This application relates to saw blades (e.g., linear edge saw blades such as reciprocating saw blades, jigsaw blades, bandsaw blades, and holesaws) with set cutting teeth (e.g., set hard metal cutting teeth).
A linear edge saw blade (e.g., reciprocating saw blades, jigsaw blades, bandsaw blades, and holesaws) generally has an elongated body with an elongated cutting edge having a plurality of cutting teeth. At least some of the teeth may be set to the left and right in a repeating pattern (e.g., unset or raker, left set, right set). Setting the teeth in this manner may improve cutting performance and/or life of a reciprocating saw blade by creating a wider kerf when cutting a workpiece.
Linear edge saw blades for cutting metal or other hard or abrasive workpieces may include hard metal (e.g., carbide) cutting tips or inserts that are welded, brazed, or otherwise affixed to the tips of the cutting teeth or tooth holders of the saw blade (see, for example, US Pat. App. Pub. No. 2013/0333541). At least some of the teeth that hold the hard metal cutting tips may be set left or right. However, it is impractical to attach hard metal cutting inserts or tips to such a saw blade having a fine pitch (e.g., a pitch finer than or equal to 12 teeth per inch (tpi) (i.e., having greater than or equal to 12 tpi)) because the tips or inserts are too small to effectively weld, braze, or otherwise attach them to the teeth of the saw blade body.
Linear edge saw blades for cutting metal or other hard or abrasive workpieces may alternatively include a body with a strip or multiple strips of hard metal (e.g., carbide) each having a plurality of full teeth (as opposed to hard metal cutting tips), with the strips welded, brazed, or otherwise attached to a softer metal body that has no cutting teeth (see, for example, GB Patent Specification No. GB840,784 and German Patent Publication No.
DE323622). In these designs, the strips generally have a length of 1.5 inches or more and the teeth are unset and generally have a trapezoidal cross-section when viewed from the rake face of the tooth. Setting these types of hard metal strips with full cutting teeth is difficult for several reasons. First, because of the length of these strips, they tend to have a large number of teeth per strip, and attempting to set teeth on a single carbide strip in different directions is extremely difficult and tends to cause fracturing of the teeth or carbide strip. Also, even if all the teeth in a strip are set the same direction, this setting operation tends to cause weakness in the joint used to attach the carbide strips to the blade body and/or causes the carbide teeth to be damaged while being set due to the high hardness and poor fracture toughness of the carbide.
In an aspect, a saw blade includes an elongated body extending along a longitudinal axis and having an elongated cutting edge. A first hard metal strip is attached to a first portion of the cutting edge and includes at least one first full hard metal cutting tooth that is set left at a first angle relative to a vertical axis of the body that is generally perpendicular to the longitudinal axis. A second hard metal strip attached to a second portion of the cutting edge and includes a second full hard metal cutting tooth that is set right at a second angle relative the vertical axis.
Implementations of this aspect may include one or more of the following. The at least one first hard metal cutting tooth may include at least two first full hard metal cutting teeth. The at least one second hard metal cutting tooth may include at least two second full hard metal cutting teeth. The first hard metal strip may be attached to the first portion of the cutting edge by welding with a first weld fusion zone composed of a ductile material. The at least one first full hard metal cutting tooth may be set left by applying a lateral force to bend the first weld fusion zone. The second hard metal strip may be attached to the first portion of the cutting edge by welding with a second weld fusion zone composed of a ductile material. The at least one second full hard metal cutting tooth may be set right by applying a lateral force to bend the second weld fusion zone. The at least one first tooth may be set left by forming a left side face of the at least one tooth to be angled away from the vertical axis.
