This invention relates generally to wire bending and automated wire bending machines. More particularly this invention relates to a simplified wire bending machine.
Automated wire bending machines are used to create accurate and complex bends in a variety of materials, cross-sectional shapes, and sizes. Automated wire bending machines may be operated, for example, through computer numerical control (CNC). CNC wire bending machines allow a user to design a shape using a computer or other processing device, and have the machine create the shape consistently according to a part program. By automating the wire-forming process, complicated parts can be made beyond the capabilities of ordinarily skilled human craftsmen. Further, CNC wire bending machines may be used to create precise parts repeatedly, reducing the need to inspect or rework individual parts. For instance, the creation of wire grocery carts requires many precise bends which are not easy to manually execute.
Automated wire bending machines are used with various kinds of wire. Wire may be fed directly from coil stock to the wire bending machine, or may be supplied in straight segments.
A variety of automated wire benders are known in the art. These include two-dimensional machines, in which the finished wire is substantially flat because each bend forms the wire in a single plane; and three dimensional machines, in which the finished wire is more complex and may have bends defining multiple planes in space.
The wire bending machines known in the art generally include a wire feeding mechanism, a clamping mechanism, a bending mechanism, and a cutoff mechanism. The wire feeding mechanism feeds wire into the bending mechanism. Once the wire is in the correct position at the wire bending mechanism, the clamping mechanism secures the wire while the bending mechanism bends the wire. By repeating the steps of feeding the wire to a selected position and bending the wire to a selected angle, the wire bending machine creates an intricate series of bends in the wire. Three dimensional wire bending machines also include a means for rotating the wire relative to the bending mechanism. Certain known three dimensional wire bending machines include a means for rotating the bending mechanism relative to the wire. By rotating the wire or the bending mechanism, a three dimensional wire shape may be formed by changing the orientation of the wire relative to the bending mechanism at each bending location. This process is repeated until the wire has been bent into its final position. After the wire is bent into its final position, the cutoff mechanism cuts the wire.
In automated (e.g., CNC) wire bending machines, the wire feeding mechanism, clamping mechanism, means for rotating, bending mechanism, and cutoff mechanism are each driven by one or more actuators through a series of sequential operations defined in a part program. The actuators may be servo motors, stepper motors, hydraulic or pneumatic cylinders, or any other device that may be commanded electronically through circuits integrated with a computing device. Each actuator may further be associated with one or more feedback devices that provide position information associated with the respective actuator. These feedback devices might include encoders, resolvers, limit switches, proximity switches, or any other device that may provide position data electronically through circuits integrated with a computing device.
Known three dimensional wire bending machines generally have a limited range of rotation for the wire or the bending mechanism. This limited range of rotation typically results from designs in which cables or hoses related to the actuators or feedback devices restrict the rotation of the bending mechanism, or designs in which a mechanical element simply cannot be rotated beyond a certain range. It is desirable for automated wire bending machines to allow unlimited rotation of the wire or the bending mechanism.
Known wire bending machines generally use a cutoff mechanism that requires periodic replacement or sharpening, and which cuts the wire at a fixed location on the cutoff mechanism. These known cutoff mechanisms typically include a shearing device that is driven against the wire to cut the wire. The shearing device typically has a sharpened edge. A fixed point along the edge cuts the wire, and after multiple cuts the edge dulls such that the cutting mechanism requires more force to cut the wire and forms a less desirable end on the wire. Thus, because the shearing device degrades it is often designed to be replaceable or removable, requiring periodic maintenance. This maintenance is undesirable because it limits the productivity of the wire bending machine. In addition, in non-industrial environments, it may not be possible or desirable to require this type of maintenance. For example, when forming orthodontic wires, the wire bending machine may be installed at an orthodontist's office, which may not have staff or tools capable of replacing or sharpening the shearing device.
Further, the cutoff mechanism in the known wire bending machines is generally designed to be separate from the bending mechanism. This known design complicates the wire bending machine design by requiring control of an additional axis of motion, which requires a separate actuator and associated feedback devices along with computer hardware and software that coordinates the motion of the cutoff mechanism.
