The present disclosure relates generally a shredding apparatus, and more particularly to a shredder lubrication system for the shredding apparatus.
Industrial shredding machines are utilized in a wide array of industries such as metal parts and scrap, consumer and industrial waste recycling, construction debris processing, etc. to break-up a variety of materials into smaller constituents. Such operation may be performed in connection with incineration where the shredded materials are transported to furnaces for recycling.
Generally, shredders are a single structure including a cutting or shredding assembly, an upper supply housing for supplying materials to the shredding assembly, a lower discharge duct for collecting and discharging comminuted materials, and a supporting structure fixed to the shredding assembly. The shredding assembly is driven by a drive assembly (e.g., motors, gears, bearings) designed to drive rotation of the cutters/shredders. One type of shredding assembly includes two shredding shafts with transversely extending shredding knives that mesh with one or more sets of transversely extending fixed counter knives or fingers. The fingers prevent the material (e.g., scrap metal) from bypassing the shredding assembly, so that the material to be shredded is forced through the shredding knives between the shredding shafts.
However, a wide variance exists in the expected lifespans of the machine components. For example, certain high wear components such as the shredding knives may become degraded prior to degradation of other components, such as the fingers or drive assembly. It is of outmost importance to reduce the down-time of shredder machines as much as possible, considering that they operate almost constantly, e.g., for 20 hours of 24 hours. To access internal components of the shredding assembly, many shredder machines required disassembly of the upper supply housing and/or the lower discharge duct together with the supporting structures from the shredding assembly, making repairs time consuming and costly.
A technique employed to reduce degradation of components, and particularly the shredding knives, has been to lubricate the rotating parts by pouring oil onto the shredding knives as the material to be shredded is loaded into the shredding assembly. However, such a technique leads to significant waste and the potential of igniting the furnace with the oil-soaked shredded material.
Overcoming these concerns would be desirable. Thus, there is a need for an improved shredder lubrication system.
While the claims are not limited to a specific illustration, an appreciation of the various aspects is best gained through a discussion of various examples thereof. Although the drawings represent illustrations, the drawings are not necessarily to scale and certain features may be exaggerated to better illustrate and explain an innovative aspect of an example. Further, the exemplary illustrations described herein are not intended to be exhaustive or otherwise limiting or restricted to the precise form and configuration shown in the drawings and disclosed in the following detailed description. Exemplary illustrates are described in detail by referring to the drawings as follows:
In the drawings, where like numerals and characters indicate like or corresponding parts throughout the several views, exemplary illustrates are shown in detail. The various features of the exemplary approaches illustrated and described with reference to any one of the figures may be combined with features illustrated in one or more other figures, as it will be understood that alternative illustrations that may not be explicitly illustrated or described may be able to be produced. The combinations of features illustrated provide representative approaches for typical applications. However, various combinations and modifications of the features consistent with the teachings of the present disclosure may be desired for particular applications or implementations.
The present disclosure relates to a shredder lubrication system for a shredder machine or shredder apparatus (hereafter shredder apparatus). The shredder lubrication systems provides a minimum quantity lube (MQL) on the shredding knives and/or fingers to save on lubrication consumption and costs, while reducing wear and degradation of components. The lubricant (e.g., oil, air, water, or a combination thereof) is introduced through the cassette housing to the knife and finger interface to reduce material galling and keep shredder components lubricated and cool.
According to a first aspect, there is provided a shredder cassette of a shredder lubrication system that supplies lubricant via the shredder fingers during operation. The shredder cassette includes a cassette housing, at least two shredding shafts arranged in parallel and rotatably mounted in the cassette housing about respective rotation axes, a first set of fingers arranged between the cassette housing and a first of the at least two shredding shafts, and a second set of fingers arranged between the cassette housing and a second of the at least two shredding shafts. At least one of the first set of fingers and the second set of fingers includes finger lubricating channels for lubricating the at least two shredding shafts.
At least one lubricant supply channel is provided extending axially along the at least one of the first set of fingers and the second set of fingers for supplying lubricant to the finger lubricating channels. Pursuant to an implementation, the at least one lubricant supply channel is provided in a side wall of the cassette housing that is connected to the at least one of the first set of fingers and the second set of fingers. For example, the at least one lubricant supply channel may be drilled or bored into the side wall.
