The present disclosure relates generally to manufacturing processes for producing a steelpan musical instrument and, more particularly (although not necessarily exclusively), to a hydroforming press machine for shaping a work piece for use in a steelpan musical instrument.
The national musical instrument of Trinidad and Tobago is the steelpan musical instrument. It can be referred to by a variety of terms, such as “steelpan,” “pan,” “steel drum,” “steel band,” or “steel orchestra.” The origins of the steelpan are generally traced back to the early part of the World War II around 1939 in Trinidad and Tobago and are often considered a product of chance and circumstance more than anything else.
What started as the hammering out of a few notes on biscuit tins, dustbin lids, and empty caustic soda drums eventually gave way to hammering out of notes in the 55 gallon steel drums that led to the “steel drum” namesake. This took much hammering of the metal and investment of many hours by the creators and early pioneers of what is now familiar as the steelpan instrument.
Traditionally, the initial sinking of a convex shape in constructing the steelpan instrument continues to be a laborious and delicate operation involving much careful hammering.
The process tends to be fraught with uncertainty and can quickly turn catastrophic in terms of lost or wasted hours of labor should the metal develop a crack at any period during the process. Given the wide and generally unknown variation in metal composition of the recycled 55 gallon drums commonly used as the starting piece for a steelpan instrument, additional unpredictability is introduced into the process, and the failure rate becomes a concern. Moreover, there can often be a latent safety risk of using recycled drums. For example, the instrument maker can receive a drum still having remnants of chemicals, which can be unknown or can remain even after a thorough cleaning.
Thus, although traditional methods of fabricating steelpan instruments have for generations produced instruments beloved by many, such traditional fabrication techniques can be subject to significant uncertainty, inefficiency, and/or health risks for the instrument makers.
The following presents a simplified summary of some embodiments of the invention in order to provide a basic understanding of the invention. This summary is not an extensive overview of the invention. It is not intended to identify key/critical elements of the invention or to delineate the scope of the invention. Its sole purpose is to present some embodiments of the invention in a simplified form as a prelude to the more detailed description that is presented later.
Various aspects described herein relate to devices, methods, and/or other features that can be implemented for improving the manufacturing process of the steelpan instrument. For example, in various situations, the fabrication of a steelpan instrument can be improved by supplying a maker or tuner of the steel pan instrument with a blank that has already been concaved. In such instances, the tuner's role can be focused on marking the notes and final tuning, rather than also investing time producing the initially concaved shape for the blank. A pre-formed blank can also be of a known thickness and consistency, which can drastically improve predictability for the tuner and reduce trial and error of finding a sweet spot of the steel to produce the desired notes. Moreover, health concerns related to toxic chemical residue can be obviated by providing a blank formed from material from a known clean source rather than from an unknown, potentially contaminated source. Various aspects described herein relate to a press or machine that can be utilized to sink a drum for a steelpan instrument in a short amount of time, such as 45 minutes, which can be a significant time savings in comparison to the 8 hours that might often be expected using traditional techniques. In addition to a faster overall turnaround time for producing the instrument when no errors are committed, use of a machine can reduce turnaround time when errors are committed. For example, even if the tuner happens to render a machine-formed pan defective, this can correspond to less than an hour of work being wasted in contrast to a full day's work being lost if the pan were instead to be initially formed by hammering by hand.
Various aspects and examples of the present disclosure are directed to apparatuses or machines for forming a work piece into a bowl subcomponent of a steel pan musical instrument. In one example, one such machine includes a pressure lid, a mold die, and a fluid passage. The mold die can be configured to receive the work piece between the mold die and the pressure lid. The mold die can include a bowl profile; a base plate including metal material; a cap plate including metal material; and at least one spacer plate including non-metal material. The spacer plate (or plates) can be positioned between the base plate and the cap plate so as to form a stacked assembly that defines the bowl profile. The fluid passage can be configured to couple with a source of pressurized fluid and arranged to introduce the pressurized fluid between the pressure lid and the work piece to exert a fluid pressure on the work piece for hydroforming in response to which the work piece is pressed against the bowl profile to be formed into the bowl subcomponent of the steel pan musical instrument.
