The present disclosure generally relates to welding technique monitoring systems, and, more particularly, to light filters for portable welding technique monitoring systems.
Welding technique generally refers to the way in which a welding operator positions, moves, and/or manipulates a welding-type tool relative to a workpiece (and/or a welding joint of the workpiece), such as, for example, during a welding-type operation. Good welding technique can positively impact the quality of a weld. Bad welding technique can negatively impact the quality of a weld. However, it can sometimes be difficult for (e.g., less experienced) human operators to accurately judge whether welding technique is good or bad.
Limitations and disadvantages of conventional and traditional approaches will become apparent to one of skill in the art, through comparison of such systems with the present disclosure as set forth in the remainder of the present application with reference to the drawings.
The present disclosure is directed to light filters for portable welding technique monitoring systems, substantially as illustrated by and/or described in connection with at least one of the figures, and as set forth more completely in the claims.
These and other advantages, aspects and novel features of the present disclosure, as well as details of an illustrated example thereof, will be more fully understood from the following description and drawings.
The figures are not necessarily to scale. Where appropriate, the same or similar reference numerals are used in the figures to refer to similar or identical elements. For example, reference numerals utilizing lettering (e.g., workpiece 122a, workpiece 122b) refer to instances of the same reference numeral that does not have the lettering (e.g., workpieces 122).
Some examples of the present disclosure relate to lightweight, self-contained, and highly portable welding technique monitoring systems that can be used to evaluate live and/or simulated welding-type operations. The disclosed welding technique monitoring systems use a portable support platform that can be easily transported to different welding stations/sites, providing a marked advantage over legacy monitoring systems that use heavy welding stands that are difficult to move between welding stations/sites. After an initial calibration, the systems can consistently and repeatedly monitor welding technique relative to a particular joint with no additional calibration necessary, even if there is sensor and/or platform movement. The systems are additionally able to detect a welding-type operation without the need to communicate with welding equipment, thereby removing the need to modify existing welding equipment to work with the systems. The systems are further configured for use with existing (rather than potentially expensive custom) welding-type tools, thereby keeping the systems low cost and highly portable. The systems are further configured to use off the shelf mobile devices for all the electronic functions, thereby simplifying equipment and/or power/battery management.
Some examples of the present disclosure relate to a weld monitoring platform, comprising: a support platform comprising a surface configured to support a monitoring sensor at a sensor position, and support a welding workpiece at a workpiece position; and a filter housing configured for attachment to the surface of the support platform, the filter housing configured to house a light filter that is configured to reduce a brightness of a welding arc viewed through the light filter.
In some examples, the surface of the support platform comprises a flat surface, the filter housing being configured to position the light filter at an angle with respect to the flat surface of the support platform when the light filter is housed in the filter housing, such that the light filter is not perpendicular to the flat surface. In some examples, the monitoring platform further comprises a reflector wall in contact with the surface of the support platform or the filter housing, the reflector wall being configured to block light from an external environment that could reflect off the light filter into the monitoring sensor. In some examples, the monitoring platform further comprises a sensor housing configured for attachment to the surface of the support platform, the sensor housing configured to house the monitoring sensor, the filter housing being configured for attachment to the surface of the support platform between the sensor housing and the workpiece position.
In some examples, the filter housing is slanted with respect to the sensor housing, such that a first side of a bottom end of the filter housing is configured for attachment to the surface of the support platform at a first point, and a second side of the bottom end of the filter housing is configured for attachment to the surface of the support platform at a second point that is farther away from the sensor housing than the first point. In some examples, the monitoring platform further comprises a workpiece positioning device configured for attachment to the surface of the support platform, the workpiece positioning device configured to position the welding workpiece at the workpiece position in an expected workpiece orientation, the filter housing being configured for attachment to the support platform between the sensor housing and the workpiece positioning device. In some examples, the light filter comprises an auto-darkening lens or a 2×4.25 inch shade 5-13 passive lens.
Some examples of the present disclosure relate to a weld monitoring platform, comprising: a support platform comprising a surface configured to support a monitoring sensor at a sensor position; and a filter housing configured for attachment to the surface of the support platform, the filter housing configured to house a light filter that is configured to reduce a brightness of a welding arc viewed through the light filter, the filter housing being spaced from the sensor position such that the light filter does not fully obstruct a field of view of the monitoring sensor when the light filter is in the filtering housing and the monitoring sensor is at the sensor position.
In some examples, the surface of the support platform comprises a flat surface, the filter housing being configured to position the light filter at an angle with respect to the flat surface of the support platform when the light filter is housed in the filter housing, such that the light filter is not perpendicular to the flat surface. In some examples, the system further comprises a reflector wall in contact with the surface of the support platform or the filter housing, the reflector wall being configured to block light from an external environment that could reflect off the light filter into the monitoring sensor. In some examples, the monitoring platform further comprises a sensor housing configured for attachment to the surface of the support platform, the sensor housing being further configured to house the monitoring sensor at the sensor position, the filter housing being configured for attachment to the surface of the support platform between the sensor housing and the workpiece position.
In some examples, the filter housing is slanted with respect to the sensor housing, such that a first side of a bottom end of the filter housing is configured for attachment to the surface of the support platform at a first point, and a second side of the bottom end of the filter housing is configured for attachment to the surface of the support platform at a second point that is farther away from the sensor housing than the first point. In some examples, the monitoring platform further comprises a workpiece positioning device configured for attachment to the surface of the support platform, the workpiece positioning device configured to position the welding workpiece at the workpiece position in an expected workpiece orientation, the filter housing being configured for attachment to the support platform between the sensor housing and the workpiece positioning device. In some examples, the light filter comprises an auto-darkening lens or a 2×4.25 inch shade 5-13 passive lens.
Some examples of the present disclosure relate to a weld monitoring platform, comprising: a support platform having a surface; a workpiece positioning device attached to the surface of the support platform, the workpiece positioning device configured to position a welding workpiece at an expected workpiece position or in an expected workpiece orientation; a sensor housing attached to the surface of the support platform, the sensor housing configured to house a monitoring sensor at a sensor position; and a light blocker or a filter housing positioned between the sensor housing and the workpiece positioning device, the light blocker being configured to block light from a welding arc from directly impinging upon the monitoring sensor, or the light filter housing being configured to house a light filter that is configured to reduce a brightness of the welding arc viewed through the light filter.
In some examples, the surface of the support platform comprises a flat surface, at least a portion of the light blocker being configured to be angled with respect to the flat surface of the support platform such that at least the portion of the light blocker is not perpendicular to the flat surface, or the light filter housing being configured to position the light filter at an angle with respect to the flat surface of the support platform when the light filter is housed in the light filter housing, such that the light filter is not perpendicular to the flat surface. In some examples, the weld monitoring platform comprises the light filter housing and further comprises a reflector wall in contact with the surface of the support platform or the light filter housing, the reflector wall being configured to block light from an external environment that could reflect off the light filter into the monitoring sensor. In some examples, the weld monitoring platform comprises the light filter housing, and the light filter housing is slanted with respect to the sensor housing, such that a first side of a bottom end of the light filter housing is configured for attachment to the surface of the support platform at a first point, and a second side of the bottom end of the light filter housing is configured for attachment to the surface of the support platform at a second point that is farther away from the sensor housing than the first point.