The side wall may have radial supply ports fluidly connecting the at least one lubricant supply channel with the finger lubricating channels. The radial supply ports extend radially to the respective rotation axes and are disposed radially between the at least one lubricant supply channel and the finger lubricating channels. The side wall may additionally have a fluid inlet fluidly connected to the at least one lubricant supply channel. The fluid inlet is fluidly connected to a supply opening in the shredder cassette receiver, which supply opening is connected to a source (e.g., hose) for conveying lubricant through the cassette housing.
An axially extending lubricant supply manifold may be disposed radially between the radial supply ports and the finger lubricating channels. The lubricant supply manifold may be continuous in the axial direction, or may be discontinuous in the axial direction and be divided into multiple discrete supply manifolds that distribute lubricant to groups of finger lubricating channels.
The finger lubricating channels may extend in individual fingers from the cassette housing in a radial direction towards the at least two shredding shafts. The finger lubricating channels may be provided in all of the individual fingers, or may skip or alternate fingers depending on lubrication demand. The finger lubricating channels respectively have at least one outlet opening disposed on an axial side of the individual fingers. Pursuant to an implementation, the finger lubricating channels have two outlet openings in each case, which are disposed on both (or opposite) axial sides of the individual fingers. The outlet opening(s) may extend obliquely to the respective finger lubricating channel.
The shredder cassette may additionally comprise shredding shafts that supply lubricant to the knife/finger interface, in addition to the first and/or second set of fingers. For example, at least one of the two shredding shafts comprises a hollow shaft defining a hollow interior that provides a central lubrication delivery channel, and a plurality of openings disposed on the hollow shaft and extending from an outer surface to the hollow interior thereof. Lubricant may be supplied from the central lubrication delivery channel to the knife/finger interface via the plurality of openings.
According to a second aspect, there is provided a shredder cassette of a shredder lubrication system that supplies lubricant via the shredding shafts during operation. The shredder cassette includes at least one shredding shaft mounted in a cassette housing. The at least one shredding shaft comprises a hollow shaft defining a hollow interior that provides a central lubrication delivery channel, and a plurality of openings disposed on the hollow shaft and extending from an outer surface to the hollow interior thereof for lubricating the at least one shredding shaft.
The at least one shredding shaft includes a plurality of shredding knives, and the plurality of openings may open into a hub of each of the plurality of shredding knives. The plurality of shredding knives may include at least one knife lubricating channel extending from an inner surface of the hub to a radially outer surface, to provide lubricant to the knife/finger interface during operation. Pursuant to an implementation, the at least one knife lubricating channel opens to the radially outer surface at a base of a blade of the plurality of shredding knives. Additionally or alternatively, the plurality of shredding knives have internal splines disposed on the inner surface of the hub, and a lubricating groove extends through the internal splines in a circumferential direction of the hollow shaft. The lubricating groove allows lubricant to flow in a circumferential direction from the associated opening to an inlet of the knife lubricating channel.
Pursuant to an implementation, the plurality of openings are arranged in a helical pattern along the shaft. For example, the openings may be rotated or circumferentially offset relative to in predefined increments corresponding to the clocking requirements of the shredding knives (e.g., 10 or 12 degree increments).
The at least one shredding shaft may include a lubricant supply inlet disposed at a longitudinal end of the hollow tube, the lubricant supply inlet being structured and arranged to permit lubricant to be delivered to the central lubrication delivery channel. The lubricant supply inlet may be fluid connected to a source (e.g., hose) for conveying lubricant in the shredder lubrication system.
The shredder cassette may additionally include shredding fingers that that supply lubricant to the knife/finger interface, in addition to the at least one shredding shaft. For example, the cassette housing may include at least one set of fingers arranged between the cassette housing and the at least one shredding shaft, wherein the at least one set of fingers includes finger lubricating channels for lubricating the at least one shredding shaft.
According to a third aspect, there is provided a shredding module of a shredder lubrication system that supplies lubricant via the shredding shafts and/or shredding fingers during operation. The shredding module includes a shredder cassette receiver and a shredder cassette received within the shredder cassette receiver. The shredder cassette includes two shredding shafts having shredding knives arranged in parallel and rotatable about a respective rotation axis, and two sets of fingers that cooperate with the two shredding shafts to shred material. At least one of the two sets of fingers include finger lubricating channels extending from the shredder cassette towards the two shredding shafts for supplying lubricant to the shredding knives. Additionally or alternatively, at least one of the two shredding shafts comprises a hollow shaft defining a hollow interior that provides a central lubrication delivery channel, and a plurality of openings disposed on the hollow shaft and extending from an outer surface to the hollow interior thereof for supplying lubricant to the shredding knives.
