along interior surface 22 toward particle collection receptacle 16, as indicated by the particle path arrows 54.

Thus in the above described embodiment the combination of the rotating filter 10, and the filter geometry, with the particle collection receptacle 16 connected to filter 10 at particle collection end 14, constitutes a particle collection means, for causing collection of particles 44 in response to centrifugal force generated by rotation of filter 10.

Applicant has had a satisfactory working prototype of the apparatus made, in which the motor 34 is a 1 HP electric motor by Marathon Electric, of Wasau WI, Model DQL56C7D5345 F-P, type SCS, 1725 RPM, 60hz; and in which the fan blade assembly 28 is by Indiana Fan and Fabrication, and is a modified 13 3/16" diameter Double Inlet Belt Drive Blower Wheel, Item #008507.

The manner of operation of the apparatus is straightforward.

The user positions the apparatus with fluid intake end 12 of filter 10 located at a site at which it is desired to draw in fluid of interest for sifting of particles, and commences rotation of filter 10 and fan blade assembly 28 by closing a connection by a switch (not shown) to connect a suitable power source (not shown) to motor 34, in a manner well known in the art. Some Possible Variations of Embodiments

For example, and not by way of limitation, the following variations of embodiments from the embodiment described above and shown in the drawings, may be suitable for various applications of the invention.

Although the filter 10 is of the form of a frustum of a cone in the described and illustrated embodiment, those familiar with the art will understand that use of this precise geometric form is not necessary, in order to obtain the benefit of the centrifugal force component causing the particles 44 to move along the interior surface 22 of filter wall 20 toward particle collection receptacle 16. In general the filter 10 may be one of a form tapering in diameter between a broader open particle collection end 14, to which particle collection receptacle 16 is connected, and a narrower open fluid intake end 12. The form of filter 10 may be that of a surface of revolution about the axis 46 of filter 10.

And although the fluid motion impeller means of the illustrated embodiment is the fan blade assembly 28 which is connected to filter 10 so that fan blade assembly 28 and filter 10 rotate together by the action of motor 34 and pulley belt assembly 36, it is of course not necessary that the invention be configured in this manner. A separate fan or other fluid motion impeller means may be employed instead, for example a separately rotated squirrel cage fan assembly and motor. But the illustrated embodiment offers relative simplicity of design, manufacture and operation. A wide variation of sizes for the filter apertures 26 of filter 10 will be natural for differing applications of the invention. For cleaning of fluids of interest, in which it is desired to achieve maximum sifting out of particulate impurities, small filter apertures 26 of the order of micron diameter size may^¬ be employed. But much larger filter apertures 26 may be sufficient for certain other applications. For example, if one wished to clean beach sand, by sifting out and removing fragments of broken glass or sea shells or other debris which might hurt the feet of bathers walking along the beach or if one wished to remove sea weed which might be deemed to render the beach unsightly, filter apertures 26 of the order of 1/8" or even larger might be sufficiently small, depending upon the precise application. And if an undersea version of the invention were to be used in treasure hunting around the wreck of a Spanish galleon, e.g. to pick up gold coins that could be drawn into the apparatus by water flow caused by the impeller, apertures of 1/8" or even larger might well be sufficiently small. Other possible applications which may call for use of varied filter aperture size include extraction of mineral particles from water slurry; collection of soil samples picked up by an air stream; lawn maintenance collection of weeds, leaves and burrs; radiation hazard removal operations, such as removal of a plutonium fragment or dust spill at a nuclear facility; biohazard removal operations, such as removal of spilled anthrax particles; and an alternative to auger type transport of food particles in food processing operations. For such applications as biohazard or radiation hazard removal operations, use of a removable liner (not shown) within particle collection receptacle 16 would be desirable.

Although use of the baffle plates 32 is essential or at least highly desirable for some applications of the illustrated embodiment, to assure that all of the fluid of interest which passes through the apparatus enters the filter 10 through fluid intake end 12 and thus passes through filter apertures 26 of filter 10, there may be applications of the invention for which use of such baffling is not necessary. One advantage of the baffling is maximize sifting efficiency by having all of the fluid taken in pass through the filter. Another is to highly localize the location from which fluid of interest is drawn, e.g. to pick up particular targeted items. But for applications in which the apparatus is used only for general sampling of the nature of particles present in the fluid of interest, and collection efficiency and spatial resolution of collection are not critical, a non-baffled version of the apparatus may suffice.