Known wire bending machines generally use a feeding mechanism separate from the clamping and rotating mechanisms. As discussed above, the separate inclusion of these mechanisms requires a separate actuator and associated feedback devices along with computer hardware and software that coordinates the motion of each mechanism. A simplified wire bending machine may be desirable, particularly for uses in which a wire bending machine is designed for non-industrial environments, where cost of the wire bending machine might outweigh the flexibility desired for large scale industrial production.
Generally speaking and pursuant to these various embodiments, a bending machine is provided comprising a wire guide mechanism configured to receive a wire and a bending head. The bending head further comprises, an inner portion, wherein the inner portion includes a guide channel aligned with the wire guide mechanism, and an outer portion, wherein the outer portion includes a cutting edge and one or more bending pins. The outer portion is rotatable about the inner portion. The outer portion is movable from a first position to a second position in which the cutting edge is configured to engage and shear a wire extending through the wire guide mechanism and the guide channel. In one example the cutting edge is the outer circumference of the top surface of the outer portion. Because the outer portion is rotatable, there are multiple positions on the cutting edge that can be used to cut the wire. In another example the cutting edge is on a vertical surface of the outer portion such that the rotation of the outer portion causes the cutting edge to shear the wire. A second vertical surface of the outer portion may also include a cutting edge, allowing the wire to be cut from either side. Because the height of the bending head is adjustable, there are multiple positions on each cutting edge that can be used to cut the wire. Thus, both examples have the benefit of providing substantially longer tool life, which reduces the need for maintenance with respect to the cutting edge.
In one described example, the bending machine further comprises a control circuit. The control circuit is configured to store a history of at least one prior usage of the cutting edge in a memory accessible by the control circuit. In this example, the history of the prior usage of the cutting edge provides information relating to the sharpness of each cutting location along the cutting edge.
In another described example, the bending machine is further configured to determine a first position of the cutting edge relative to the wire. The first position may optionally be the position of the cutting edge at the completion of the wire part. In this example, the bending machine is further configured to select a second position different than the first position of the cutting edge based at least in part on the history of at least one prior usage of the cutting edge stored in a memory accessible by the control circuit. The bending machine is further configured to command the outer portion to rotate so that the second position is aligned with the clamping mechanism. In this example, the history of the prior usage of the cutting edge is used to select a position of the cutting edge according to one or more different approaches. In one alternative, the selected position may provide even wear on the cutting edge. In another alternative, the selected position may provide the sharpest possible location for cutting the wire. In another alternative, the selected position may optimize cycle time, by selecting a second position closest to the first position such that movement of the outer portion of the bending head is minimized. Other methods for selecting the second position may be employed without departing from the spirit of the disclosed example.
In another described example, the control circuit is further configured to determine that the first position of the cutting edge is dull based at least in part on the history of at least one prior usage of the cutting edge. In this example, the history of the prior usage of the cutting edge provides information about the cutting positions that are no longer viable for use. The determination of dullness of the cutting edge may be based on an absolute number of prior uses, or may alternatively be based on a relative number of prior uses in comparison to other positions along the cutting edge.
Generally speaking and pursuant to these various embodiments, a wire bending machine is provided comprising a bending head and a clamping mechanism further comprising a housing, a rotary shaft extending through the housing, two or more jaws coupled to the rotary shaft, a rotating jaw holder, and a jaw actuation bracket. The rotary shaft includes a channel and is rotatable within the housing. The rotating jaw holder encircles the two or more jaws and is supported by a bearing within a jaw actuation bracket. The bearing makes the rotating jaw holder free to rotate within the jaw actuation bracket. In particular, this design enables the jaws to rotate freely and without limit as to the amount of rotation. The jaw actuation bracket encircles the rotating jaw holder, and the jaw actuation bracket is movably coupled to the housing. The jaw actuation bracket is movable from a first position to a second position, wherein when the jaw actuation bracket is in the second position it urges the two or more jaws together. By moving the jaw actuation bracket from the first position to the second position, the clamping mechanism may provide a clamping force on a wire such that the wire is substantially fixed with respect to the two or more jaws of the clamping mechanism.