A right side face of the at least one first tooth may be formed to be angled relative to the vertical axis at an angle that is substantially the same as the first angle, so that the at least one first tooth has the shape of a parallelogram. The at least one second tooth may be set right by forming a right side face of the at least one tooth to be angled away from the vertical axis by the second angle. A left side face of the at least one second tooth may be formed to be angled relative to the vertical axis at an angle that is substantially the same as the second angle, so that the at least one second tooth has the shape of a parallelogram. A third hard metal strip may be affixed to a third portion of the cutting edge and including at least one third full hard metal cutting tooth that is unset. The first hard metal strip may further include a first base portion integral with the at least one first hard metal cutting tooth, the first base portion attached to first portion of the cutting edge. The second hard metal strip may further include a second base portion integral with the at least one second hard metal cutting tooth, the second base portion attached to second portion of the cutting edge. The at least one first hard metal cutting tooth may include at least two first hard metal cutting teeth and at least one first full gullet between the at least two first hard metal cutting teeth. The at least one second hard metal cutting tooth may include at least two second hard metal cutting teeth and at least one second full gullet between the at least two second hard metal cutting teeth. A space may be between the first hard metal strip and the second hard metal strip within a gullet. The saw blade may be formed as one of a reciprocating saw blade, a jigsaw blade, a holesaw, an oscillating blade, and a bandsaw blade.
In another aspect, a method of manufacturing a saw blade includes: providing an elongated body extending along a longitudinal axis and having an elongated cutting edge; attaching a first hard metal strip to a first portion of the cutting edge, the first hard metal strip including at least one first full hard metal cutting tooth; attaching a second hard metal strip to a second portion of the cutting edge, the second hard metal strip including at least one second full hard metal cutting tooth; causing the at least one first full hard metal cutting tooth to be set left at a first angle relative to a vertical axis of the body that is perpendicular to the longitudinal axis; and causing the at least one second full hard metal cutting tooth to be set right at a second angle relative to the vertical axis.
Implementations of this aspect may include one or more of the following features. The at least one first hard metal cutting tooth may include at least two first full hard metal cutting teeth. The at least one second hard metal cutting tooth may include at least two second full hard metal cutting teeth. Attaching the first hard metal strip to the body may include welding the first hard metal strip to the cutting edge with a first weld fusion zone composed of a ductile material. Causing the at least one first full hard metal cutting tooth to be set left comprises applying a lateral force to bend the first weld fusion zone. Attaching the second hard metal strip to the body may include welding the second hard metal strip to the cutting edge with a second weld fusion zone composed of a ductile material. Causing the at least one second full hard metal cutting tooth to be set right comprises applying a lateral force to bend the second weld fusion zone. Causing the at least one first tooth to be set left may include forming a left side face of the at least one tooth to be angled away from the vertical axis at the first angle. Causing the at least one first tooth to be set left may include forming a right side face of the at least one tooth to be angled relative to the vertical axis at an angle that is substantially the same as the first angle, so that the at least one first tooth has the shape of a parallelogram. Causing the at least one second tooth to be set right may include forming a right side face of the at least one tooth to be angled away from the vertical axis by the second angle. Causing the at least one second tooth to be set right may include forming a left side face of the at least one tooth to be angled relative to the vertical axis at an angle that is substantially the same as the second angle, so that the at least one second tooth has the shape of a parallelogram.
A third hard metal strip may be attached to a third portion of the cutting edge, the third hard metal strip including at least one third full hard metal cutting tooth that is unset. The first hard metal strip may further include a first base portion coupled to the at least one first hard metal cutting tooth, and attaching the first hard metal strip to the first portion of the cutting edge may include attaching the first base portion to the cutting edge. The second hard metal strip may further include a second base portion coupled to the at least one second hard metal cutting tooth, and attaching the second hard metal strip to the second portion of the cutting edge may include attaching the second base portion to the cutting edge. The at least one first hard metal cutting tooth may be formed to include at least two first hard metal cutting teeth with at least one first full gullet between the at least two first hard metal cutting teeth. The at least one second hard metal cutting tooth may be formed to include at least two second hard metal cutting teeth with at least one second full gullet between the at least two second hard metal cutting teeth. A space may be left between the first hard metal strip and the second hard metal strip to serve as a gullet. The saw blade may be formed into one of a reciprocating saw blade, a jigsaw blade, a holesaw, an oscillating blade, and a bandsaw blade.
In another aspect, a saw blade includes an elongated body having an elongated cutting edge, a left side face, and a right side face. A hard metal strip may have a base portion affixed to the cutting edge, at least one first full hard metal cutting tooth attached to the base portion, and at least one second full hard metal cutting tooth attached to the base portion, each cutting tooth having a left side surface and a right side surface. The right side surface of each first cutting tooth may define a first recess in the first cutting tooth, such that each first cutting tooth is set left. The left side surface of each second cutting tooth may define a second recess in the second cutting tooth, such that each second cutting tooth is set right.
