This patent is directed to air balancing for a vibratory apparatus, and in particular to air balancing for a vibratory apparatus with an air knife.
According to an aspect of the present disclosure, a system includes a vibratory apparatus and an air handling system. The vibratory apparatus includes a housing having a floor with an opening therethrough, the housing defining a chamber with an inlet and an outlet, a deck disposed in the chamber between the inlet and the opening in the floor, at least a section of the deck having a plurality of apertures to permit air to flow through the section of the deck and a plenum defined beneath the section of the deck, an air knife disposed between the section of the deck and the outlet, the air knife comprising first and second surfaces spaced from each other to guide air therebetween, and a vibration generator coupled to the deck to cause motion of material along the deck. The air handling system includes a first air flow path in communication with the plenum, a second air flow path in communication with the air knife, a third air flow path in communication with a space beneath the air knife, a fourth air flow path in communication with the chamber above the deck between the inlet and the section of the deck, a return air flow path from the outlet of the chamber, and an air mover having an outlet in communication with the first, second, third, and fourth air flow paths and an inlet in communication with the return air flow path.
It is believed that the disclosure will be more fully understood from the following description taken in conjunction with the accompanying drawings. Some of the figures may have been simplified by the omission of selected elements for the purpose of more clearly showing other elements. Such omissions of elements in some figures are not necessarily indicative of the presence or absence of particular elements in any of the exemplary embodiments, except as may be explicitly delineated in the corresponding written description. None of the drawings is necessarily to scale.
Although the following text sets forth a detailed description of different embodiments of the invention, it should be understood that the legal scope of the invention is defined by the words of the claims set forth at the end of this patent. The detailed description is to be construed as exemplary only and does not describe every possible embodiment of the invention since describing every possible embodiment would be impractical, if not impossible. Numerous alternative embodiments could be implemented, using either current technology or technology developed after the filing date of this patent, which would still fall within the scope of the claims defining the invention.
It should also be understood that, unless a term is expressly defined in this patent using the sentence “As used herein, the term ‘——————’ is hereby defined to mean . . . ” or a similar sentence, there is no intent to limit the meaning of that term, either expressly or by implication, beyond its plain or ordinary meaning, and such term should not be interpreted to be limited in scope based on any statement made in any section of this patent (other than the language of the claims). To the extent that any term recited in the claims at the end of this patent is referred to in this patent in a manner consistent with a single meaning, that is done for sake of clarity only so as to not confuse the reader, and it is not intended that such claim term be limited, by implication or otherwise, to that single meaning. Finally, unless a claim element is defined by reciting the word “means” and a function without the recital of any structure, it is not intended that the scope of any claim element be interpreted based on the application of 35 U.S.C. §112, sixth paragraph.
Furthermore, while a certain spatial conventions have been adopted for purposes of illustration, these conventions are not necessarily intended to limit the installation of the system according to the present disclosure. Consequently, terms such as up and down, upstream and downstream, and inner and outer, are simply to facilitate the discussion of the illustrated embodiment as it is shown in the attached drawings.
As seen in
Furthermore, as seen in
In operation, air exiting the air knife 140 has a tendency to create a negative pressure in the space 168 beneath the air knife 140. Further, a negative pressure may be created in the general area 190 (
The air handing system 104 according to the present disclosure provides an offsetting air flow to balance the negative pressure that would otherwise develop in the space 168. As a consequence, the path of the material flowing past the knife 140 may be more predictable, providing for better and more predictable separation of the materials. A similar improvement in predictability may be achieved when the offsetting air flow is provided to the space 190. Moreover, where the offsetting flows are provided from air recycled from the outlet 120 of the chamber 116, the system 100 limits the amount of air exiting the system 100 that must otherwise be processed before it can be released.
It will be recognized that while air flow paths 164, 166 have been provided to balance the negative pressures that build below the air knife 140 and within the chamber 116, both air flow paths 164, 166 need not be provided in every embodiment of the system 100 according to the present invention. For that matter, it is not a requirement that the fluidizing stage defined by section 132 of the deck 130 be provided according to every embodiment. It is possible, according to the present disclosure, simply to provide the third air flow path 164 to balance the negative pressure that builds under the air knife 140, thereby preventing this negative pressure to draw air into the housing 110 in an uncontrolled fashion and/or amount.
Each of the apparatus 102 and the air handling system 104 is now discussed in greater detail relative to
Starting first with the apparatus 102, and referring in particular to
The apparatus 102 may also include an end wall 214 (
As seen in
Starting then at the inlet end 118 of the chamber 116, a first section 220 of the deck 130 may have a plurality of apertures therethrough, with a chute 222 disposed below the first section 220 of the deck 130. The first section 220 may be referred to as a separation stage. The plurality of apertures may be defined by a mesh or screen, and may be used for an initial separation of materials entering the vibrator apparatus 102. Materials of a certain size and weight may pass through the first section 220 of the deck 130 and the chute 222. For example, the section 220 may include a plurality of apertures sized to allow particles below one-half inch in size to pass through. The materials passing through the chute 222 may be directed onto a separate conveyor, which may be a vibratory conveyor or a belt conveyor, for example. It will be recognized that according to variants, this section 220 may be replaced with a solid plate instead (thereby eliminating the separation action of this section of the deck 130).
The material that moves along the deck 130 past the first section 220 may pass under the top wall or hood 204. A flexible flap or curtain 230 may depend from an inner surface 232 of the hood 204, and may extend to an upper surface 234 of the deck 130. A lower edge 236 of the curtain 230 may abut the upper surface 234 of the deck 130, or may be spaced therefrom. The curtain 230 may be constructed of any suitable material, including, for example, cloth, rubber, and/or the like. The curtain 230 may assist confining the materials to the section of the chamber 116 between the curtain 230 and the outlet 120 of the chamber.