No particular form of motor 34 is required for operation of the invention, provided said motor is sufficiently powerful to achieve desired fluid motion. An electric motor could be used, or possibly a gasoline or diesel powered motor for operations away from electric power sources.

No particular material is required for construction of the invention, which may fabricated of metal, or plastics or other materials of suitable strength. Alternative fluid impeller means may be employed to impel or draw fluid into the fluid inlet end of the filter and out of the filter through the filter apertures . In one embodiment, the fluid impeller means may be a fluid vacuum or fluid pumping system (not shown) having a connection inlet in fluid communication and fluid tight connection with filter apertures . The fluid vacuum/pumping system draws fluid out of the filter apertures into the vacuum/pumping system via the vacuum/pumping system connection inlet.

Reference will now be made to FIG. 7, which is a flow chart outlining a method S700 for sifting solid particles from fluid according to one embodiment .

Method S700 includes providing a filter (S701) . The filter has a filter wall with an interior surface and an exterior surface, a longitudinal axis and a diameter that narrows or tapers between a broader open particle collection end and a narrower open fluid inlet end. Numerous small filter apertures extend through the filter wall from the interior surface of said filter wall to the exterior surface of said filter wall. The geometric form of the filter causes captured particles to travel along the interior surface towards the particle collection end in response to rotation of the filter. Filter 28 shown in fig. 2 provides a non limiting example of such a geometric form. Fluid is drawn into the fluid inlet end of the filter and out of the filter through the filter apertures (S702) . The filter is rotated in a rotation direction about the filter longitudinal axis to cause particles captured in the filter to travel along the interior surface towards the particle collection end in response to rotation of the filter (S703) . Particles leaving the particle collection end of the filter are collected (S704) .

In one embodiment, the process of drawing fluid (S702) is achieved by rotating, with the filter, a cylindrical fan blade assembly surrounding and coaxial with the filter. The fan blades are slanted in a direction relative to the rotation direction such that the fluid is drawn into the fluid inlet end of the filter and out of the filter through the apertures. By way of a non-limiting example, method S700 can be implemented utilizing sifting apparatus of fig. 2 in which cylindrical fan blade assembly 28 is a non-limiting example of such a fan blade assembly.

Alternatively, the process of drawing fluid (S702) may be achieved utilizing a fluid vacuum or fluid pumping system (not shown) having a connection inlet in fluid communication and fluid tight connection with filter apertures . Operation of the fluid vacuum and pumping system causes fluid to be drawn out of the filter apertures into the vacuum/pumping system via the vacuum/pumping system connection inlet.

The process of collecting particles leaving the filter particle collection end (S704) is preferably achieved by collecting the leaving particles into a fluid tight particle collection receptacle in fluid tight connection with the filter, for example as shown in the aforementioned embodiment of the sifting apparatus of FIG. 2. The particle collection receptacle can be connectable to and removable from the filter.

It will be appreciated that variations of the above- disclosed and other features and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Also, that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.

Claims

Claims

1. Sifting apparatus, for sifting solid particles from a fluid, comprising:

(a) a filter, having a filter wall with an interior surface and an exterior surface, having a principal longitudinal axis and tapering or narrowing in diameter between a broader open particle collection end and a narrower open fluid inlet end, and having numerous small filter apertures extending through said filter wall from said interior surface of said filter wall to said exterior surface of said filter wall; wherein said filter has a geometric tapering or narrowing form to cause captured particles to travel along said interior surface towards said particle collection end in response to rotation of said filter;

(b) a rotation means, connected to said filter, for rotating said filter in a rotation direction about said axis of said filter; and

(c) a fluid impeller means, connected to said filter, for causing said fluid to flow into said fluid inlet end of said filter and to flow out of said filter through said filter apertures .

2. The system of claim 1, further comprising

d) a particle collection receptacle operably connected to said filter at said particle collection end of said filter.

3. The sifting apparatus of claim 2, wherein said particle collection receptacle is fluid tight and in fluid tight connection with said filter.

4. The sifting apparatus of claim 1, 2 or 3, wherein said filter has the shape of a surface of revolution about said axis.