Implementations of this aspect may include one or more of the following features. Each first recess may extend into the right side face of the body. Each second recess may extend into the left side face of the body. The right side surface of each first cutting tooth may be parallel to the right side face of the body. The left side surface of each second cutting tooth may be parallel to the left side face of the body. The left side surface of each first cutting tooth may extend at an angle away from the left side surface of the body. The right side surface of each second cutting tooth may extend at an angle away from the right side surface of the body. The hard metal strip may further include at least one third hard metal tooth attached to the base portion and being free of any recess, such that the third hard metal tooth is unset. The left side surface of each third cutting tooth may extend at an angle away from the left side surface of the body and the right side surface of each second cutting tooth may extend at an angle away from the right side surface of the body. Each first recess may be formed by grinding the right side surface of each first tooth after the hard metal strip has been attached to the body. Each second recess may be formed by grinding the left side surface of each second tooth after the hard metal strip has been attached to the body. The saw blade may be formed as one of a reciprocating saw blade, a jigsaw blade, a holesaw, and a bandsaw blade.
In another aspect, a method of forming a saw blade may include providing an elongated body having an elongated cutting edge, a left side face, and a right side face; affixing a base portion of a hard metal strip to the cutting edge, the hard metal strip having at least one first full hard metal cutting tooth attached to the base portion and at least one second full hard metal cutting tooth attached to the base portion, each cutting tooth having a left side surface and a right side surface; forming a first recess in the right side surface of each first cutting tooth, such that each first cutting tooth is set left; and forming a second recess in the left side surface of each second cutting tooth, such that each second cutting tooth is set right.
Implementations of this aspect may include one or more of the following features. The first recess may be extended into the right side face of the body. The second recess may be extended into the left side face of the body. After forming each first recess, the right side surface of each first cutting tooth may be parallel to the right side face of the body. After forming each second recess, the left side surface of each second cutting tooth may be parallel to the left side face of the body. After forming each first recess, the left side surface of each first cutting tooth may extend at an angle away from the left side surface of the body. After forming each second recess, the right side surface of each second cutting tooth may extend at an angle away from the right side surface of the body. The hard metal strip may further include at least one third hard metal tooth attached to the base portion and free of any recess, such that the third hard metal tooth is unset. The left side surface of each third cutting tooth may extend at an angle away from the left side surface of the body and the right side surface of each second cutting tooth may extend at an angle away from the right side surface of the body. Forming each first recess may include grinding the right side surface of each first tooth after the hard metal strip has been attached to the body. Forming each second recess may include grinding the left side surface of each second tooth after the hard metal strip has been attached to the body. The saw blade may be formed into one of a reciprocating saw blade, a jigsaw blade, a holesaw, an oscillating blade, and a bandsaw blade.
Advantages may include one or more of the following. The set carbide teeth of the present disclosure provide for a significantly longer life and improved cutting performance as compared to bi-metal blades having a similar tooth pitch. The carbide teeth of the present disclosure having full carbide teeth on fine pitch saw blades, instead of carbide inserts on coarse pitch saw blades, are technically feasible to manufacture and have better cutting performance and life. In addition, the saw blades according to this disclosure allow for mixing of carbide grade in the various carbide segments in order to obtain improved cutting life and performance when cutting a wide variety of workpiece materials. For example, certain carbide grades perform best cutting extremely hard objects like cast iron pipe, while other carbide grades excel at cutting stainless steel workpieces, and yet other carbide grades are best for cutting carbon steel. The carbide saw blade of this invention could be made so that the carbide grades are blended to get the highest level of performance and versatility when used in a wide variety of cutting applications. These and other advantages and features will be apparent from the description, the drawings, and the claims.
Referring to
Each cutting strip 22 is composed of a hard metal material to facilitate cutting metal materials, such as pipes or electrical conduits. The hard metal material may be composed of a hard metal, such as carbide (e.g., tungsten carbide) or cermet, that is harder than the metal material of the body 12. It is desirable to select a grade of hard metal material that has a high amount of toughness and impact resistance. A carbide that lacks good toughness will typically fail by chippage, strippage or carbide fracturing. Moreover, the carbides on prior art carbide blades consist of long extruded carbide strip or strips having a length of 1.5 inches or more and a trapezoidal cross-section attached to the backing steel blade body. Full cutting teeth are ground, pressed, molded, or otherwise formed in the carbide strips prior to them being attached to the body 12, which creates a simple design with low manufacturing complexity and cost.