Various aspects and examples of the present disclosure are directed to processes for use in making a steelpan musical instrument. In one example, one such method includes providing a metal sheet as a work piece from which to form at least a portion of the steel pan instrument, hydroforming the work piece into a bowl shape, and forming at least one note region in the work piece by hand hammering the note region (or regions) for the steel pan musical instrument. The method may further include coupling a skirt with the work piece. Additionally or alternatively, the method may include hydroforming the work piece into a bowl shape by hydroforming the work piece against a mold die that includes a bowl profile; a base plate including metal material; a cap plate including metal material; and at least one spacer plate including non-metal material, where the at least one spacer plate is positioned between the base plate and the cap plate so as to form a stacked assembly that defines the bowl profile.
In another example, a method of forming a steel pan musical instrument more specifically includes providing (A) a metal sheet as a work piece from which to form at least a portion of the steel pan instrument, and (B) a pressure lid including (i) a press collar, (ii) a fluid passage extending through the pressure lid, (iii) a guide shaft extending from an underside of the pressure lid, and (iv) a groove formed in the underside of the pressure lid . The method also includes coupling the press collar of the pressure lid with a hydraulic press and coupling the fluid passage of the pressure lid to a source of pressurized fluid. The method also includes installing a ring in the groove of the pressure lid and installing a forming die onto the pressure lid by engaging the forming die with the ring. The forming die can include (i) a main body having a partial dome shape and (ii) an outlet extending through the main body and in fluid communication with the fluid passage of the pressure lid when the forming die is installed on the pressure lid. The method also includes providing a mold die including (i) a face groove in an upper side, (ii) a bowl profile recessed from the upper side and positioned radially inward from the face groove, and (iii) a guide passage configured to receive the guide shaft of the pressure lid. The mold die can be provided by providing a base plate of the mold die assembly; providing at least one spacer plate of the mold die assembly; providing a cap plate of the mold die assembly; positioning the base plate, the at least one spacer plate, and the cap plate together into a stack such that the at least one spacer plate is positioned between the base plate and the cap plate; and coupling the base plate, the at least one spacer plate, and the cap plate together by extending rods through the stack and securing the rods to secure the stack together. The method also includes placing the work piece on the mold die, placing a diaphragm on the work piece, and aligning the guide shaft of the pressure lid to travel within the guide passage of the mold die so as to maintain an alignment between the pressure lid and the mold die during movement of the pressure lid relative to the mold die. The method also includes operating the hydraulic press to push the pressure lid toward the mold die so that the forming die coupled with the pressure lid engages the diaphragm for pressing the work piece into sealing engagement with the face groove of the mold die and for imparting a shape of the forming die into the work piece. The method also includes hydroforming the work piece, where the hydroforming includes: introducing pressurized fluid through the fluid passage of the pressure lid and the outlet of the forming die to the diaphragm so as to exert fluid pressure through the diaphragm to the work piece, and, in response to the fluid pressure exerted through the diaphragm to the work piece, causing the work piece to be pressed against the bowl profile of the mold die to form the work piece into a corresponding bowl shape. The method also includes operating the hydraulic press to separate the lid from the mold die and removing the work piece in the form of a bowl for incorporation into the steel pan musical instrument.
For a fuller understanding of the nature and advantages of the present invention, reference should be made to the ensuing detailed description and accompanying drawings.
Various embodiments in accordance with the present disclosure will be described with reference to the drawings, in which:
In the following description, various embodiments will be described. For purposes of explanation, specific configurations and details are set forth in order to provide a thorough understanding of the embodiments. However, it will also be apparent to one skilled in the art that the embodiments can be practiced without the specific details. Furthermore, well-known features can be omitted or simplified in order not to obscure the embodiment being described.