In one described example, the clamping mechanism further comprises one or more jaw actuation pins disposed on the rotating jaw holder. The one or more jaw actuation pins engage a jaw actuation pin slot formed within the two or more jaws such that when the jaw actuation bracket is in the second position the jaw actuation pin slot urges the jaws together.
In another described example, the clamping mechanism further comprises a motor mechanically coupled to the rotary shaft so as to rotate the rotary shaft and the rotating jaw holder. By operating the motor, a wire substantially fixed with respect to the two or more jaws of the clamping mechanism may be rotated with respect to a bending head on a wire bending machine.
Generally speaking and pursuant to these various embodiments, a system is provided comprising a CAD system configured to receive input from an input device, present a representation of a wire via a display device based on the input, create a wire shape based on the input, and transmit the wire shape to a bending machine. The bending machine is configured to receive the wire shape from the input device, and to manufacture a wire based on the wire shape. In one example, the wire is an orthodontic wire. In another example, the bending machine comprises features including the various embodiments disclosed herein such as the bending head and the clamping mechanism discussed above.
In addition to the above-mentioned embodiments, it should be understood that a variety of methods are also disclosed herein. For example, pursuant to these various embodiments a method of manufacturing a wire is provided comprising receiving an input from an input device, presenting a representation of a wire via a display device based on the input, creating a wire shape based on the input, transmitting the wire shape to a bending machine via a communications network, and manufacturing a wire based on the wire shape by the bending machine.
These and other methods related to the subject matter set forth herein are intended to be covered by this disclosure. It should also be understood that while certain features have been described with certain embodiments, these features may be intermixed or interchanged with one another to form other embodiments as desired. All features disclosed herein are intended to be used in any of the embodiments disclosed herein either in lieu of similar features or in combination with other features.
The disclosed simplified wire bending machine may be optimized for non-industrial environments. For example, such wire bending machines may be used to form orthodontic wires in an orthodontist's office, where tools and persons with mechanical aptitude may not be available. Pursuant to the various embodiments disclosed herein, the simplified wire bending machine may be a relatively smaller device, designed for table-top operation. Features and concepts disclosed herein apply equally to wire bending machines used in industrial environments on machines of relatively larger size.
This description includes drawings, wherein:
As previously discussed, current wire bending machines are limited in the manner in which they can manipulate and cut wire. Embodiments of the inventive subject matter include a bending machine that has a greater ability to manipulate wire while bending. Additionally, embodiments of the inventive subject matter include a bending machine that has additional flexibility in cutting wire after it is bent. The bending machines described herein can be modified for use with any type (e.g., material, shape, etc.) of wire and any size (e.g., gauge) wire).
The bending head 110 may be raised or lowered, and includes a rotatable outer portion 108. The outer portion 108 includes a cutting edge along the outer circumference of its top surface. The bending head 110 is movable in the vertical direction. Movement of the outer portion 108 in the vertical direction causes the outer portion 108 to extend toward and through the wire 102. The cutting edge of the outer portion 108 shears the wire 106 when the cutting edge pass through the wire 106. Embodiments of the bending head 110 are described in greater detail with reference to
The outer portion 108 rotates about the inner portion to bend the wire 102. The bending head 110 is driven by a bending head drive mechanism 150. The bending head drive mechanism 150 includes a first motor 122, a gearbox 124, one or more guide bearings 126, a second motor 132, a drive pulley 134, a driven pulley 130, and a belt 128. The first motor 122 drives vertical movement of the bending head 110. The first motor is (optionally) coupled to the gearbox 124 to more accurately control movement of the bending head 110. For example, the gearbox 124 can include a reduction gear. The first motor 122 drives a threaded shaft (e.g., the threaded shaft 136 depicted in
The bending head drive mechanism 150 also drives rotational motion of the outer portion 108 to bend the wire 102. Specifically, the second motor 132 is mechanically coupled via a gearbox 133 to the drive pulley 134. A belt 128 couples the drive pulley 134 to the driven pulley 130. The outer portion 108 of the bending head 110 is coupled to the driven pulley 130 such that rotational motion of the second motor 132 causes rotational motion of the outer portion 108. The motor 132 is preferably servo-controlled, but may also be a stepper.