Each hard metal cutting strip 22 includes a base portion 24 and a plurality of full cutting teeth 26A, 26B that are integral with the base portion 24. In the illustrated embodiment, each hard metal cutting strip 22 comprises at least two cutting teeth 26A that will be set left, at least two teeth 26B that will be set right (e.g., by approximately 0.005 inches to approximately 0.025 inches), and intermediate gullets 28 disposed between adjacent teeth 26A, 26B. Using strips 22 having a plurality of full hard metal cutting teeth 26 enables the hard metal teeth to be arranged with at a fine tooth pitch (e.g., a pitch finer than or equal to 12 tpi (i.e., having greater than or equal to 12 tpi)), since a plurality of full teeth connected by a baserse can be welded more easily to the body 12. It should be understood that each strip 22 may include only one or more cutting teeth and may be formed without any base portion beneath the cutting teeth. In addition, each strip 122 may include a fewer or a greater number of full cutting teeth 26A, 26B.
Each full cutting tooth 26A, 26B includes a rake face 30 extending upward from the base portion 24 to a cutting tip 32, and a relief face 34 extending downward from the cutting tip 30 to the base portion 28. Each rake face 30 is disposed at a rake angle α (e.g., approximately −10° to 10°) relative to a vertical axis Y that is perpendicular to the longitudinal axis X. Each relief face 34 is disposed at a relief angle β (e.g., approximately 5° to 45°) relative to the vertical axis Y. Each cutting tooth 26 also has a left side face 37 and a right side face 35 extending from the rake face 30 to the relief face 34.
Each hard metal strip 22 is attached to the cutting edge 14 of the body 12, e.g., by welding, brazing, soldering, or adhesive. In one embodiment, the base portion 24 of each hard metal strip 22 is welded to the cutting edge 14 via a more ductile weld fusion zone 36. Each weld fusion zone 36 may be composed of an alloying material that results in a more ductile welded joint. For example, an alloying material such as nickel or a nickel alloy may be sandwiched between the strip 22 and blade body 12 or fed into the weld zone between the strip 22 and the blade body 12. This blended composition of the resulting weld joint results in a ductile material that enables stronger plastic deformation of the weld zone during a setting operation. Without the additional ductility, the weld seam would crack, and the set carbide strips and teeth would be prone to fracturing, chipping, or breaking off during the setting process or use of the saw blade.
Alternatively, as shown in
Because they are made of a hard metal, the teeth 26 on the strips 22 cannot be set left or right in the traditional manner by bending the teeth because this would require a great deal of force and risk fracturing the strips 22. Instead, in an embodiment illustrated in
Similarly, left and right side faces 37B, 35B of teeth 26B on a second hard metal strip 22B that is adjacent to the first hard metal strip 22A may be ground or otherwise formed or shaped (either before or after being attached to the body 12) so that the right side face 35B is at a first right angle γR1 (e.g., approximately 2° to 10°) and the left side face 37A is at a second right angle γR2 (e.g., approximately 0° to 20°) relative to the vertical axis Y of the body 12. The first and second right angles γR1, γR2 may be equal so that, when viewed from the rake face 30, the second teeth 26A have a parallelogram appearance. Alternatively, the first and second right angles γR1, γR2 may be different.
The first and second left angles γL1, γL2 of the side faces 37A, 35A of the first teeth 26A on the first strip 22A effectively cause the first teeth 26A to perform as though they are set to the left. The first and second right angles γR1, γR2 of the side faces 35B, 37B of the second teeth 26B on the first strip 22B effectively cause the first teeth 26B to perform as though they are set to the right. For example, in the illustrated embodiment, the strips 22A, 22B, each having two teeth 26A, 26B, are set in a L-R-L-R- pattern so that two consecutive teeth 26A are set left followed by two consecutive teeth 26B set right. Alternatively, there may be a third strip in each sequence in which the side faces are not ground or are formed generally parallel to the vertical axis Y, such that the teeth on the third strip perform as though they are unset or raker teeth. In that embodiment, the strips 22 could be set in a L-R-U-L-R-U- pattern. Other set patterns may be used, such as light left-light right-heavy left-heavy right- or unset-left-right-left-right-. The set angles of the left set teeth and the right set teeth may be the same or may be different.