The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense. It will, however, be evident that various modifications and changes can be made thereunto without departing from the broader spirit and scope of the disclosure as set forth in the claims.
Referring now to the drawings, in which like reference numerals refer to like elements,
As illustrated by arrow 116, operation of the machine 100 hydroforms the blank 102 into a bowl 104 that can be a sub-component to be used for incorporating into a steel pan instrument, such as the steel pan instrument 106. In some aspects, use of the machine 100 can significantly reduce an amount of time and/or chance of inadvertent errors in creating a bowl for a steel pan instrument. For example, traditionally, as described above, a bowl for a steel pan can be hammered out of an end of a steel drum and can entail many hours (e.g., two to four) of hammering to obtain the bowl. Moreover, the hammering process by hand in many cases can be prone to mistakes that can render the bowl unsuitable for incorporation into a steel pan instrument, thus rendering much labor lost. For example, hand-hammering inadvertently with too much force may irreparably rupture or crack the bowl at a particular location, or excessive hand-hammering may render a portion of the bowl too thin or to dented to use in the steel pan musical instrument. In contrast, use of the machine 100 in some examples can allow a bowl 104 to be reproduced in a matter of 45 minutes or less and can provide a reliable fabrication process that reduces risk of labor losses from hand worked errors in fabrication. For example, the machine 100 may evenly distribute pressure to make the bowl a uniform thickness and/or avoid problems from concentrated stresses from the sharp blows of a hammer.
As illustrated at arrow 118, suitable operations can be conducted relative to the bowl 104 to fabricate the bowl 104 into a steel pan instrument 106. In some aspects, such subsequent operations can include “tuning” the bowl. For example, a laborer can hand-hammer in specific note regions 112 according to preference and design to provide distinct areas of the instrument 106 that will produce different tones when struck while being played by a musician. In some aspects, the note regions can be automatically introduced by operation of the machine rather than or in addition to being a post-processing manual operation. Other post-processing operations can include attaching the bowl 104 to a skirt 108 and/or mounting the bowl 104 on a stand 110. In some examples, coupling the skirt 108 with the bowl 104 can include welding the two components together. However, the skirt can be formed of any suitable material. Thus, although in some aspects the skirt can be metal and facilitate welding to a metal bowl 104, in other aspects, other materials (such as, but not limited to, wood, plastic, rubber, metal, non-metal materials, and/or other suitable materials) can be utilized for the skirt 108 and coupled with the bowl 104 in any suitable manner (such as via fasteners, adhesives, or other coupling methods). Similarly, the stand 110 can be metal or any other suitable material and can include suitable structure for supporting the bowl 104 and other associated components of the steel pan instrument 106 during and/or upon completion of fabrication. For example, the stand 110 can be used in positioning the note regions 112 or other elements of the steel pan instrument 106 at a conveniently accessible location for a musician during use.
In various aspects, the pressure lid 120 and associated features provide a structure in which water or other fluid can be introduced to provide pressure for forming the work piece 128 into a suitable shape in the fabrication process. The particular features depicted in
The illustrated pressure lid 120 in
In operation, the fittings 144 can be coupled with appropriate lines (e.g., tubes or hoses) in fluid communication with a pump or other pressure-raising component for introducing fluid pressure through the fittings 144. Fluid pressure introduced through the fittings 144 can be communicated through the fluid ports 142 of the pressure lid 120 to provide fluid pressure for pressing the work piece 128 into the mold die assembly 130 so that the work piece 128 deforms to match the shape of the mold die assembly 130.