While
In some embodiments, the bending machine stores a history of the usage of the cutting edge 212. For example, the bending machine records locations on the cutting edge 212 that are used to cut the wire 102. Specifically, a control circuit associated with the bending machine tracks the number of times each location of the cutting edge 212 is used. The bending machine logs this information to monitor wear of the cutting edge 212. Additionally, in some embodiments, the bending machine rotates the outer portion 108 before cutting the wire to ensure that a sharp portion of the cutting edge 212 is used to cut the wire. For example, if the log indicates that a portion of the cutting edge 212 has been used a sufficient number of times to become dull, the bending machine rotates the outer portion 212 before cutting the wire 102. Further, if the log indicates that all portions of the cutting edge 212 have been used a sufficient number of times to become dull, the bending machine alerts a user that attention is required. For example, the bending machine alerts the user to replace the bending head 110, outer portion 108, or cutting edge 212, or recommend that the cutting edge 212 be sharpened.
The wire guide 1216 includes a vertical neck 1274 extending from a base 1272 that is mounted to the plate 1202. A nose 1276 extends from the top of the neck 1274 toward the bending head 1210. By incorporating an elongated nose 1276, the wire guide provides ample clearance to wires being formed by the bending head 1210. Wire shapes formed at the bending head 1210 may include bends that direct the wire back from the bending head 1210 toward the wire guide 1216. The nose 1276 has a thin profile designed to encourage the wire to pass over or under the wire guide 1216, in the event the wire reaches the wire guide 1216.
In one embodiment (not illustrated), the wire guide 1216 is slidably mounted on the plate 1202. In this embodiment, the track 1215 extends toward the bending head 1210 and the base 1272 is slidably mounted on the track 1215. Because it is slidable, the wire guide 1216 can be adjusted to positions closer or farther from the bending head 1210. The wire guide 1216 may be manually adjustable with set screws or pints to hold a desired position, or may be driven by a motor and leadscrew in the same fashion as the clamping mechanism 1220. Alternatively, a pneumatic cylinder, belt drive, rack and pinion, or other mechanism may be used to drive the wire guide 1216.
Similar to the bending machine illustrated in
The bending head drive mechanism 1250 also drives rotational motion of the outer portion 1208 to bend and cut the wire. Specifically, the second motor 1232 is mechanically coupled via a gearbox 1233 to the drive pulley (not illustrated, but similar to 134 in
The bending head 1210 includes an inner portion 1206 and an outer portion 1208. The outer portion 1208 is rotatable around the inner portion. A wire channel 1209 receives the wire such that the bending pin 1204 may bend the wire around inner portion 1206 when the outer portion 1208 rotates. The outer portion 1208 also includes a cutoff 1212, which is described in greater detail in
The inner portion 1206 includes a wire bending channel 1209 in the portion of the inner portion 1206 above the upper step 1282. The inner portion 1206 further includes a wire cutting channel 1207 below the upper step 1282 and above the bottom step 1281. Both the wire cutting channel 1207 and the wire bending channel 1209 are sized to fit the wire, and the wire bending channel 1209 is open into the wire cutting channel 1207. Thus, the vertical position of the bending head 1210 determines whether the wire extends through the bending channel 1209 or the cutting channel 1207. The wire guide 1216 includes a hole 1217 through which the wire protrudes. Because the wire guide 1216 does not move vertically, the wire is held at a fixed height relative to the bending head 1210, which moves vertically as shown by the arrow 1240.