In some examples, the weld monitoring platform comprises the light blocker, the light blocker being attached to the surface of the support platform or to the sensor housing. In some examples, the weld monitoring platform comprises the light filter housing, and the light filter comprises an auto-darkening lens or a 2×4.25 inch shade 5-13 passive lens.
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In some examples, the monitoring platform 202a and alignment platform 202b of the support platform 202 are comprised of different materials. For example, the monitoring platform 202a may be comprised of a sturdy lightweight and/or spatter resistant material, such as aluminum or plastic, while the alignment platform 202b may be comprised of a material more suited to conducting electrical current suitable for a welding-type operation, such as steel. The power connectors 212 attached to the alignment platform 202b may be comprised of similarly conductive material. In some examples, one or more of the power connectors 212 may be used to connect the welding technique monitoring system 200 (and/or support platform 202) to the welding-type power supply 108, through the grounding cable 120 (e.g., via an intervening connector attached to the power connector 212 and grounding cable 120).
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In some examples, the two opposite sets of platform connectors 210 on the alignment platform 202b of the support platform 202 allow for the alignment platform 202b to be connected to the monitoring platform 202a at two different (e.g., opposite) orientations that are approximately 180 degrees apart.
In some examples, the support platform 202 may be reconfigurable (e.g., via the alignment platform 202b) to ensure that, during a welding-type operation, the welding-type tool 1100 will be pointed away from a monitoring sensor 1502 (e.g., of a monitoring device 1500 housed in the monitoring device housing 206). Having the welding-type tool 1100 pointed away from the monitoring sensor 1502 may help to reduce the amount of sparks that come between the welding-type tool 1100 and monitoring sensor 1502 during a welding-type operation, as such sparks might interfere with and/or impede the detection capabilities of the monitoring sensor 1502. Additionally, the orientation of the alignment platform 202b may be reconfigurable to ensure that, regardless of which way the welding-type tool 1100 is pointed, the joint alignment fixture 400, marker stands 208, and workpiece clamps 204 can always be placed on a side of the joint 124 that is opposite to where the operator 118 will be positioned (e.g., to avoid obstructing and/or impeding the operator 118 during the welding-type operation).
In some examples, first and second orientations of the alignment platform 202b may correspond to right and left handed welding. For example, the first orientation of the alignment platform 202b shown in
Whether right or left handed, a welding operator 118 generally prefers to hold the welding-type tool 1100 such that the welding-type tool 1100 is pointed across the body of the operator 118, from dominant hand to weaker hand. Thus, if the welding operator 118 is positioned below and facing the monitoring system 200 in
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Additionally, the alternative monitoring platform 302a no longer has platform connectors 210 at its abutting edge 218 that connect to complementary platform connectors 210 on the alignment platform 202b across the abutting edges 218. Rather, the alternative monitoring platform 302a has alternative platform connectors 310 (e.g., holes) on an upper surface 301 of the alternative monitoring platform that connect with complementary platform connectors 310 (e.g., protrusions) on an under surface of the alternative alignment platform 302. Thus, the alternative alignment platform 302b may sit atop the surface 301 of the alternative monitoring platform 302a when the two alternative platforms 302 are connected, and may be lifted off the surface and rotated approximately 180 to reconfigure for left or right handed welding.
In some examples, the alternative support platform 302 may have additional, or different, alternative platform connectors 310. For example, the alternative support platform 302 may use bracket platform connectors 210a and/or latch platform connectors 210b (e.g., similar to those shown in
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In some examples, the monitoring sensor 1502 may comprise one or more motion sensors, depth sensors, camera sensors (e.g., infrared cameras, visible spectrum cameras, high dynamic range cameras, etc.), acoustic sensors, optical sensors, radio frequency (RF) sensors, ultrasonic sensors, magnetic sensors, acceleration sensors (e.g., accelerometers), gyroscopic sensors, and/other appropriate sensors. In some examples, the sensor data captured by the sensors 1502 may comprise one or more images, videos, sounds, temperatures, radio waves, heat waves, radiation measurements, and/or other appropriate data. In some examples, the acceleration sensor(s) may detect the direction(s) and/or magnitude(s) of linear acceleration(s) (e.g., due to gravity, etc.). In some examples, sensor data captured by the monitoring sensor(s) 1502 may allow the monitoring system 200 to track, detect, and/or record positions, orientations, and/or movement of the welding-type tool 1100 and/or other objects in the welding environment.
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In some examples, the monitoring device housing 206 may be attached to the surface 201 of the support platform 202 via fasteners 101 that extend through passages 198 in the support platform 202 (see, e.g.,
In some examples, the monitoring device housing 206 may be overlaid with a housing cover. In some examples, the housing cover may help to protect the monitoring device 1500 from damage via collision, spatter, sparks, debris, etc. In some examples, the housing cover may be transparent so that the operator 118 can see a display screen of the monitoring device 1500 through the housing cover.
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Because the joint alignment fixture 400 is fixed to the support platform 202, and the alignment arm 410 is of an unchanging length with a single axis of rotation, if the alignment arm 410 is used to position the joint 124 (e.g., via contact with the joint 124), then the joint 124 will always be placed at the same position relative to the joint alignment fixture 400. Additionally, for straight line joints 124, if at least two points of the alignment arm 410 make contact with the joint 124, the joint 124 is assured to always be at the same orientation relative to the joint alignment fixture 400 (e.g., aligned with a line passing through those two contact points).
Furthermore, the ability of the alignment arm 410 to move up and/or down via movement of the hinge pin 408 in the slots 406 of the stanchions 404 allows for the joint alignment fixture 400 to accommodate workpieces 122 of different thicknesses (e.g., extending to different heights above the surface 201 of the support platform 202). In particular, the ability of the alignment arm 410 to move up and/or down allows for the arm supports 414 of the alignment arm 410 to avoid contact with the workpiece(s) 122, regardless of their thickness. This, in turn, allows the arm supports 414 to extend parallel to the surface of the support platform 202 when the joint alignment fixture 400 makes contact with the joint 124, regardless of the material thickness of the workpiece(s) 122 (at least up to a practical point beyond which virtually no real life workpiece 122 extend).
In some examples, the alignment fixture 400 may be considered to be in an engaged position when the arm supports 414 extend parallel to the surface 201 of the support platform 202 and/or the alignment arm 416 makes contact with the joint 124 (and/or the workpiece(s) 122 defining the joint 124). In some examples, joint contacting elements 418 of the joint alignment fixture 400 may be used to contact and/or engage the joint 124 (and/or the workpiece(s) 122 defining the joint 124) to position and/or align the joint 124 at the expected joint position and/or orientation.
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In some examples, the rounded edge 418a further prevents the crossbar 416 from pushing the vertical workpiece 122a away when the alignment arm 410 moves from the engaged position to a disengaged position (e.g., where the alignment arm 410 no longer makes contact with the workpiece(s) 122). Were the rounded edge 418a of the half-cylindrical crossbar 416 instead a flat surface of a half polygonal (e.g., rectangular) crossbar 416, the flat surface would push the workpiece 122a away as the alignment arm 410 is rotated from an engaged position (e.g., as shown in
In some examples, the rounded edge joint contacting element 418a may instead be a corner edge. For example, an edge along a line of intersection of two sides of a triangular or half polygonal, rather than cylindrical, portion of the crossbar 416. In such examples, the corner edge joint contacting element would still form a line of contact, rather than a flat surface of contact, and therefore would not push the vertical workpiece 122a away when moving from the engaged position to a disengaged position.