Implementations of the disclosure may include combinations of the above-described features. Details of these and other aspects of the disclosure will be apparent from the following discussion of but one non-limiting example of a shredder apparatus comprising a quick change shredder cassette and/or an improved lubrication system.
Referring now to
The shredding apparatus 100 is intended for stationary use and includes a stationary support structure or support frame (not shown), which may comprise a conventional table or bench with legs positioned on the ground. Other implementations of the shredding apparatus 100 may be mobile where the stationary frame may be replaced with some other supporting structure. In the illustrated example, the shredding apparatus 100 is positioned on the ground by a conventional stand or support legs (not shown). The shredding apparatus 100 includes a shredding module 102 comprising a shredder cassette 104 and a shredder cassette receiver 106. The shredding module 102, e.g., the shredder cassette 104 and the shredder cassette receiver 106, are shown with a rectangular shape, although other shapes are contemplated. The shredder cassette receiver 106 may form part of the support/stationary frame, or may be a separate component attached to the support/stationary frame. The shredder cassette 104 includes one or more cutting or shredding shafts 108 rotatably mounted therein, for shredding/cutting material such as metal scrap (e.g., aluminum scrap). In the illustrated example, the shredder cassette 104 includes two shredding shafts 108 arranged in parallel and rotatable about a respective rotation axis A. At least one drive module 110 is mounted to the shredding module 102 for driving the shredding shaft(s) 108.
The shredder apparatus 100 includes an upper supply housing 112 is mounted on top of the support frame (e.g., in relation to the ground) for supplying material to be shredded to the shredding module 102, and a lower discharge duct 114 mounted underneath the support frame for discharging and conveying shredded material. The upper supply housing 112 is connected to a top of the shredder cassette receiver 106 and the lower discharge duct 114 is connected to a bottom of the shredder cassette receiver 106. Pursuant to an example, the upper supply housing 112 and/or the lower discharge duct 114 are detachably connected to the shredder cassette receiver 106, so that they may be customized for each user and adapted to the waste material type. Pursuant to another example, the upper supply housing 112 and/or the lower supply duct 114 are integrally formed with the shredder cassette receiver 106 to reduce parts and assembly time.
As shown in
With reference to
In the illustrated example, two drive modules 110A, 110B are positioned on opposite longitudinal ends of the shredding module 102 and operatively connected to the at least two shredder shafts 108 for driving the shredder shafts 108 independently to allow the speeds and direction to be controlled separately. During operation, the shredding shafts 108 rotate in opposite direction, toward each other, but may also be controlled to rotate away from each other or combinations thereof. A first or front drive module 110A is drivingly connected to the first shredding shaft 108A and a second or rear drive module 110B is drivingly connected to the second shredder shaft 108B. The drive module(s) 110A, 110B may comprise one or two motors 124 (e.g., hydraulic and/or electric) and a gearbox 126 that couples the motor(s) 124 to the associated shredding shaft 108. The drive module(s) 110A, 110B include a mounting plate 128 detachably coupled to (e.g., via screws/bolts) a longitudinal end of the shredder cassette 104 and/or the shredder cassette receiver 106.
With reference to
To facilitate attaching/detaching the drive module(s) 110 from the shredding module 102, the shredder cassette 104 may have, on an outer face or surface of the first/front end plate 130, positioning aids 134 that mate with counter positioning aids (not shown) on an inner surface of the mounting plate 128 of the first/front drive module 110A. For example, the positioning aids 134 may comprise grooves or slots on the end plate 130 that mate with ridges or protrusions on the mounting plate 128, or vice versa. It is also contemplated that the shredder cassette receiver 106 and/or rear end plate 132 has positioning aids on its outer surface that mate with counter positioning aids disposed on an inner surface of the mounting plate 128 of the second/rear drive module 110B, to likewise facilitate assembly/disassembly efficiencies.