The inner portion 1206 of the bending head 1210 is divided by the bending channel 1209 and the cutting channel 1207 such that two bending/cutting dies 1263 and 1264 protrude vertically from the inner portion 1206. The inner surfaces of the bending channel are preferably flat, and intersect tangentially with the bending surfaces 1261 and 1262. The bending surfaces 1261 and 1262 have a radius that determines the inner radius of a wire bent around the bending surfaces. The respective bending surfaces 1261 and 1262 may have different radii to facilitate flexibility in the wire bending operations performed by the bending machine 1200. By rotating the wire using the clamping mechanism 1220 the bending machine 1200 can selectively use either bending surface for any given bend. The inner surfaces of the cutting channel 1207 are preferably flat, and intersect to form a sharp edge 1268 at the outer edge of the inner portion 1206. The outer portion includes a vertical face 1283 between the bottom step 1281 and the upper step 1282, with a cutting edge 1212. If the bending head 1210 is positioned such that the wire is in the cutting channel, the cutting edge 1212 of the outer portion 1208 shears the wire against the sharp edge 1268 of the inner portion 1206 when the outer portion 1208 rotates the vertical face 1283 past the cutting channel 1207. A second vertical surface (not shown) exists at the opposite side of the upper step 1281, and may also include a cutting edge. Similarly, every intersection of the cutting channel 1207 and the outer surface of the inner portion 1206 includes a corresponding sharp edge and may be used to cut the wire. Thus, the bending head 1210 has multiple surfaces at which the wire may be cut.
In some embodiments, the bending machine stores a history of the usage of the cutting edge 1212. By adjusting the vertical height of the bending head 1210, different parts of the cutting edge 1212 and 1268 may be used to shear the wire. Further, the wire bending machine 1200 may use different edges on the cutting head 1210, as described above. Thus, the bending machine can select different locations for shearing the wire. Similar to the embodiment illustrated in
In addition to the features described above, the bending head 1310 includes a cutting insert 1384 seated between the bottom step 1381 and the upper step 1382 such that a vertical surface 1383 of the cutting insert 1384 includes a cutting edge 1312 used to shear the wire. As would be known to a person having ordinary skill in the art, the cutting insert 1384 comprises hardened steel or other material and may comprise a hardened coating to improve the wear life of the cutting edge 1312. The cutting insert 1384 is secured in place by a screw 1385 that threads through the cutting insert 1384 and into the outer portion 1308.
While
A rotary shaft 830 runs through the housing 832 and is supported by the rotary bearing(s) 708. The rotary shaft 830 includes a channel through which the wire 102 is fed. The channel is formed by wire channel blocks 746 that are removable from the rotary shaft 830. Because the wire channel blocks 746 are removable, they can be sized to fit a variety of wire shapes or sizes. For example, wire channel blocks 746 with a channel having a diameter smaller than that of the rotary shaft 830 allow the wire bending machine to accommodate smaller wire. The jaws 606 are coupled to the rotary shaft 830 via jaw pivot pin 850. The jaws 606 are free to open and clamp shut by rotating on the jaw pivot pin 850. The rotary shaft 830 is also coupled via the rotating jaw holder 604 to the jaws 606. Axial movement (illustrated by the arrow 826) of the jaw actuation bracket 625 can force the jaws 606 together using any suitable means. For example, the jaws 806 can be shaped such that they protrude further from the wire at one end, such that the rotating jaw holder 804 forces the jaws 806 together when the jaw actuation bracket 625 is extended over the jaws 606. An alternative embodiment is depicted in
As described above, the rotary shaft 830 is coupled via the rotating jaw holder 604 to the jaws 606 on a front end and the driven pulley 816 on the back end. Consequently, the jaws 606 rotate with the rotary shaft 830 as the motor 802 rotates. A jaw actuation bracket 625 is coupled via the pistons 742 to the housing 832. The jaw actuation bracket 625 encircles the rotating jaw holder 604. The rotating jaw holder 604 is supported by the thrust bearing 608 and can therefore spin freely within the jaw actuation bracket 625. The jaw actuation bracket 625 is secured via the thrust bearing 608 to the jaw actuation bracket 608 by a rotating jaw holder retainer 636. The jaw actuation bracket 625 is movable, as indicated by the arrow 826. When the clamping mechanism is in the first position, the jaw actuation bracket 625 and the rotating jaw holder 604 is advance towards the jaws 606.