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While the joint contacting elements 418 of the joint alignment fixture 400 will always be adequate for engaging and aligning a Tee joint 124c, there may be situations where certain lap joints 124b and/or butt joints 124c present problems. For example, there may be a lap joint 124 where the upper workpiece 122a has a thickness and/or width that is greater than the length of the protruding edge joint contacting element 418b. In such an example, the protruding edge joint contacting element 418b may have trouble making contact with the lower workpiece 122b when the alignment arm 410 is in the engaged position. As another example, there may be a butt joint 124c where the groove is wider than the protruding edge joint contacting element 418b down to a depth that is greater than the length of the protruding edge joint contacting element 418b. In such an example, the protruding edge joint contacting element 418b may have trouble making contact with both workpieces 122 when the alignment arm 410 is in the engaged position.
The first alternative alignment joint fixture 500 shown in the examples of
Unlike the joint alignment fixture 400 discussed above, each first alternative joint alignment fixture 500 is shown as including two first alternative alignment arms 510 attached to a single hinge pin 408. As shown in
Another example of a mechanism through which the first alternative joint alignment fixture(s) 500 can be reconfigured to switch between protruding edge joint contacting elements 418b is the rotatable first alternative fixture base 502 and rotatable alternative crossbar 516 of each first alternative joint alignment fixture 500.
Another example of a mechanism through which the first alternative joint alignment fixture(s) 500 can be reconfigured to switch between protruding edge joint contacting elements 418b is the removable hinge pin 408.
Another example of a mechanism through which the first alternative joint alignment fixture(s) 500 can be reconfigured to switch between protruding edge joint contacting elements 418b is the detachable first alternative alignment arms 510.
In some examples, the different mechanisms for switching between differently sized alternative protruding edge joint contacting elements 418b may be mixed and matched, with some (or all) of them used with the first alternative joint alignment fixture 500 (and/or previously discussed joint alignment fixture 400), while some others are not used. While, in the examples of
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The first alternative welding technique monitoring system 600 shown in
However, because the alignment platform 202b of the first alternative welding technique monitoring system 600 is not reconfigurable with respect to the monitoring platform 202a, there is no need for the marker stands 208 to be on the alignment platform 202b. Additionally, the markers 199 of the marker stand 208 are more easily detectable by the monitoring sensor 1502 the closer the markers 199 are to the monitoring sensor 1502. Thus, the first alternative welding technique monitoring system 600 positions the marker stands 208 on monitoring platform 202a, near the light filter housing 900.
The first alternative welding technique monitoring system 600 shown in
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In some examples, the second alternative alignment arm 710 may be considered to be fully engaged when rotated as far as possible about the hinges 704 in a first direction 801 (see, e.g.,
In some examples, the second alternative alignment arm 710 may be considered to be fully disengaged when rotated about the hinges 704 as far as possible in a second direction 803 (see, e.g.,
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Instead, the second alternative joint alignment fixture 700 is configured with alternative joint contacting elements 718 that can accommodate joints 124 positioned for left and/or right handed welding from either side of the support platform 202 and/or second alternative joint alignment fixture 700. In the examples of
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At the ends of the armature 720 are shown tabs 718b that protrude perpendicular to the armature 720 out of the cavity 716. The armature 720 is configured to rotate about the pivot 724 such that when one tab 718b moves one direction (e.g., up), the other tab 718b moves the opposite direction (e.g., down). Thus, when one protruding tab joint contacting element 718 is pushed up (e.g., due to contact with a workpiece 122), the other protruding tab joint contacting element 718 is pushed down until it also contacts the workpiece 122, at which point the protruding tab joint contacting elements 718 reach equilibrium.
In some examples, the tabs 718b are configured to extend into the groove of a butt joint 124c and contact the workpieces 122 within, extend over and against the edge of a lap joint 124b and contact the workpieces 122 forming the lap joint 124b, and/or contact the lower/horizontal/base workpiece 122 in a Tee joint 124a, similar to the protruding edge joint contacting element 418b discussed above. In this way, the tabs 718b ensure at least two points of contact can be made with at least one workpiece 122 (e.g., regardless of whether right or left handed welding is used.
Once the joint 124 and/or workpieces 122 are correctly positioned and/or oriented through use of the joint alignment fixture 400 (and/or first alternative joint alignment fixture 500 and/or second alternative joint alignment fixture 700), the operator 118 may use the clamps 204 to secure the workpiece 122 in place so that the workpieces 122 do not move. In the examples of
After clamping, the joint alignment fixture 400 (and/or first alternative joint alignment fixture 500 and/or second alternative joint alignment fixture 700) may be disengaged from the workpiece(s) 122 by rotating the alignment arm 410/510/710 away from the workpiece(s) 122. Once disengaged, the alignment arm 410/510/710 will be out of the way of any subsequent welding-type operation, and therefore less likely to impede the welding-type operation and/or be subject to damage due to outputs of the welding-type operation (e.g., particulates, sparks, heat, smoke, etc.). In some examples, the alignment arm 410, first alternative alignment arm 510, and/or second alternative alignment arm 710 may be spring biased towards the disengaged position, so that the alignment arm 410/510/710 will default to the disengaged (out of the way) position when not in use.
In some examples, the welding technique monitoring system 200 (and/or first alternative welding technique monitoring system 600) may detect whether the alignment arm 410/510/710 is in an engaged or disengaged position, and operate accordingly. To assist in this endeavor, the joint alignment fixtures 400/500/700 may be outfitted with one or more markers 199 that can be detected by the welding technique monitoring system 200. In some examples, detection of the markers 199 may enable the welding technique monitoring system 200 (and/or first alternative welding technique monitoring system 600) to determine a (e.g., three dimensional (3D)) position of the alignment arm 410/510/710, which can then be used to determine whether the position is an engaged or disengaged position. In some examples, detection of the marker(s) 199 associated with the first alternative joint alignment fixture 500 may additionally enable the welding technique monitoring system 200 to determine which first alternative alignment arm 510 (and/or which joint contacting element 418) is in which position.
In some examples, one or more of the markers 199 may comprise an active or passive tag. In some examples, one or more of the markers 199 may comprise a fiducial tag, such as, for example, an April Tag. In some examples, one or more of the markers 199 may comprise a unique asymmetrical visual pattern that encodes information that can be used to identify both a three dimensional position and a three dimensional orientation of the marker 199. In some examples, one or more of the markers 199 may have a flat/matte finish (e.g., rather than glossy) in order to reduce reflections from a welding arc or welding environment that may interfere with tracking. In some examples, one or more of the markers 199 may comprise labels, etchings, and/or paintings.
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In some examples, the welding technique monitoring system 200 and/or first alternative welding technique monitoring system 600 may be able to determine whether the alignment arm 410/510/710 (and/or which alignment arm 510) is in an engaged or disengaged position by determining whether one or more of the above alignment fixture 400/500/700 associated markers 199 are visible and/or detectable. In some examples, the welding technique monitoring system 200/600 may be able to determine whether the alignment arm 410/510/710 is in an engaged or disengaged 3D position by determining a position of the alignment fixture 400/500/700 associated marker(s) 199, and/or a distance of between the marker(s) 199 and the monitoring sensor 1502, and comparing with a threshold distance and/or 3D position.