As better seen in
The third section of the deck 130 is the section 132 discussed above with reference to
The section 132 of the deck 130 acts to fluidize the material moving over the screen 260. As such, the size of the apertures 134 may vary; bark chunks may require more fluidizing air and therefore may require larger apertures 134, while saw dust may require less fluidizing air and therefore may require smaller apertures 134, for example. Further, air passing through the apertures 134 causes the material passing over the deck 130 to tumble, agitating any large, bound-together clumps. The fluidizing air works the various sized parts of the disintegrating clumps, allowing the heavier fraction to collect at the bottom, or lower level, of the bed and the lighter, loose particles to bob and jump at the upper level of the bed. As a further consequence, the heavier particles may fall through the adjustable air stream formed by the air knife 140 into the opening 114 while the lighter particles may be picked up by the air stream formed by the air knife 140.
Between the air knife 140 and the outlet 120 of the chamber 116 is the opening 114 in the floor 112. The opening 114 may be referred to as a dropout opening. Once the materials moving along the deck 130 become fluidized while passing over section 132 of the deck 130, the materials pass over the air knife 140, which causes certain of the materials to be blown out over the opening 114, while other materials pass into the opening 114. To permit a greater adjustability as to the selectivity of the separation caused by the air knife 140, the apparatus 102 may include a plate assembly 270 (which may be referred to as a landing plate) that may have an adjustable length and angular position, as is illustrated in
In particular, the plate assembly 270 may includes a first plate 272 having side plates disposed on either side, one of the side plates 274 being shown in
Turning now to the space below the second and third sections 240, 132 of the deck 130, it will be recognized that two chambers or plenums are defined between the deck 130 and the floor 112 of the housing 110. One of these chambers is the plenum 136, while the other is the chamber 252 in communication with the air knife 140 and the second air flow path 162. In particular, the plenum 136 is defined at either side by the side walls 200, 202, above by the deck plate 242 and the finger screen 260, and below by a separation plate 302 (part of which may define the plate 264). The plenum 300 is defined at either side by the side walls 200, 202, above by the deck plate 242 and the separation plate 302, below by the floor 112, at one end by an end plate 304 that defines in part the chute 222, and at the other end by an adjustable deflector plate 306.
In the illustrated example, the portion 264 of the separation plate 302 and the deflector plate 306 may define the surfaces of 142, 144 of the air knife 140. The first surface 142 of the air knife 140 (and thus the plate 264, for example) has a first end 320 and a second end 322, and the second surface 144 of the air knife 140 (and thus the plate 306) has a corresponding first end 324 and a corresponding second end 326. The second surface 144 is translatable between a first position, wherein the second surface 144 is shifted towards the first surface 142 so that the first ends 320, 324 and second ends 322, 326 of the first and second surfaces 142, 144 have a first spacing therebetween, and a second position, wherein the second surface 144 is shifted away from the first surface 142 so that the first ends 320, 324 and second ends 322, 326 of the first and second surfaces 142, 144 have a second spacing therebetween, the second spacing being larger than the first spacing.
The first, or narrow, spacing may provide a high velocity air stream from the air knife 140. The high velocity air stream may be well suited for separating two or more commingled, relatively light objects, such as paper and glass. The second, wider, spacing may provide a lower velocity air stream. The low velocity air stream may be well suited for separating other, heavier commingled objects, such as wood and rock.
The apparatus 102 may be suspended, as illustrated such that the housing 110 slopes generally downward from the inlet 118 towards the outlet 120 to assist in motion of the mixture as described below. As seen in
As also seen in
Turning now to the air handling system 104 as illustrated in
Starting then at the outlet 182 of the air mover 180 with reference to
The return air flow path 170 includes more than conduits, dampers and connectors. As illustrated in
The wall 410 is also defined in part by a hood 420 that collects the air entering the box 400, and directs the air into a conduit 422. The conduit 422 is connected to an inlet 424 (see
While no system has been illustrated for the automated operation of the air handling system 104 has been illustrated, it will be recognized that the manual operation of the air mover 180 and the dampers 382, 384, 386, 388, 428 may be coordinated using automated methods. For example, one or more controllers may be connected to control the operation of the air mover 180 (through the use of a variable frequency drive, for example) and the movement of the dampers 382, 384, 386, 388, 428 (through the use of electromechanical actuators) so as to permit the air handling system 104 to be controlled from a single point, if not by a single controller. The control of the air handling system 104 may even be automated to as to be coordinated with the operation of the apparatus 102 to permit unified control of the entire system 100.
In operation, an air flow may be selected for the first and second air flow paths 160, 162 so as to optimize the fluidization and separation of the material passing through the apparatus 102 with the vibration generator 150 operating to move material along the deck 130. At the same time, air flow may be selected for the third air flow path 164 to balance the negative air pressure that builds below the air knife 140 to maintain a slight negative pressure within the chamber 120. Similarly, air flow may be selected for the fourth air flow path 166 to balance the negative pressure that builds upstream of the section 132 of the deck 130 to maintain the slight negative pressure. The air for each of the paths 160, 162, 164, 166 is obtained from the return air flow path 170, and potentially the fresh air inlet 424. The selection of the air flows 160, 162, 164, 166 may involve control of the operation of the air mover 180, as well as movement of the dampers 382, 384, 386, 388 and 428.
It will be recognized that the system according to the present disclosure may present one or more advantages relative to prior systems. According to any particular embodiment of the present system, any or all of these advantages may be present.
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Extended European Search Report from corresponding European Application No. EP10150744.0, dated Jan. 11, 2011 (3 pages). |
Number | Date | Country | |
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Number | Date | Country | |
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61144539 | Jan 2009 | US |