When in the second position (depicted in
While
The input device 1002 receives and/or generates data associated with a patient's mouth. For example, the input device 1002 can determine locations of the patient's teeth and/or desired locations for orthodontic appliances (e.g., brackets). Accordingly, the input device 1002 can take any suitable form. In one embodiment, the input device 1002 is a computer including a pointing device, such as a mouse, and any other devices required to capture an image of a patient's mouth, such as an oral imaging device. The computer presents an image of the patient's mouth (two or three dimensional) and a user can use the pointing device to select positions on the image on which to place orthodontic appliances. The image of the patient's mouth may be captured directly by scanning the patient's mouth with an oral imaging device, or indirectly, by scanning a model or casting of the patient's mouth. In an alternative embodiment, the input device 1002 can be a haptic device with which the user can select positions on a model of the patient's mouth on which to place orthodontic appliances. The haptic device can be a handheld device (e.g., a wand) or a computer controlled device (e.g., an articulating arm including a haptic sensor). The user can either select points at which he/she wishes the orthodontic appliance to be placed, or trace a path along which he/she wishes the wire to traverse.
The CAD station 1004 receives the data from the input device and determines a wire shape based on the data. In embodiments in which the user selects the locations at which he/she wishes to place the orthodontic appliances, the CAD system 1004 presents the wire along a path consistent with the selected locations. In some embodiments, the CAD system 1004 presents the wire in real time as the user selects the locations (i.e., the CAD systems presents the wire as the input is received). In some embodiments, the CAD system 1004 can determine locations at which the orthodontic appliances should be placed based on one or more locations selected by the user or predefined templates. After the CAD system 1004 determines the locations at which the orthodontic appliances should be placed, the CAD system 1004 presents a representation of the wire. In some embodiments, the user can manipulate the representation of the wire. For example, the user can manipulate the representation of the wire by scaling, translating, rotating, lengthening, shortening, smoothing, fitting, etc. the representation of the wire. The CAD system 1004 generates a wire shape part program file that the bending machine 1008 can use to manufacture the wire.
The server 1006 receives the wire shape part program file. In local embodiments, the server 1006 can be an interface or bus between the CAD system 1004 and the bending machine 1008. In remote embodiments, the server 1006 can be an intermediary node within a communications network.
The bending machine 1008 receives the wire shape part program file and manufactures the wire based on the wire shape file. The bending machine 1008 can take the form of the wire bending machine described herein or any other suitable wire bending machine. As previously discussed, in embodiments in which all components of the system 1000 are local, the system 1000 can be located in a practitioner's office. Such a configuration may decrease both the time and the cost of manufacturing wires.
In addition to being used to manufacture wires for orthodontia, systems similar to those depicted in
While
At block 1102, input is received. For example, a CAD system can receive input from an input device. The input can take any suitable form (e.g., any suitable data format or data type). In some embodiments, the input is a scan or other representation of a patient's mouth. For example, oral imaging devices are known, which provide data that describes the shape of a patient's mouth. In another example, a scanning device may be used to capture scan data from a casting or model of the patient's mouth. After receiving the scan data, the CAD system displays an image of the patient's mouth and enables a user to select locations at which an orthodontic wire will contact the patient's teeth. In addition to, or in lieu of, a representation of a patient's mouth, the input can include locations at which orthodontic appliances should be installed. For example, a casting of a patient's mouth might be created. Using a haptic input device such as a contact probe or a coordinate measuring machine (CMM), a user selects locations at which an orthodontic wire will contact the patient's teeth by capturing points on the casting. The flow continues at block 1104.
At block 1104, a representation of the wire is presented. For example, the CAD system can present a representation of the wire via a display device. In some embodiments, the CAD system presents the representation of the wire in real time as a user selects locations at which orthodontic appliances should be placed. The flow continues at block 1106,
At block 1106, a wire shape based on the input is created. For example, the CAD system can create the wire shape based on the input. In some embodiments, the CAD system creates the wire shape based on predefined templates in addition to the input. In such embodiments, the user may be able to manipulate the wire shape. The CAD system can generate the wire shape automatically based on locations of the patient's teeth and desired final positions of the patient's teeth. For example, the CAD system can calculate a wire shape that will achieve the desired movement. The CAD system can also generate a wire shape file based on the wire shape. The wire shape file can take any suitable form. The flow continues at block 1108.