In some examples, the marker 199 on the marker flag 802 may provide some level of redundancy to the marker 199 on the crossbar 416, which may be of help if, for example, one or the other becomes obscured for some reason. In some examples, the marker 199 on the marker flag 802 and/or the marker 199 on the crossbar 416 may be omitted. In some examples, a different sort of alignment fixture may be used that need not be moved, and may stay continually engaged throughout a welding-type operation, in which case no distinction may need to be made between engaged and disengaged positions.
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In some examples, the light filter 902 is configured to reduce a brightness of light emitted by a welding arc that passes through the light filter 902. Such a reduction in brightness may be beneficial to the monitoring sensor 1502 when viewing and/or capturing sensor data relating to the welding-type operation through the light filter 902. Were the light filter 902 omitted, the light output by the welding-type operation and/or welding arc may be so blindingly bright as to obscure the view of the monitoring sensor(s) 1502 and/or impede data capture by the monitoring sensor(s) 1502 and/or analysis of the captured data.
In some examples, in the absence of a welding arc, the environment viewed through the light filter 902 may be so dark as to be invisible and/or indistinguishable. In some examples, in the presence of the welding arc, the environment viewed through the light filter 902 may appear dimly lit, with the welding arc appearing noticeably (but not blindingly) bright.
In some examples, the monitoring system 200/600 may be able to detect the presence of a welding arc by analyzing light filtered by the light filter 902 and captured by the monitoring sensor 902, and determining whether the filtered light is still noticeably bright. In some examples, the monitoring system 200/600 may additionally, or alternatively, look for a particular color light that can be detected through the light filter 902 when filtering light from a welding arc. By using the light filter 902 to filter/dim the otherwise blindingly bright light emitted by a welding arc, the monitoring system 200/600 may be able to detect the welding arc using the monitoring sensor 1902, and thereby avoid the need to establish communication with the welding-type tool 1100, welding-type equipment, and/or other device to determine when a welding-type operation is occurring.
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In some examples, the light filter housing 900 is attached to the surface of the support platform 202 via fasteners 101 that are inserted through the spacers 912 of the light filter housing 900 and/or passages 198 of the support platform 202. In some examples, the light filter housing 900 may be removable from the support platform 202 via removal of the fasteners 101. In some examples, the fasteners 101 may be secured to the support platform 202, and removal of the light filter housing 900 from the fasteners 101 may remove the light filter housing 900 from the support platform 202.
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In some examples, this angling of the light filter housing 900 and/or light filter 902 ensures that any light emitted close to the surface 201 of the support platform 202 that is reflected by the light filter 902, is reflected back down to the surface 201 of the support platform 202. Thus, light from a welding arc that is generated close to the surface 201 of the support platform 202 (e.g., proximate a joint 124 of a workpiece 122 supported on the surface 201 of the support platform 202) is reflected back down towards the surface 201 of the support platform 202, rather than upwards. Were the light filter housing 900 and/or light filter 902 not so angled, the light might instead be reflected upwards into the environment above the light filter 902, where it may obscure and/or interfere with data capture by the monitoring sensor 1502 (e.g., with respect to the welding-type tool 1100 and/or a marker ring 1200 attached to the welding-type tool 1100).
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In some examples, the unconnected wall 918 of the reflector wall 914 prevents light from outside the welding technique monitoring system 200 from reflecting off the light filter 902 into the monitoring sensor 1502, which may impede the detection capabilities of the monitoring sensor 1502. In some examples, the unconnected wall 918 of the reflector wall 914 further prevents light reflected off the (e.g., display screen of) the monitoring device 1500, and then off the light filter 902, from being further reflected. In some examples, the reflector wall 914 may be composed of a non or low reflective material, and/or have a non or low reflective color (e.g., black, gray, etc.).
In some examples, the alternative reflector wall 1014 may serve a similar, or identical, function to that of the reflector wall 914. In some examples, the alternative reflector wall 1014 may additionally, or alternatively, serve to protect (e.g., universal serial bus (USB), power, etc.) cords and/or wires connected to the monitoring device 1500 from weld spatter during a welding-type operation. While described as an alternative reflector wall 1014, in some examples, both the reflector wall 914 and alternative reflector wall 1014 may be used together in the welding technique monitoring system 200 (and/or first alternative welding technique monitoring system 600).
At the opposite end of the gooseneck 1102 from the tool handle 1101 is connected a nozzle assembly 1104. Within the nozzle assembly 1104 is shown a contact tip 1106. In some examples, the nozzle assembly 1104 may additionally include a nozzle shell, an insulator, a gas diffuser, and/or other elements. In some examples, (e.g., where the welding-type tool 1100 is a tungsten inert gas (TIG) torch configured for GTAW), the nozzle assembly 1104 may include a nozzle shell, an insulator, a tungsten electrode, a back cap, and/or other elements.
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In some examples, the marker ring 1200 may additionally, or alternatively, be attached to the tool handle 1101 (as shown, for example, by the dotted line outline of the marker ring 1200 on the handle 1101). However, attachment of the marker ring 1200 to the tool handle 1101 may also be less ideal due to potential obstruction of a trigger 1108 on the tool handle 1101, and/or obstruction of a hand of an operator 118 when attempting to hold the welding-type tool 1100 by the handle 1101.
In some examples, the marker ring 1200, and/or the markers 199 on the marker ring 1200, are used by the welding technique monitoring system 200 to track a position and/or orientation of the welding-type tool 1100. In some examples, a separate marker ring 1200 that is attachable to, and/or detachable from, the welding-type tool 1100, may allow the welding technique monitoring system 200 to be easily used with existing welding-type tools 1100 and/or welding-type equipment 104. And the ability to use existing welding-type tools 1100 and/or welding-type equipment 104 eliminates (or substantially reduces) the need for special customized welding-type tools 1100 and/or welding-type equipment 104. Thus, the use of the marker ring 1200 may help to reduce the cost of the monitoring system 200/600.
In particular, the attachable/detachable marker ring 1200 may allow the monitoring system 200/600 to use existing welding-type tools 1100 because existing welding-type tool 1100 are poorly suited to markers 199. For example, the nozzle assembly 1104 and/or gooseneck 1102 of many existing welding-type tools 1100 are substantially cylindrical, with rounded and/or curved surfaces (e.g., as shown in
In some examples, the inner ring surface 1204 may only extend partway around the ring bore 1208, thereby leaving a gap in the ring body 1202. In some examples, such a gap may allow a diameter of the ring bore 1208 to expand to accommodate larger goosenecks 1102 (and/or other element(s)) of a welding-type tool 1100. In some examples, this feature may be used, for example, to help attach the marker ring 1200 to the gooseneck 1102 (and/or other part) of the welding-type tool 1100.
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In some examples, the outer ring surface 1206 may further include a washer shaped circular flange between the upper ring sidewall 1216 and lower ring sidewall 1218. In some examples, the flange might have a surface approximately parallel to the ring top face 1212 and/or ring bottom face 1214. In some examples, such a flange may be used to protect the upper ring sidewall 1216 and/or lower ring sidewall 1218 (and/or the markers 199 positioned thereon) from damage in the event the marker ring 1200 is dropped.