With reference to
The first end plate 130 and the second end plate 132 mount a first longitudinal end 152 and a second longitudinal end 154 of the two shredding shafts 108, respectively, via bearing openings 156. The bearing openings 156 receive bearings 158 on which the shredder shafts 108 rotate. Pursuant to an implementation, the first end plate 130 and the second end plate 132 define semi-circular openings 160A that receive first and second bearing blocks or inserts 162 defining corresponding counter semi-circular openings 160B that are positioned above and aligned with the semi-circular openings 160A of the first and second end plates 130, 132, wherein the semi-circular openings 160A and the counter semi-circular openings 160B together define the bearing openings 156. The first and second bearing blocks 162 can be inserted into and removed from engagement with the first and second end plates 130, 132, so that the shredder shafts 108 can be loaded from the top into the shredder cassette 104 to facilitate assembly/disassembly efficiencies. The two inner end walls 148, if provided, may likewise each comprise two components having semi-circular openings aligned with each other and axially aligned with the bearing openings 156, as shown in
The first set of fingers 120 are arranged between a first side wall 140 and the first shredding shaft 108A, and the second set of fingers 122 are arranged between a second side wall 142 and the second shredding shaft 108B. The first and second set of fingers 120, 122 are fastened to the associated side wall 140, 142, e.g., via screws, to facilitate removal and replacement should the fingers 118 become degraded or broken. However, it is also contemplated that the first and second set of fingers 120, 122 may be integrally connected (e.g., welded) to the associated side wall 140, 142. Each set of fingers 120, 122 includes a plurality of fingers 118 disposed on a base 164 and extending crosswise or transversely in relation to the shredding shafts 108 and are mutually spaced by openings in the axial direction 166. The individual fingers 118 (or scrapers) may be interchangeable and independently replaceable such that only a broken or degraded finger 118 need be serviced instead of removing the entire set to save on cost, such as by removing a bolt/screw securing the finger 118 to the base 164. Each set of fingers 120, 122 may be divided into groups comprising a number of fingers (e.g., 2, 3, or 4 fingers) associated with a common base 164 and detachably fastened to the side wall 140, 142, to facilitate replacing broken fingers 118 without having to remove the whole set of fingers 120, 122 during repair, thereby reducing downtime and costs associated with repair. In the example shown (see
The shredding shafts 108 each comprise a rotatable shaft tube 168 and a set of disc-shaped shredding knives 116 mounted on the shaft tube 168 at mutually spaced intervals in the axial direction 166. The shredding knives 116 extend partly into the openings between the fingers 118. The shaft tube 168 includes a stop collar 172 at one end (see
As shown in
Referring to
The two side plates 186, 188 include at least one slide projection 194, projecting radially inwards, that includes, but is not limited to, a pin, a wheel or roller slide, and a cam follower (hereafter cam follower 194) on a radially inner surface thereof that interacts with the at least one guide track 144 on the radially outer surface of the side walls 140, 142 of the shredder cassette 104. The cam follower 194 may comprise a stud or pin type follower, or a wheel or roller follower where a wheel is arranged on a radially projecting pin anchored to the shredder cassette receiver 106. The cam follower 194 engages into the guide track 144 (e.g., a race or groove on the side walls 140, 142) to facilitate the (axial) sliding movement between the shredder cassette 104 and the shredder cassette receiver 106. Although the following description refers to a cam follower 194, it will be appreciated that a simple pin/stud, wheel slide, or ball bearing slide may be used in place of the cam follower without departing from the scope of the disclosure.
Pursuant to the illustrated example, the two side plates 186, 188 may each include one or a plurality of upper cam followers 194A that engage with the respective upper guide track 144A of the two side walls 140, 142. The upper cam follower 194A, or the forward cam follower 194A if multiple are provided, is positioned at an axial location on the respective side plate 186, 188 that stops the shredder cassette 104 at a predefined insertion depth when it reaches the end of the upper guide track 144A, to aid in properly positioning the shredder cassette 104 in the shredder cassette receiver 106 in the assembled state. The two side plates 186, 188 may additionally each include one or a plurality of lower cam followers 194B that engage with the respective lower guide track 144B of the two side walls 140, 142 of the shredder cassette 104. The cam follower(s) 194 and guide track(s) 144 facilitate slidably moving the shredder cassette 104 in the axial direction 166 relative to the shredder cassette receiver 106. To stop the shredder cassette 104 from being removed entirely from the shredder cassette receiver 106 without first properly securing the shredder cassette 104 (e.g., via a harness or table), one or both side plates 186, 188 may have a bore 196 that receives a safety pin 198 (see also
With reference to
The shredder cassette receiver 106 has a supply opening 204 in one or both side plates 184, 186 for the introduction of lubricant into the shredding module 102. The supply opening 204 may be connected to a hose (not shown) for a supply of lubricant. The lubricant may include air, oil, water, or a combination thereof (e.g., air over oil).