At block 1108, the wire shape is transmitted. For example, the CAD system can transmit the wire shape. The CAD system can transmit the wire shape via the wire shape file. The CAD system can transmit the wire shape via any suitable communications network. The flow continues at block 1110.
At block 1110, the wire shape is received. For example, a bending machine can receive the wire shape. The flow continues at block 1112.
At block 1112, a wire based on the wire shape is manufactured. For example, the bending machine can manufacture the wire based on the wire shape. The bending machine can manufacture the wire by bending and/or cutting the wire based on the wire shape file.
This detailed description refers to specific examples in the drawings and illustrations. These examples are described in sufficient detail to enable those skilled in the art to practice the inventive subject matter. These examples also serve to illustrate how the inventive subject matter can be applied to various purposes or embodiments. Other embodiments are included within the inventive subject matter, as logical, mechanical, electrical, and other changes can be made to the example embodiments described herein. Features of various embodiments described herein, however essential to the example embodiments in which they are incorporated, do not limit the inventive subject matter as a whole, and any reference to the invention, its elements, operation, and application are not limiting as a whole, but serve only to define these example embodiments. This detailed description does not, therefore, limit embodiments of the invention, which are defined only by the appended claims. Each of the embodiments described herein are contemplated as falling within the inventive subject matter, which is set forth in one or more of the following claims.
This application claims the benefit of U.S. Provisional Application No. 62/328,444 filed Apr. 27, 2016, which is hereby incorporated by reference in its entirety.
Number | Name | Date | Kind |
---|---|---|---|
4207567 | Juengel | Jun 1980 | A |
5464349 | Andreiko | Nov 1995 | A |
5553895 | Karl | Sep 1996 | A |
5683243 | Andreiko | Nov 1997 | A |
6015289 | Andreiko | Jan 2000 | A |
6244861 | Andreiko | Jun 2001 | B1 |
6616414 | Yoo | Sep 2003 | B2 |
6616444 | Andreiko | Sep 2003 | B2 |
6817220 | Liu | Nov 2004 | B2 |
6846179 | Chapouland | Jan 2005 | B2 |
7094053 | Andreiko | Aug 2006 | B2 |
7134310 | Hu | Nov 2006 | B2 |
7229282 | Andreiko | Jun 2007 | B2 |
7293444 | Hacker | Nov 2007 | B2 |
8359896 | Wolf | Jan 2013 | B2 |
8616036 | Jaubert | Dec 2013 | B2 |
8631674 | Christofilis | Jan 2014 | B2 |
9067255 | Fries | Jun 2015 | B2 |
9566636 | Del Fabro | Feb 2017 | B2 |
9592546 | Christofilis | Mar 2017 | B2 |
9604271 | Pace | Mar 2017 | B2 |
9751122 | Carruthers | Sep 2017 | B2 |
10232424 | Koechig | Mar 2019 | B2 |
10639693 | Yogo | May 2020 | B2 |
20050103080 | Anagnostopoulos | May 2005 | A1 |
20090173127 | Pace | Jul 2009 | A1 |
20100275668 | Riemeier | Nov 2010 | A1 |
20170312808 | Suto | Nov 2017 | A1 |
20170355005 | Grapsas | Dec 2017 | A1 |
20180250778 | Fumagalli | Sep 2018 | A1 |
20200130038 | Mock | Apr 2020 | A1 |
Number | Date | Country |
---|---|---|
19736468 | Feb 1998 | DE |
0949021 | Oct 1999 | EP |
1388383 | Feb 2004 | EP |
2172229 | Sep 1986 | GB |
Entry |
---|
European Search Report for Application No. 17168515.9 dated Sep. 20, 2017 (pp. 9). |
Number | Date | Country | |
---|---|---|---|
20170312808 A1 | Nov 2017 | US |
Number | Date | Country | |
---|---|---|---|
62328444 | Apr 2016 | US |