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Because the lower ring sidewall faces 1230 are rotationally and angularly offset from the six upper ring sidewall faces 1220, none of the upper ring sidewall faces 1220 extends parallel to any lower ring sidewall face 1230, nor shares an edge with any lower ring sidewall face 1230. Additionally, the lower ring sidewall faces 1230 are not connected together along their lower ring side edges 1232 (except at one point where the lower ring bottom edges 1234 of the lower ring sidewall faces 1230 intersect). Rather, each lower ring sidewall face 1230 is connected along its lower ring side edge 1232 to a corner portion 1236 of the lower ring sidewall 1218.
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While the ring sidewall faces 1220/1230 of the marker ring 1200 are shown as square and/or rectangular, in some examples, the ring sidewall faces 1220/1230 may take the form of other polygons. While six ring sidewall faces 1220/1230 are shown as part of each of the upper ring sidewall 1216 and lower ring sidewall 1218, in some examples the upper ring sidewall 1216 and/or the lower ring sidewall 1218 may have more or less ring sidewall faces 1220/1230 (e.g., 8, 7, 5, 4, etc.).
While the markers 199 themselves are omitted in
In some examples, one or more of the markers 199 may be (e.g., laser) etched onto the faces of the marker ring 1200. In some examples, etched markers 199 may be more resistant to damage from heat, spatter, and/or sparks (e.g., as compared to markers 199 attached via adhesive). In some examples, the faces of the marker ring 1200 may be buffed before etching to improve the contrast of the markers 199, which may be helpful for tracking. Alternatively, or additionally, the faces of the marker ring 1200 may be painted white (or some other light color), then etched to remove the white paint and apply a black (or other dark) coloring.
In the example of
In the example of
In some examples, the ring fastening element 1250b may be an inflatable diaphragm that can be inflated and/or deflated to modify the diameter of the ring bore 1208. In some examples, the ring fastening element 1250b may be a clamping element that can be clasped onto and/or unclasped from the welding-type tool 1100 (e.g., the gooseneck 1102). In some examples, the ring fastening element 1250b may be a spring loaded snap on clasp configured to be snapped onto and/or off of the welding-type tool 1100. In some examples, the ring fastening element 1250a and/or some other fastener adjuster may be used to activate (e.g., inflate, clamp, clasp, etc.), deactivate (e.g., deflate, unclamp, unclasp, etc.) and/or otherwise adjust the ring fastening element 1250b.
Instead, the lower ring sidewall faces 1430 and upper ring sidewall faces 1420 are aligned, such each lower ring sidewall face 1430 shares a common edge 1470 with each upper ring sidewall face 1420. As a result, there are no triangular corner portions 1236/1336. There are, however, trapezoidal lower ring sidewall faces 1430 positioned between each rectangular lower ring sidewall face 1430.
In the example of
As shown in
The lower ring sidewall faces 3230 are also shown as being smaller relative to the upper ring sidewall faces 3220 in the third alternative marker ring 3200 than the lower ring sidewall faces 1230 are relative to the upper ring sidewall faces 1220 in the marker ring 1200. This is possible because no markers 199 are included on the lower ring sidewall faces 3230 in the third alternative marker ring 3200.
Recent empirical evidence suggests that high precision tracking of the welding-type tool 1100 may be conducted using only markers 199 on the upper ring sidewall faces 3220. Indeed, in some examples, the lack of markers 199 on tilted and/or slanted lower ring sidewall faces 3230 make tool may welding-type position and/or orientation determinations/calculations even easier. As high precision tracking may be conducted using only markers 199 on the upper ring sidewall faces 3220, the third alternative marker ring 3200 does not put markers 199 on the lower ring sidewall faces 3230.
Because there is no need for markers 199 on the lower ring sidewall faces 3230 of the third alternative marker ring 3200, there is also no need for the lower ring sidewall faces 3230 of the third alternative marker ring 3200 to be large enough to accommodate (e.g., visible, observable, discernable, etc.) markers 199. Thus, the lower ring sidewall faces 3230 are smaller relative to the upper ring sidewall faces 3220 in the third alternative marker ring 3200 than the lower ring sidewall faces 1230 are relative to the upper ring sidewall faces 1220 in the marker ring 1200. The smaller size of the lower ring sidewall faces 3230 results in a smaller overall size and lower weight of the third alternative marker ring 3200, which may make the third alternative marker ring 3200 less likely to negatively impact welding technique during a welding-type operation.
Rather than being used for markers 199, the lower ring sidewall faces 3230 are used primarily for attaching the third alternative marker ring 3200 to the welding-type tool 1100. Because it is important that the third alternative marker ring 3200 remain stationary (relative to the welding-type tool 1100), each lower ring sidewall face 3230 is shown as having a channel 1238 through which a ring fastening element 1250a may extend. The ring fastening elements 1250a that extend through the channels 1238 on the lower ring sidewall faces 3230 of the third alternative marker ring 3200 serve to attach the third alternative marker ring 3200 to the welding-type tool 1100.
In the examples of
The circular flange 3299 may further serve as a shield to protect the upper ring sidewall faces 3220 (and markers 199 positioned thereon) from heat, debris, sparks, and/or spatter generated during a welding-type operation. As may be seen in the examples of
In some examples, the communication interface(s) 1504 may include one or more wireless adapters, wireless cards, cable adapters, wire adapters, dongles, radio frequency (RF) devices, wireless communication devices, Bluetooth devices, IEEE 802.11-compliant devices, WiFi devices, cellular devices, GPS devices, USB devices, Ethernet ports, network ports, lightning cable ports, cable ports, etc. In some examples, the communication interface(s) 1504 may be configured to facilitate communication via one or more wired media and/or protocols (e.g., Ethernet cable(s), universal serial bus cable(s), etc.) and/or wireless mediums and/or protocols (e.g., cellular communication, general packet radio service (GPRS), near field communication (NFC), ultra high frequency radio waves (commonly known as Bluetooth), IEEE 802.11x, Zigbee, HART, LTE, Z-Wave, WirelessHD, WiGig, etc.).
In some examples, the communication interface(s) 1504 may be coupled to one or more antennas to facilitate wireless communication. In some examples, the communication interface(s) 1504 may be coupled to one or more power supplies of the monitoring device 1500 to facilitate power transfer, generation, and/or recharging.
In some examples, the communication interface(s) 1504 may be configured to facilitate internal and/or external communications. In some examples, the communication interface(s) 1504 may receive one or more signals (e.g., from the remote computing device(s) 1510) decode the signal(s), and provide the decoded data to the electrical bus 1501. As another example, the communication interface(s) 1504 may receive one or more signals from the electrical bus 1501 (e.g., representative of one or signals from the computing components 1508, monitoring sensor(s) 1502, and/or UI 1506) encode the signal(s), and transmit the encoded signal(s) to the remote computing device(s) 1510.
In some examples, the remote computing device(s) 1510 in communication with the monitoring device 1500 through the network and communication interface(s) 1504 may be similar to the monitoring device 1500, in that the remote computing device 1510 comprises one or more communication interfaces 1504 in electrical communication with computing components 1508. In some examples, the remote computing device(s) 1510 may or may not comprise a similar UI 1506.