The press collar 136 can receive a ram 138 of a hydraulic press in order to exert a force against the pressure lid 120 that is sufficient to withstand pressure from an opposite side of the lid 120 that can be exerted during the fabrication process. For example, in operation, the ram 138 of the hydraulic press can press against a top of the pressure lid 120 to maintain the pressure lid 120 in a closed or sealed position and counteract hydraulic forces exerted on a bottom side of the pressure lid 120 that urge the pressure lid 120 toward an open or unsealed position. In some aspects, in lieu of a hydraulic press acting on the pressure lid 120 through the press collar 136, the pressure lid 120 can be secured to the mold die assembly 130 with latches or other mechanisms capable of securing the pressure lid 120 to the mold die assembly 130 sufficiently tightly to withstand pressure build-up between the pressure lid 120 and the mold die assembly 130.
In
The guide shafts 148 shown in
The groove 146 shown in
The forming die 124 in
The diaphragm 126 can be formed of rubber or any other suitable material. The diaphragm 126 can provide a sealing interface that can seal water traveling through the fluid path (e.g., through the pressure lid 120). The diaphragm 126 further can flex in response to pressure from such water or other fluid. Thus, the diaphragm 126 can function to seal water or other fluid and also communicate pressure conveyed by such water or other fluid. In some aspects, the diaphragm is sized so that guide shafts 148 can extend into the mold die assembly without passing through the diaphragm 126. In other aspects, the diaphragm 126 can include through holes to accommodate the guide shafts 148.
The work piece 128 can correspond to the blank 102 of
The mold die assembly 130 shown in
The mold die assembly 130 shown in
The face groove 178 can facilitate sealing during operation of the machine 100. For example, the face groove 178 may function to receive a portion of the work piece 128 (e.g., in response to pressure from the ring 122 and/or forming die 124), which can form a seal that can prevent passage of pressurized fluid away from the work piece 128 during operation of the machine 100. Example operation relative to the face groove 178 is described in greater detail below beginning with reference to
In various examples, the cap plate 162 can be formed of a metal (such as a medium carbon steel or other form of steel) or other suitable material. The base plate 158 can similarly be formed of such a metal (such as a medium carbon steel or other form of steel) or other suitable material. The spacer plates 160 can be formed of polyoxymethylene or other suitable material that is more lightweight than metal. Polyoxymethylene is also known by many other names, including chemical names (such as acetal, polyacetal and polyformaldehyde) and commercial names (such as Delrin®, Celcon®, Ramtal, Duracon®, Kepital®, and Hostaform®). Using a material such as polyoxymethylene (which exhibits a high strength characteristic and/or hardness that can be suitable for such applications) can allow the mold die assembly 130 to be significantly lighter in weight (and therefore more easily transportable or portable) than if the mold die assembly 130 were instead made of a single, unitary, undivided piece. In some aspects, the spacer plates 160 can also be more easily replaced than if an entire mold die assembly 130 were to be refabricated as a unitary piece.
In
In some aspects, the rod passages 170 (
Respective ends of the rod passages 170 (
Openings 168 (
Any respective layer of the mold die assembly 130 can also include openings 168 (
Openings 168 (
In
Other features are also identified in
Relative movement of the pressure lid 120 and the mold die assembly 130 toward one another (e.g., from the position shown in
Engagement of the pressure lid 120 and the mold die assembly 130 with one another can seal components within the machine 100. For example, movement of the pressure lid 120 and the mold die assembly 130 toward one another (e.g., from the position shown in
In operation, the pressure lid 120 may withstand pressure from the fluid 190. For example, the hydraulic press ram 138 may exert force against the lid 120 to maintain the lid 120 in contact with the mold die assembly 130 and prevent the lid 120 from being pushed out of engagement with the mold die assembly 130 by forces exerted by the fluid 190. The machine 100 may additionally or alternatively include clamps or other latches in addition to or in lieu of the hydraulic press ram 138 to maintain the lid 120 in engagement with the mold die assembly 130.