The shredder cassette 104 includes a supply inlet 206 in communication with the supply opening 204 of the shredder cassette receiver 106. The supply inlet 206 may be arranged in one or both side walls 140, 142 and aligned with the supply opening 204, to reduce flow resistance and back pressure. A lubricant supply channel 208 extends axially along the first and/or second set of fingers 120, 122 for supplying lubricant from the supply inlet 206 to the lubricating channels 202. The lubricant supply channel 208 may be formed in, e.g., bored or drilled, the side wall(s) 140, 142 of the cassette housing 138. Radially inwards of the lubricant supply channel 208, radial supply ports 210 may be provided in the side wall(s) 140, 142 to communicate lubricant from the lubricant supply channel 208 to the lubricating channels 202. The radial supply ports 210 are distributed axially in the side wall 140, 142 along the lubricant supply channel 208. The radial supply ports 210 accordingly penetrate a radially inner surface of the associated side wall 140, 142, and the supply inlet 206 penetrates a radially outer surface of the associated side wall 140, 142, with the lubricant supply channel 208 extending in the axial direction 166 between the radial supply ports 210 and the supply inlet 206. The supply inlet 206 may open into the lubricant supply channel 208 at a position axially offset from the radial supply ports 210 so that the incoming flow is split or diverted axially by the channel wall towards the front and rear of the shredder cassette 104 to facilitate a more uniform lubricant flow.
A lubricant supply manifold 212 may be disposed radially between the radial supply ports 210 and the lubricating channels 202. The lubricant supply manifold 212 extends axially along the associated set of fingers 120, 122 (e.g., parallel to the lubricant supply channel 208) and may be formed in the base 164 (e.g., a drilled or bored chamber in the base 164) or formed on the base 164 (e.g., as a groove on the radially outer side of the base 164). The lubricant supply manifold 212 may be continuous or discontinuous in the axial direction 166. For example, the lubricant supply manifold 212 may connect lubricating channels 202 of different groups of fingers 118 together (discontinuous), or may be used to connect lubricating channels 202 of the whole set of fingers 120, 122 together (continuous). The illustrated example of
The lubricating channels 202 extend in the radial direction in individual fingers 118 from the cassette housing 138 or respectively the lubricant supply manifold 212 towards the at least two shredding shafts 108. The lubricating channels 202 may extend in each finger 118, or may alternate fingers 118, depending on design and lubrication requirements. At a distal end of the finger 118, the lubricating channel 202 has at least one outlet opening 214 (see also
During operation of the shredder lubrication system 200, a supply of lubricant (e.g., air, oil, water, or a combination thereof such as air over oil) is provided from the supply opening 204 in the shredder cassette receiver 106 to the supply inlet 206 in the cassette housing 138, enters the lubricant supply channel 208 and is distributed among the radial supply ports 210 to the lubricant supply manifold 212, where lubricant proceeds through the lubricating channels 202 and exits at the outlet openings 214 at the finger/knife interface to lubricate the shredding shafts 108. The lubricant is applied via the outlet openings 214 to the waste material (e.g., metal scrap) as it is shredded to reduce galling as well as lubricate and cool the shredding knives 116 and fingers 118. The lubricant may be replaced/supplied continuously (e.g., a continuous feed/supply of lubricant is provided to the system 200) or may be replaced/supplied on demand or periodically as needed. The lubrication system 200 provides an MQL system for the shredding module 102 to save on the amount of lubricant consumed and the cost thereof, and accordingly reduces the risk of furnace ignition as compared with conventional lubrication techniques. Additionally, the lubrication system 200 facilitates more uniformly lubricating the knives 116 and fingers 118 through the dedicated lubricating channels 202 and distribution of outlet openings 214, thereby reducing wear and degradation of the shredding components (e.g., knives 116 and fingers 118). The improved lubrication of the shredding components also leads to reduced degradation of the drive assembly (e.g., gears), owing to reduced resistance and torque on the shredding shafts 108.
Referring to
With reference to
The central lubrication delivery channel 304 is formed by the inner surface 312 of the hollow shaft tube 168 defining the hollow interior 302 and extends along the axial direction 166 of the shaft tube 168. At a longitudinal end 152, 154 of the shaft tube 168, a lubricant supply inlet 316 may be provided to permit lubricant to be delivered to the central lubrication delivery channel 304. The lubricant supply inlet 316 may communicate with a lubricant source (not shown) such as a lubricant tube threaded through the associated drive module 110.