Referring also to
The strips 22A′, 22B′ of
In the illustrated embodiment, the strips 22A′, 22B′, each having two teeth 26A′, 26B′, are set in a L-R-L-R- pattern so that two consecutive teeth 26A′ are set left followed by two consecutive teeth 26B′ set right. Alternatively, there may be a third strip in each sequence in which the side faces are formed generally parallel to the vertical axis Y and is not set left or right, such that the teeth on the third strip are unset or raker teeth. In that embodiment, the strips could be set in a L-R-U-L-R-U- pattern. Other set patterns may be used, such as light left-light right-heavy left-heavy right- or unset-left-right-left-right-. In each embodiment, the set angles of the left set teeth and the right set teeth, and the angles of the side faces of the left and right set teeth, may be the same or may be different than one another.
In an experiment, saw blades having carbide strips attached to the blade body by a ductile weld fusion zone (e.g., containing a 0.005 inch nickel shim), according to the embodiment of
Referring to
Each cutting strip 122 is composed of a hard metal material to facilitate cutting metal materials, such as pipes or electrical conduits. The hard metal material may be composed of a hard metal, such as carbide (e.g., tungsten carbide) or cermet, that is harder than the metal material of the body 112. It is desirable to select a grade of hard metal material that has a high amount of toughness and impact resistance. A carbide that lacks good toughness will typically fail by chippage, strippage or carbide fracturing. Full cutting teeth are ground, pressed, molded, or otherwise formed in the carbide strip prior to the strips being attached to the body 112, which creates a simple design with low manufacturing complexity and cost.
Each hard metal cutting strip 122 includes a base portion 124 and a plurality of full cutting teeth 126A, 126B that are integral with the base portion 124. In the illustrated embodiment, each hard metal cutting strip 122 comprises at least two cutting teeth 126A to be set left, at least two cutting teeth 126B to be set right, and intermediate gullets 128 disposed between adjacent teeth 126A, 126B. Using strips 122 having a plurality of full hard metal cutting teeth 126 enables hard metal teeth to be arranged with at a fine tooth pitch (e.g., a pitch finer than or equal to 12 tpi (i.e., having greater than or equal to 12 tpi)), since a base 124 supporting a plurality of teeth 126A, 126B can be welded more easily to the body 112. It should be understood that each strip 122 may include one or more cutting teeth without any base portion beneath the cutting teeth. Alternatively, each strip 122 may include a fewer (e.g., one) or a greater (e.g., three or four) number of full cutting teeth 126.
Each full cutting tooth 126A, 126B includes a rake face 130 extending upward from the base portion 124 to a cutting tip 132, and a relief face 134 extending downward from the cutting tip 130 toward the base portion 128. Each rake face 130 is disposed at a rake angle α (e.g., approximately −10° to 10°) relative to a vertical axis Y that is perpendicular to the longitudinal axis X. Each relief face 134 is disposed at a relief angle β (e.g., approximately 5° to 45°) relative to the vertical axis Y. Each cutting tooth 126 also has a left side face 135A and a right side face 135B extending from the rake face 130 to the relief face 134. As shown in
Each hard metal strip 122 is attached to the cutting edge 114 of the body 112, e.g., by welding, brazing, soldering, or adhesive. In an illustrated embodiment, the base portion 124 of each hard metal strip 122 may be welded to the cutting edge 114 via a more ductile weld fusion zone 136. Each weld fusion zone 136 may be composed of an alloying material that results in a more ductile welded joint. For example, an alloying material such as nickel or a nickel alloy may be sandwiched between the strip 122 and blade body 112 or fed into the weld zone between the strip 122 and the blade body 112.