Pressure can be bled off through the fittings 144 to de-pressurize the contents of the machine 100, and the pressure lid 120 can be removed from the mold die assembly 130 (e.g., via operation of the hydraulic press ram 138) to expose the formed work piece 128. Any remaining fluid 190 in the work piece 128 can be emptied (e.g., by upending the work piece 128 to cause the fluid to drain out through the drain passage 174). The formed work piece 128 can be plastically or permanently deformed to hold the shape formed by pressing against the curved surface 176 of the mold die assembly 130. The diaphragm 126 may be elastically deformed by the fluid 190 such that cessation of pressure from the fluid 190 will cause the diaphragm 126 to return to its original shape and be suitable for re-use for subsequent forming operations. The formed work piece 128 (and diaphragm 126 if present) can be removed to provide space for inserting a new work piece 128 to repeat the process.
In some aspects, the machine 100 may be operated with a different combination of components than already described. For example, in some examples, the machine 100 may be readily configurable to form work pieces 128 of different sizes for different sizes of steel pan instruments 106. In some aspects, work pieces 128 of different sizes may be formed by swapping between different variations of the mold die assembly 130, e.g., which may include different bowl profiles. In some aspects, work pieces 128 of different sizes may be formed by swapping between different variations of the pressure lid 120. For example, some variations of the pressure lid 120 may be utilized without use of the forming die 124 or with a different size of forming die 124. An illustrative example of an alternate configuration of the machine 100 is described below with respect to
In use, the ring 122 of
In use, the forming die 124 of
In use, the face groove 178 of
The process 300 at operation 310 can include assembling a machine. The machine, for example, can correspond to the machine 100 described herein.
The operation 310 can include assembling components of the pressure lid 120. For example, the operation 310 can include mounting the forming ring 122 to the pressure lid 120, such as by inserting the forming ring 122 into the groove 146 of the pressure lid 120 and/or use of any other attachment method. As another example, the operation 310 can include mounting the forming die 124 to the pressure lid 120, such as by connecting the forming die 124 to the ring 122, inserting a part of the forming die 124 into the groove 146 of the pressure lid 120, coupling the forming die 124 with fasteners through fastener apertures 184, or any combination of these or other attachment methods. In some aspects, the operation 310 may include selecting between assembling components to leave the ring 122 exposed from the pressure lid 120 or to leave the forming die 124 exposed from the pressure lid 120, for example, to facilitate production of different sizes of steel pan instrument 106 such as described with reference to
The operation 310 can include assembling components of a mold die. The mold die, for example, can correspond to the mold die assembly 130 described herein. For example, the operation 310 can include stacking one or more spacer plates 160 on a base plate 158, topping the stack with a cap plate 162, and securing the stack together (e.g., via rods 164 secured by nuts 166 or other fasteners and positioned inserted with or without sleeves 180 through rod passages 170 that extend through respective layers of the stack). In some aspects, the operation 310 may include selecting between different options for the mold die, for example, to facilitate production of different sizes of steel pan instrument 106 such as described with reference to
The process 300 at operation 320 can include aligning the pressure lid with the mold die. For example, the operation 320 can include aligning the forming ring 122 and/or the forming die 124 of the pressure lid 120 for insertion relative to the curved surface 176 and/or face groove 178 of the mold die assembly 130. Additionally or alternatively, the operation 320 can include aligning the guide shafts 148 for insertion relative to the guide passages 172. For example, tips of the guide shafts 148 can be inserted into the guide passages 172 so that further movement of the pressure lid 120 relative to the mold die assembly 130 can be constrained by travel of the guide shafts 148 in the guide passages 172 to maintain relative alignment of other features of the pressure lid 120 with the mold die assembly 130.
The process 300 at operation 330 can include receiving a work piece in the machine between the lid and the mold die. For example, the operation 330 can include placing a blank 102 or work piece 128 on the mold die assembly 130, such as on the cap plate 162 or in an indentation formed therein for holding in place. In some aspects, the blank 102 or work piece 128 can further be lubricated (e.g., with mineral or vegetable oil) before being received in the machine 100. In some aspects, the operation 330 can also include receiving a diaphragm 126 on and/or over the work piece 128. In some aspects, the operation 330 can be performed before operation 320.