Referring to
Although the knife lubricating channel 308 is shown extending from the inner surface 318 of the hub 178 to the radially outer surface 320 of the shredding knife 116, it will be appreciated that the knife lubricating channel 308 may instead extend from the inner surface 318 of the hub 178 to an outer surface (e.g., outer diameter) of the hub 178 (e.g., through the spacer 184) without departing from the scope of the disclosure.
During operation of the shredder lubrication system 300, a supply of lubrication (e.g., air, oil, water, or a combination thereof) is provided from the lubricant supply inlet 316, e.g., via a lubricating tube coupled thereto acting as a source, to the central lubrication delivery channel 304 wherein the lubricant is distributed to the plurality of openings 306 arranged along the shaft tube 168. The lubricant is communicated from the openings 306 to the knife lubricating channel(s) 308 of the plurality of knives 116, where the lubricant exits the outlet 324 thereof in a region of the blade 182 at the knife/finger interface to lubricate the shredding components (e.g., knives 116 and fingers 118), thereby reducing wear and degradation thereof. The lubricant may be communicated from the central lubrication delivery channel 304 directly to the knife lubricating channel 308 where the opening 306 at the outer surface 310 of the shaft tube 168 is aligned with the inlet 322 of the knife lubricating channel 308, or the lubricant may travel through the lubricating groove 328 formed in the splines 176, 180 along the circumferentially extending lubrication path between the shaft tube 168 and the hub 178 of the shredding knives 116 when the opening 306 is rotated or offset from the inlet 322 of the knife lubricating channel 308. The lubricant that exits the knife lubricating channel 308 is applied to the waste material (e.g., metal scrap) to reduce galling. The lubricant may be replaced/supplied continuously (e.g., a continuous feed/supply of lubricant is provided to the system 300) or may be replaced/supplied on demand or periodically as needed. The lubrication system 300 provides an MQL system for the shredding module 102 to save on the amount of lubricant consumed and the cost thereof, and accordingly reduces the risk of furnace ignition as compared with conventional lubrication techniques.
It will be appreciated that the aforementioned, apparatus 100, system 200, 300 and/or method may be modified to have some components and steps removed, or may have additional components and steps added, all of which are deemed to be within the spirit of the present disclosure. For example, while the guide tracks 144 on the two side walls 140, 142 of the shredder cassette 104 are described as grooves, it will be appreciated that the grooves of the guide tracks 144 may be disposed on side plates 186, 188 of the shredder cassette receiver 106 and the cam followers 194 are disposed on the side walls 140, 142 of the shredder cassette 104. As another example, although the shaft tube 168 has been described as splined, it will be appreciated that the shaft tube 168 may have a hexagonal outer profile that engages with a hexagonal inner profile of the hub 178 of the shredding knives 116 without departing from the scope of the disclosure. Accordingly, even though the present disclosure has been described in detail with reference to specific examples, it will be appreciated that the various modifications and changes can be made to these examples without departing from the scope of the present disclosure as set forth in the claims. It is anticipated and intended that future developments will occur in the technologies discussed herein, and that the disclosed method, device and/or article will be incorporated into such future developments. Thus, the specification and the drawings are to be regarded as an illustrative thought instead of merely restrictive thought.
As used herein, spatial or directional terms such as “top,” “bottom,” “upper,” “lower,” “up,” “down,” “left,” “right,” “first,” “second,” “third,” and the like, relate to the illustrations shown in the figures and are not to be considered as limiting. Further, all numbers expressing dimensions, ratios and the like, used in the specification and claims, are to be understood to encompass tolerances and other deviations as represented by the term “about” or “approximately.” Moreover, all ranges disclosed herein are to be understood to encompass any and all sub-ranges subsumed therein.
All terms used in the claims are intended to be given their broadest reasonable constructions and their ordinary meanings as understood by those knowledgeable in the technologies described herein unless an explicit indication to the contrary in made herein. In particular, use of the singular articles such as “a,” “the,” “said,” etc. should be read to recite one or more of the indicated elements unless a claim recites an explicit limitation to the contrary. Further, the use of “at least one of” is intended to be inclusive, analogous to the term and/or. Additionally, use of adjectives such as first, second, etc. should be read to be interchangeable unless a claim recites an explicit limitation to the contrary.
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