5. The sifting apparatus of any one of the preceding claims 1 to 4, wherein said fluid impeller means comprises a rotating cylindrical fan blade assembly surrounding and coaxial with said filter, connected to and rotating with said filter, said fan blades being slanted in a direction opposite said rotation direction .

6. The sifting apparatus of claim 5, further comprising baffle means, surrounding said filter and fan blade assembly, for allowing flow of said fluid through said filter only from said fluid inlet end of said filter.

7. The sifting apparatus of any one of preceding claims 1 to 4, wherein said fluid impeller means comprises a fluid vacuum/pumping system configured for drawing said fluid out of said filter via said filter apertures into said fluid vacuum system, said fluid vacuum system having a connection inlet in fluid communication and fluid tight connection with said filter apertures.

8. The sifting apparatus of any one of the preceding claims, wherein said rotation means has an electric motor or gasoline powered motor.

9. The sifting apparatus of any one of the preceding claims, wherein said filter apertures are at least substantially 1 micron in diameter.

10. The sifting apparatus of any one of the preceding claims 1 to 8, wherein said filter apertures are at least substantially 1/8 inch in diameter.

11. The sifting apparatus of any one of the preceding claims, wherein said filter is at least substantially of the shape of a frustum of a cone extending between said fluid inlet end and said particle collection end.

12. Sifting apparatus, for sifting solid particles from a fluid, comprising:

(a) a filter, having a filter wall with an interior surface and an exterior surface, having a principal longitudinal axis and having the shape of a surface of revolution about said axis, said filter tapering in diameter between a broader open particle collection end and a narrower open fluid inlet end, and having numerous small filter apertures extending through said filter wall from said interior surface of said filter wall to said exterior surface of said filter wall;

(b) a rotatable cylindrical fan blade assembly surrounding and coaxial with said filter, connected to and rotatable with said filter in a desired rotation direction, said fan blades being slanted in a direction opposite said rotation direction;

c) a rotation means, connected to said filter and to said fan blade assembly, for rotating said filter in said rotation direction about said axis of said filter; and

(d) particle collection receptacle, connected to said filter, for collecting said particles leaving said particle collection end of said filter.

13. The sifting apparatus of claim 12, further comprising

baffle means, surrounding said filter and fan blade assembly, for allowing flow of said fluid through said filter only from said fluid inlet end of said filter, and wherein said particle collection receptacle is fluid tight and in fluid tight connection with said filter .

14. The sifting apparatus of claim 12 or 13, wherein said filter is at least substantially of the shape of a frustum of a cone extending between said fluid inlet end and said particle collection end.

15. A method for sifting solid particles from fluid, the method comprising

providing a filter, said filter having a filter wall with an interior surface and an exterior surface, a longitudinal axis, a diameter tapering or narrowing between a broader open particle collection end and a narrower open fluid inlet end, numerous small filter apertures extending through said filter wall from said interior surface of said filter wall to said exterior surface of said filter wall; and having a geometric form to cause captured particles to travel along said interior surface towards said particle collection end in response to rotation of said filter;

drawing fluid into said fluid inlet end of said filter and out of said filter through said filter apertures;

rotating said filter in a rotation direction about said longitudinal axis of said filter to cause particles captured in said filter to travel along said interior surface towards said particle collection end in response to rotation of said filter; and

collecting particles leaving said particle collection end of said filter.

16. The method of claim 15, wherein collecting particles leaving said particle collection end of said filter comprises collecting said particles leaving said particle collection end into a fluid tight particle collection receptacle in fluid tight connection with said filter

17. The method of claim 15 or 16, wherein drawing said fluid into said fluid inlet end and out of said filter apertures comprises rotating, with said filter, a cylindrical fan blade assembly surrounding and coaxial with said filter; said fan blades being slanted in a direction opposite said rotation direction such that said fluid is drawn into said fluid inlet and out of said filter through said filter apertures.

18. The method of claim 15 or 16, wherein drawing said fluid in said fluid inlet end and out of said filter apertures comprises operating a fluid vacuum/pumping system having a connection inlet in fluid communication and fluid tight connection with said filter apertures such that said vacuum/pumping system draws said fluid out of said filter apertures .