In the example of
In some examples, the UI 1506 may include circuitry configured to drive the input device(s) 1516 and/or output device(s) 1518 of the UI 1506. In some examples, the UI 1506 may be configured to generate one or more signals representative of input received via the input device(s) 1516 and provide the signal(s) to the bus 1501. In some examples, the UI 1506 may also be configured to control the output device(s) 1518, to generate one or more outputs in response to one or more signals received via the bus 1501 (e.g., from the computing components 1508).
In some examples, information output by the output device(s) 1518 of the UI 1506 may additionally (or alternatively) be output by remote I/O device(s) 150 (e.g., of the remote computing device(s) 150). This mirrored output may be useful for teachers, students, administrators, and/or others not directly using the welding technique monitoring system 200. In some examples, the remote I/O devices 150 may include input and/or output devices similar (or identical) to those described above with respect to the UI 1506.
In the example of
In the example of
In some examples, the joint orientation vector 1704 may be a vector that extends parallel to the joint 124. In some examples, the joint orientation vector 1704 may have a length equal to the length of the joint 124. In some examples, the joint orientation vector 1704 may be a unitary vector, and the length of the joint 124 may be represented by another portion of the joint data 1524 (e.g., the joint position), or not represented at all.
In some examples, the base plate surface vector 1706 may be a vector that extends perpendicular to the joint orientation vector 1704 in a plane parallel to a surface of a workpiece 122 (and/or parallel to the surface 201 of the support platform 202). In some examples, the base plate perpendicular vector 1708 may be a vector that extends perpendicular to the base plate surface vector 1706 and the joint orientation vector 1704. In some examples, the base plate surface vector 1706 and/or the base plate perpendicular vector 1708 may be unitary vectors.
In the example of
In some examples, the joint identifying information 1526 may include one or more joint parameters. In some examples, the one or more joint parameters may include the type of joint 124 (e.g., Tee/corner joint 124a, lap joint 124b, butt joint 124c, etc.), a thickness of the workpiece(s) 122 being joined at the joint 124, an alignment arm 410 configuration applicable to the joint 124, and/or whether the joint 124 is configured for a right or left handed welding-type operation (e.g., via the configuration of the clamps 204, configuration of the support platform 202, handedness of the operator 118, etc.). In some examples, the joint identifying information 1526 may include information that only indirectly pertains to the joint 124, such as, for example, identifying information regarding the operator 118, a project (and/or job), a training exercise, a work order, a WPS, the welding-type equipment 104, a weld number, and/or other information that might be associated with the joint data 1524.
In some examples, the memory circuitry 1520 may also include (and/or store) values for other determined, target, present, and/or past parameters, such as, for example, welding parameters (e.g., voltage, current, wire feed speed, gas flow rate, etc.), welding technique parameters (e.g., work angle, travel angle, travel speed, travel direction, contact tip to work distance, travel speed, aim, etc.), weave parameters (e.g., frequency, weave width, dwell time, etc.), monitoring sensor 1502 parameters (e.g., sensor coordinate system 2304, sensor plane 2602, sensor axis 2604, etc.), and/or operation parameters (e.g., exercise identifier(s), operator identifier(s), weld cell identifier(s), project identifier(s), welding procedure specification (WPS) information, work order information, welding-type equipment 104 type/identifier(s), etc.). In some examples, one or more parameters may be associated with timestamp information, one or more other parameters, and/or other information. In some examples, a technique monitoring process 1600 may use and/or update one or more of the stored parameters during operation.
In some examples, the memory circuitry 1520 may also include (and/or store) several different (e.g., rigid body) models of different welding-type tools 1100, markers 199, marker rings 1200/1300/1400, and/or calibration blocks 2000 (further discussed below with respect to
In some examples, the memory circuitry 1520 may also include (and/or store) one or more of the thresholds discussed herein. Though certain items and/or information are sometimes described as being included, stored, and/or recorded in memory circuitry 1520, one of ordinary skill will understand this is a shorthand for specifying that data representative of those items and/or information is included, stored, and/or recorded in memory circuitry 1520.
In the example of
While the below disclosure refers to the memory circuitry 1520 and/or processing circuitry 1522 of the monitoring device 1500, it should be understood that some or all of functions may additionally, or alternatively, be performed by memory circuitry and/or processing circuitry of the remote computing device(s) 1510. Though the discussion below focuses on the welding technique monitoring system 200, joint alignment fixture 400, and marker ring 1200, it should be understood that the discussion may be equally applicable to the first alternative welding technique monitoring system 600, the first/second alternative alignment fixtures 500/700, and first/second alternative marker rings 1300/1400.
In some examples, prior to beginning (or at the beginning of) the technique monitoring process 1600, the processing circuitry 1522 may calibrate the welding technique monitoring system 200 to work with the monitoring sensor(s) 1502. For example, where one or more of the monitoring sensors 1502 are camera and/or optical sensors, the processing circuitry 1522 may identify a resolution (e.g., 1280×720) and/or field of view (e.g., 60 degrees) of the monitoring sensor(s) 1502. In some examples, the resolution and/or field of view of the camera and/or optical monitoring sensors 1502 may be stored in memory circuitry 1520 and/or entered by the operator 118 (e.g., via the UI 1506).
In some examples, the resolution and/or field of view may be automatically detected. For example, the monitoring sensor(s) 1502 may capture an image of two markers 199 on the marker stand 208 that are both positioned on a plane that is parallel to the sensor plane 2602 (see, e.g.,
In the example of
After the marker ring calibration process 1900, the technique monitoring process 1600 proceeds to block 1602 where the processing circuitry 1522 determines whether the technique monitoring system 200 needs to be calibrated to identify the position and/or orientation of a particular joint 124. In some examples, whether or not the technique monitoring system 200 needs a joint calibration may be determined on the basis of user input (e.g., received via the UI 1506). In some examples, whether or not the technique monitoring system 200 needs a joint calibration may be determined on the basis of whether the processing circuitry 1522 determines that sensor data captured by the monitoring sensor(s) 1502 relates to and/or shows (e.g., a marker 1999 of) a calibration device (e.g., further discussed below with respect to
If the processing circuitry 1522 determines that the technique monitoring system 200 needs a joint calibration at block 1602, the processing circuitry 1522 performs a joint calibration process 2200 after block 1602. In some examples, the joint calibration process 2200 enables the welding technique monitoring system 200 to determine the position and/or orientation of a welding joint 124 relative to the marker stand 208, and record that position and/or orientation of the joint 124 as joint data 1524. In some examples, the welding technique monitoring system 200 may be put into a calibration mode prior to performing the joint calibration process 2200. The joint calibration process 2200 is discussed further below with respect to
In the example of
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In some examples, the processing circuitry 1522 may determine that a (e.g., simulated and/or practice) welding-type operation has begun and/or is occurring based on operator input (e.g., received via the UI 1506). For example, the operator 118 may wish to do practice or simulate a welding-type operation before performing a live-welding-type operation. In such an example, the operator 118 may provide an input indicating that they are beginning (or continuing) a simulated and/or practice welding-type operation, and the processing circuitry 1522 may determine that a (e.g., simulated and/or practice) welding-type operation has begun and/or is occurring based on the operator input.