Because they are made of a hard metal, the teeth 126 on the strips 122 cannot be set left or right in the traditional manner by bending the teeth because this would require a great deal of force and risk fracturing the strips 122. Instead, as shown in
Similarly, the right side faces 135B of a one or more of the teeth 126B may be ground or otherwise formed or shaped (either before or after being attached to the body 112) so that a portion of left side face 135B is removed to create a right side recess 139B and a new left side face 135B′ that is recessed from a right side face 113 of the body 112. In the illustrated embodiment, if this forming operation is performed after attaching the strip 122 to the body, the right side recess 139A may extend at least partially into or through one or more of the base portion 124 of the strip 122, the weld fusion zone 136, and the right side face 113 of the body 112. In the embodiment shown in
Forming the recesses 139A, 139B in an alternating pattern of the side surfaces 135, 137 of the teeth 126A, 126B makes the teeth function as though they are set in an alternating left and right pattern. In the illustrated embodiment, with fine pitch teeth, it may be more expedient to form each recess 139A, 139B across two teeth 124A, 126B, so that the teeth are then set in a L-L-R-R- pattern. Alternatively, a third tooth or set of teeth in each sequence may not be formed to have a recess or may be formed with a recess on both side faces of the tooth, such that these third teeth are unset or raker teeth. In that embodiment, the teeth could be set in a L-L-R-R-U- pattern or a L-L-R-R-U- pattern. Other set patterns may be used, such as L-R-L-R, L-R-L-R, U, and light left-light right-heavy left-heavy right- or unset-left-right-left-right-. In each embodiment, the set angles of the left set teeth and the right set teeth, and the angles of the side faces of the left and right set teeth, may be the same or may be different than one another.
Referring to
The above-described embodiments are not limited for use in reciprocating saw blades. Rather they can be used in any number of different types of saw blades, such as, for example, jigsaw blades, bandsaw blades, and holesaws. For example,
The cutting portion 618 includes one or more hard metal cutting strips 630 attached to the front cutting portion 622. The hard metal cutting strip(s) 630 having teeth 632 with portions of their top and bottom faces 634, 636 removed, similar to the hard metal cutting strip 122 described above with respect to
The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting. As used herein, the singular forms “a,” “an,” and “the” may be intended to include the plural forms as well, unless the context clearly indicates otherwise. The terms “comprises,” “comprising,” “including,” and “having,” are inclusive and therefore specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. The method steps, processes, and operations described herein are not to be construed as necessarily requiring their performance in the particular order discussed or illustrated, unless specifically identified as an order of performance. It is also to be understood that additional or alternative steps may be employed.
When an element or layer is referred to as being “on,” “engaged to,” “connected to,” or “coupled to” another element or layer, it may be directly on, engaged, connected or coupled to the other element or layer, or intervening elements or layers may be present. In contrast, when an element is referred to as being “directly on,” “directly engaged to,” “directly connected to,” or “directly coupled to” another element or layer, there may be no intervening elements or layers present. Other words used to describe the relationship between elements should be interpreted in a like fashion (e.g., “between” versus “directly between,” “adjacent” versus “directly adjacent,” etc.). As used herein, the term “and/or” includes any and all combinations of one or more of the associated listed items.
Although the terms first, second, third, etc. may be used herein to describe various elements, components, regions, layers and/or sections, these elements, components, regions, layers and/or sections should not be limited by these terms. These terms may be only used to distinguish one element, component, region, layer or section from another region, layer or section. Terms such as “first,” “second,” and other numerical terms when used herein do not imply a sequence or order unless clearly indicated by the context. Thus, a first element, component, region, layer or section discussed below could be termed a second element, component, region, layer or section without departing from the teachings of the example embodiments.
Terms of degree such as “generally,” “substantially,” “approximately,” and “about” may be used herein when describing the relative positions, sizes, dimensions, or values of various elements, components, regions, layers and/or sections. These terms mean that such relative positions, sizes, dimensions, or values are within the defined range or comparison (e.g., equal or close to equal) with sufficient precision as would be understood by one of ordinary skill in the art in the context of the various elements, components, regions, layers and/or sections being described.
Numerous modifications may be made to the exemplary implementations described above. These and other implementations are within the scope of this application.
This application claims priority, under 35 U.S.C § 119(e) to U.S. Provisional Patent Application No. 62/775,445, filed Dec. 5, 2018, titled “Saw Blade with Set Cutting Teeth” and to U.S. Provisional Patent Application No. 62/791,942, filed Jan. 14, 2019, titled “Saw Blade with Set Cutting Teeth,” each of which is incorporated by reference.
Number | Date | Country | |
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62775445 | Dec 2018 | US | |
62791942 | Jan 2019 | US |