The process 300 at operation 340 can include pressing the lid toward the mold die to preform the work piece. For example, the operation 340 can include pressing the forming die 124 into the work piece 128 to impart a truncated dome or frustoconical shape to a portion of the work piece 128 located near an upper section of the curved surface 176 of the bowl profile of the mold die assembly 130 and/or near the face groove 178 of the mold die assembly 130. As an illustrative example, the operation 340 may include operating a 100 ton single action hydraulic press at 55 tons to exert a force through the ram 138 on the pressure lid 120 for preforming the work piece 128.
The process 300 at operation 350 can include pressing the lid toward the mold die to seal the work piece between the lid and the mold die. For example, the operation 350 can include pressing the forming die 124 and/or the forming ring 122 into the work piece 128 and/or into the diaphragm 126 to cause sealing engagement in the face groove 178 of the mold die assembly 130. In some aspects, the operation 340 and the operation 350 may be accomplished by a single process. As an illustrative example, the operation 340 may include operating a 100 ton single action hydraulic press at 55 tons to exert a force through the ram 138 on the pressure lid 120 for sealing the work piece 128 between the pressure lid 120 and mold die assembly 130 by forcing a portion of the work piece 128 into the face groove 178 of the mold die assembly 130. In some aspects, the operation 350 can be performed independent of the operation 340. As an illustrative example, the operation 340 may be omitted (e.g., based on omitting the forming die 124 and proceeding solely with the forming ring 122), and the operation at 350 may be performed by a hydraulic press, by clamps about the pressure lid 120 and the mold die assembly 130, or by any other structure capable of pressing and/or holding the pressure lid 120 and the mold die assembly 130 together in sealing engagement. In various aspects, the operation 350 may be continued during other operations of the process 300, such as to maintain the pressure lid 120 and the mold die assembly 130 in sealed engagement during such other operations. As an illustrative example, the pressure lid 120 and the mold die assembly 130 may be maintained in sealed engagement by ongoing operation of the hydraulic press (such as holding at 55 tons) or by clamps to counteract forces that may be exerted on the pressure lid 120 and/or other components of the machine 100 during operations 350 and 370 described below.
The process 300 at operation 360 can include providing pressurized fluid between the lid and the work piece to form the work piece to the mold die. For example, the operation 360 can include introducing fluid 190 through the fittings 144 to exert fluid pressure against the work piece 128 (e.g., via the diaphragm 126, if present) to form the work piece 128 to the mold die assembly 130 (such as to cause the work piece 128 to adopt the shape of the curved surface 176 and indentations 179, if present). In an illustrative example, the fluid 190 can be pressurized to 1500 PSI and that pressure can be held for a suitable amount of time (e.g., 15 seconds) to provide sufficient pressure to deform the work piece 128 into a shape conforming to the mold die assembly 130. In some aspects, progress of the forming may be detectable via observation through the drain passage 174 in addition to or in lieu of imparting a threshold pressure for a pre-determined amount of time. For example, if a threshold pressure such as 1500 PSI is not obtained, pressurizing can be continued until it is confirmed through observation through the drain passage 174 that the work piece 128 has been sufficiently deformed to adopt the shape of the mold die assembly 130.
In some aspects, providing pressurized fluid in the operation 360 can include expelling air that might otherwise be present in the machine 100 when initiating pressurization. For example, at least one of the fittings 144 can function or be operated as a relief valve. The relief valve can be maintained in an open condition to allow venting of air as water or other fluid is initially introduced through another fitting 144 to initiate pressurization. When water or other fluid introduced through another fitting exits through the relief valve, this may indicate that all air has been vacated and that the relief valve can be closed to facilitate increasing the pressure of the water or other fluid.
The process 300 at operation 370 can include de-pressurizing the machine. For example, the operation 370 can include bleeding off pressure through one or more of the fittings 144. The operation 370 can also include separating the pressure lid 120 from the mold die assembly 130, such as by pulling the pressure lid 120 away by force of the hydraulic press ram 138.