For example, the monitoring sensor(s) 1502 may capture (e.g., image) sensor data relating to one or more (e.g., marker 199 positioned) portions of the joint alignment fixture 400. Thereafter, the processing circuitry 1522 may analyze the sensor data and determine whether the sensor data indicates the one or more portions of the joint alignment fixture 400 are detectable (e.g., visible) and/or within a certain volume relative to (e.g., in a given direction and/or distance from) the monitoring sensor 1502. In some examples, the portion(s) of the joint alignment fixture 400 may include a marker flag 802 and/or alignment arm 410, and/or the marker(s) 199 on the marker flag 802 and/or alignment arm 410.
If the joint alignment fixture 400 is determined to be engaged, the technique monitoring process 1600 proceeds to block 1610 after block 1608. In some examples, the technique monitoring process 1600 may also proceed to block 1610 if the processing circuitry 1522 cannot make a determination as to whether the joint alignment fixture 400 is engaged. At block 1610, the processing circuitry 1522 outputs (e.g., via the output device(s) 1518 of the UI 1506) directions and/or guidance for how to use the joint alignment fixture 400 to correctly position and/or align the joint 124.
In some examples, the directions and/or guidance may be based on a position and/or orientation of the joint 124 identified during the joint identification process 2400. In some examples, the directions and/or guidance may include one or more pictures, videos, animations, audio/text instructions, and/or other appropriate outputs. In some examples, the directions and/or guidance output at block 1610 may be output regardless of whether the joint alignment fixture 400 is engaged.
In the example of
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At block 1614, the processing circuitry 1522 suppresses output from the output device(s) 1518 of the UI 1506 for the duration of the welding-type operation. In some examples, this may help to avoid distracting the operator 118 during the welding-type operation. In some examples, information may instead (and/or still) be provided via the remote I/O devices 150 (e.g., for teachers, students, administrators, etc.). After block 1614, the technique monitoring process 1600 proceeds to block 1616, where the processing circuitry 1522 locks in the position and/or orientation of the joint 124 relative to the monitoring sensor(s) 1502 determined during the joint identification process 2400 (as there is likely to be no or negligible movement of the joint 124 and/or monitoring sensor(s) 1502 during the welding-type operation).
Following block 1616, the technique monitoring process 1600 proceeds to block 1618 where the processing circuitry 1522 tracks the welding-type tool 1100 using sensor data captured by the monitoring sensor 1502. For example, the processing circuitry 1522 may analyze the (e.g., image) sensor data captured by the monitoring sensor 1502 to identify the position and/or orientation of the marker ring 1200 (and/or one or more markers 199 on the marker ring 1200) on the welding-type tool 1100. Thereafter, the processing circuitry 1522 may apply one or more translations (e.g., determined during the marker ring calibration process 1900) to determine the position and/or orientation of the welding-type tool 1100 using the identified position and/or orientation of the marker ring 1200 (and/or one or more markers 199 on the marker ring 1200) on the welding-type tool 1100.
In some examples, the orientation of the welding-type tool 1100 may be represented and/or conceptualized in the form of a tool orientation vector 1702 (see, e.g.,
In the example of
In some examples, travel angle may be defined as the angle of the welding-type tool 1100 with respect to a direction that a welding-type operation progresses (e.g., where a perpendicular angle is a zero degree travel angle). Thus, in some examples, the technique monitoring process 1600 may determine the travel angle based on the angle between the joint orientation vector 1704 and the tool orientation vector 1702 (and/or 90 degrees minus this angle).
In some examples, work angle may be defined as the angle between a line perpendicular to a base workpiece 122 (e.g., the workpiece 122 lying flat on the support platform 202 and/or parallel to the support platform 202 itself) and a plane determined by the axis of an electrode of the welding-type tool 1100 (e.g., tool orientation vector 1702) and the weld axis (e.g., joint orientation vector 1704). Thus, in some examples, the technique monitoring process 1600 may determine the work angle based on the base plate perpendicular vector 1708 and the tool orientation vector 1702 (e.g., where the tool orientation vector 1702 is assumed to be the relevant line on the plane). In some examples, precise calculations of travel angle and/or work angle may rely on both an angle between the tool orientation vector 1702 and the joint orientation vector 1704, and an angle between the tool orientation vector 1702 and the base plate perpendicular vector 1708 (e.g., applied to certain trigonometric functions).
In some examples, the contact tip to work distance may be defined as the distance between the position of the joint 124 and the position of the welding-type tool 1100 (e.g., where the position of the welding-type tool 1100 is defined to be the position at the end of a contact tip 1106 or tungsten electrode of the welding-type tool 1100). In some examples, the travel speed may be defined as the change in the position of the welding-type tool 1100 along the joint 124 (and/or parallel to the joint orientation vector 1704) over time. In some examples, the aim may be defined as the shortest distance along the workpiece 122 between a center of the joint 124 (e.g., along the base plate surface vector 1706) and an intersection of the workpiece 122 and (e.g., an extension of) the tool orientation vector 1702.
In some examples, the processing circuitry 1522 may determine instantaneous values for the one or more welding technique parameters at block 1620, and record the values in memory circuitry 1520 until the welding-type operation is over. In some examples, only the instantaneous position(s) and/or orientation(s) of the welding-type tool 1100 (and/or of the joint 124) relative to the monitoring sensor 1502 (and/or joint 124) may be recorded at block 1620, and the instantaneous values for the one or more welding technique parameters determined afterwards. In some examples, feedback regarding the welding technique parameter values may be suppressed during the welding-type operation to avoid distracting the operator 118 during the welding-type operation.
In the example of
In the example of
At block 1624, feedback regarding the determined welding technique parameters may be provided (e.g., via UI 1506). In some examples, the feedback may in the form of one or more text messages, images, videos, sounds, vibrations, and/or appropriate outputs. In some examples, the feedback may identify one or more of the welding technique parameter values and/or weave pattern characteristic values determined at block 1620. In some examples, the feedback may identify the welding technique parameter values and/or weave pattern characteristic values at different times of the welding-type operation, and/or average welding technique parameter values and/or weave pattern characteristic values. In some examples, the feedback may output video and/or audio recorded at the time corresponding to the displayed an/or selected welding technique parameter values and/or weave pattern characteristic values.
In some examples, the processing circuitry 1522 may compare the determined welding technique parameter values (and/or weave pattern characteristic values) to expected and/or target welding technique parameter (and/or weave pattern characteristic) values, and/or provide feedback regarding the comparison. In some examples, the technique monitoring process 1600 might provide different feedback (e.g., red vs. green colors, chime vs. alarm sounds, etc.) depending on whether the determined values are within, or outside of, a threshold range of the expected/target values. In some examples, the technique monitoring process 1600 may further determine one or more ratings, grades, and/or scores based on the comparison of the determined values to the expected/target values, and provide feedback with respect thereto.
In the example of
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In some examples, each pillar 2006 is configured to abut a contact tip or tungsten electrode of the nozzle assembly 1104 when the nozzle assembly 1104 is inserted into the cavity 2004. Such abutment may serve to stop the nozzle assembly 1104 (and/or welding-type tool 1100) from further movement down into the cavity 2004 (e.g., in a direction parallel to the pillar 2006). In some examples, the pillar 2006 both restricts movement and ensures that the contact tip 1106 or tungsten electrode of the nozzle assembly 1104 will always be at the same position in a particular cavity 2004.