The process 300 at operation 380 can include removing the work piece from the machine. For example, the operation 380 can include extracting the work piece 128 from the face groove 178 of the mold die assembly 130 following separation of the pressure lid 120 from the mold die assembly 130.
The process 300 at operation 380 can include incorporating the work piece into a steel pan musical instrument. For example, the operation 380 can include tuning the work piece 128, such as by hand hammering to make indentations to form note regions 112 or checking and/or correcting note regions 112 introduced by the machine 100 via indentations 179 if present in the mold die assembly 130. As further examples, the operation 380 can include coupling the work piece 128 to a suitable skirt 108 and/or stand 110, such as by welding or any other suitable coupling method.
Other variations are within the spirit of the present disclosure. Thus, while the disclosed aspects are susceptible to various modifications and alternative constructions, certain illustrated embodiments thereof are shown in the drawings and have been described above in detail. It should be understood, however, that there is no intention to limit the disclosure to the specific form or forms disclosed, but on the contrary, the intention is to cover all modifications, alternative constructions and equivalents falling within the spirit and scope of the disclosure, as defined in the appended claims.
The use of the terms “a” and “an” and “the” and similar referents in the context of describing the disclosed embodiments (especially in the context of the following claims) are to be construed to cover both the singular and the plural, unless otherwise indicated herein or clearly contradicted by context. The terms “comprising,” “having,” “including,” and “containing” are to be construed as open-ended terms (i.e., meaning “including, but not limited to,”) unless otherwise noted. The term “connected” is to be construed as partly or wholly contained within, attached to, or joined together, even if there is something intervening. Recitation of ranges of values herein are merely intended to serve as a shorthand method of referring individually to each separate value falling within the range, unless otherwise indicated herein and each separate value is incorporated into the specification as if it were individually recited herein. All methods described herein can be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context. The use of any and all examples, or exemplary language (e.g., “such as”) provided herein, is intended merely to better illuminate embodiments of the disclosure and does not pose a limitation on the scope of the disclosure unless otherwise claimed. No language in the specification should be construed as indicating any non-claimed element as essential to the practice of the disclosure.
Disjunctive language such as the phrase “at least one of X, Y, or Z,” unless specifically stated otherwise, is intended to be understood within the context as used in general to present that an item, term, etc., can be either X, Y, or Z, or any combination thereof (e.g., X, Y, and/or Z). Thus, such disjunctive language is not generally intended to, and should not, imply that certain embodiments or aspects require at least one of X, at least one of Y, or at least one of Z to each be present.
Preferred embodiments of this disclosure are described herein, including the best mode known to the inventors for carrying out the disclosure. Variations of those preferred embodiments can become apparent to those of ordinary skill in the art upon reading the foregoing description. The inventors expect skilled artisans to employ such variations as appropriate and the inventors intend for the disclosure to be practiced otherwise than as specifically described herein. Accordingly, this disclosure includes all modifications and equivalents of the subject matter recited in the claims appended hereto as permitted by applicable law. Moreover, any combination of the above-described elements in all possible variations thereof is encompassed by the disclosure unless otherwise indicated herein or otherwise clearly contradicted by context.
All references, including publications, patent applications and patents, cited herein are hereby incorporated by reference to the same extent as if each reference were individually and specifically indicated to be incorporated by reference and were set forth in its entirety herein.
This application is a continuation of U.S. patent application Ser. No. 16/486,465 (“the '465 application”), filed Aug. 15, 2019 as the United States national phase entry under 35 USC § 371 of International Patent Application No. PCT/IB2017/055922 (“the '922 application”), filed Sep. 27, 2017. The '465 application and the '922 applications are hereby incorporated in their entireties by this reference.
Number | Date | Country | |
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Parent | 16486465 | Aug 2019 | US |
Child | 16855091 | US |