In the example of
As shown, each block face 2002 additionally includes four complementary fasteners 2001. Each complementary fastener 2001 is shown positioned between two markers 199. In some examples, the complementary fasteners 2001 are configured to connect with fasteners 101 secured to the support platform 202. In some examples, connection of complementary fasteners 2001 of a block face 2002 to fasteners 101 secured to the support platform 202 will result in the calibration block 2000 being removably attached to the support platform 202. In some examples, disconnection of the fasteners 101 and complementary fasteners 2001, and/or removal of the fasteners 101 from the support platform 202, may allow the calibration block 2000 to be removed from the support platform 202. While the complementary fasteners 2001 are shown as holes (e.g., configured to fit/receive protruding pins, screws, bolts, etc.) in the example of
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In some examples, the tool holder (e.g., calibration block 2000) may be positioned with only one block face 2002 being visible to (and/or detectable/discernable by) the monitoring sensor 1502. For example, fasteners 101 attached to the support platform 202 may be arranged such that when the complementary fasteners 2001 of the calibration block 2000 connect with the fasteners 101, only one block face 2002 of the calibration block 2000 is visible to (and/or detectable/discernable by) the monitoring sensor 1502. In such examples, determining which block face 2002 is most visible (and/or detectable/discernable) is a simple endeavor as only one block face 2002 is at all visible (and/or detectable/discernable).
However, in some examples, the block face 2002 may be positioned askew, such that more than one block face 2002 is visible (and/or detectable/discernable). Or the monitoring sensor 1502 may be slightly elevated above the tool holder (e.g., calibration block 2000), such that the upper block face 2002 is also visible (and/or detectable/discernable). In such examples, the processing circuitry 1522 may need to first discern which block face 2002 is most visible (and/or detectable/discernable) to the monitoring sensor 1502.
In some examples, the memory circuitry 1520 may store a model of the calibration block 2000 that identifies which markers 199 are on each block face 2002 of the calibration block 2000, and/or how the markers 199 are arranged on each block face 2002 of the calibration block 2000. In some examples, the processing circuitry 1522 may analyze the (e.g., image) sensor data and identify the markers 199 that are currently detectable (e.g., visibly recognizable). The processing circuitry 1522 may then determine the position(s) and/or orientation(s) of the identified marker(s) 199 using the sensor data, and identify the arrangement of detected and/or identified markers 199. The processing circuitry 1522 may further compare the arrangement of the identified markers 199 to the stored model of the calibration block 2000 (and/or the stored arrangement(s) of marker(s) 199 on the block faces 2002 in the model).
By comparing identified arrangements of markers 199 to the stored model, the processing circuitry 1522 may identify which block faces 2002 were detected by (e.g., visible in) the sensor data. The processing circuitry 1522 may then determine which of the detected block faces 2002 has the most markers 199 oriented towards the monitoring sensor 1502 (e.g., perpendicular to a sensor axis 2604 of the monitoring sensor 1502 and/or parallel to a sensor plane 2602 of the monitoring sensor 1502—see, e.g.,
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For example, the processing circuitry 1522 may conclude the most visible (and/or most detectable) block face 2002 is facing (and/or oriented towards) the monitoring sensor 1502. The processing circuitry 1522 may then determine the orientation(s) of the most visible block face 2002 (and/or the orientation of the calibration block 2000) based on the (e.g., previously determined) orientation(s) of the marker(s) 199 on the most visible block face 2002 (e.g., as compared with the orientation(s) of the marker(s) 199 in the stored model). The processing circuitry 1522 may further reference the stored model of the calibration block 2000 to determine which cavity 2004 is available for use (e.g., oriented upwards) when the most visible block face 2002 is facing sideways (e.g., towards the monitoring sensor 1502) and in the determined orientation.
In the example of
In some examples, the memory circuitry 1520 may store relative peak positions of each pillar 2006 of the calibration block 2000 (e.g., as part of the stored model of the calibration block 2000). For example, each peak position of each pillar 2006 may be stored relative to one or more markers 199 on a block face 2002 adjacent to the block face 2002 having the cavity 2004 with the pillar 2006. Thus, the processing circuitry 1522 may use the previously determined position(s) and/or orientation(s) of the marker(s) 199 in conjunction with the information stored in the stored model to determine the peak position of the pillar 2006 of the cavity 2004 that will receive the nozzle assembly 1104 of the welding-type tool 1100.
In some examples, a simpler version of the calibration block 2000 may be used as a tool holder. For example, the pillars 2006 of the calibration block 2000 may all be of the same height, and/or all peak at the same position relative to the block face 2002 and/or marker(s). As another example, a simpler calibration block 2000 may have only one cavity 2004, where some mechanism may be used to adjust the volume inside the cavity 2004 to accommodate different sized nozzle assemblies 104 (e.g., similar to the mechanisms 1250 shown and discussed with respect to the marker ring 1200 of
In the example of
After defining the position of the welding-type tool 1100 to be the position of the peak of the pillar 2006 at block 1914, the marker ring calibration process proceeds to block 1916. At block 1916, the processing circuitry 1522 directs the monitoring sensor 1502 to capture sensor data relating to the welding-type tool 1100 as the welding-type tool 1100 is moved by the operator 118.
In some examples, the processing circuitry 1522 may prompt the operator 118 (e.g., via UI 1506) to move the welding-type tool 1100 so that the monitoring sensor 1502 can capture data relating to (and/or showing) all the ring faces 1220/1230 (and/or markers 199) of the marker ring 1200. In some examples, the processing circuitry 1522 may prompt the operator 118 to move the welding-type tool 1100 in one complete continuous revolution while the monitoring sensor 1502 is capturing data. In some examples, one or more of the cavities 2004 of the calibration block 2000 may be configured to allow rotational movement of the welding-type tool 1100 while the nozzle assembly 1104 is in the cavity 2004. For example, the rotational movement may be about the nozzle assembly 1104 and/or a central axis of the nozzle assembly 1104 (e.g., approximately parallel to the pillar 2006). In such examples, the operator 118 may provide (and/or the processing circuitry 1522 may prompt the operator 118 to provide) some indication (e.g., via the UI 1506) when the monitoring sensor 1502 should begin and/or end capturing data (and/or when they will begin and/or end moving the welding-type tool 1100), such as via two inputs, or one input and a timer function, and the monitoring sensor 1502 may capture data relating to the welding-type tool 1100 and/or marker ring 1200 in response to such an indication.
In some examples, the processing circuitry 1522 may prompt the operator 118 to move the welding-type tool 1100 in a series of discrete steps that combine to equal one complete revolution. For example, one or more of the cavities 2004 may not allow for rotational movement of the nozzle assembly 1104 while in the cavity 2004. In such examples, the operator 118 may be prompted to remove the nozzle assembly 1104 from the cavity 2004, rotate the welding-type tool 1100, and then reinsert the nozzle assembly 1104 into the cavity 2004. In such examples, the operator 118 may provide (and/or the processing circuitry 1522 may prompt the operator 118 to provide) some indication (e.g., via the UI 1506) when the monitoring sensor 1502 should capture data for a particular discrete step, and the monitoring sensor 1502 may capture data relating to the welding-type tool 1100 and/or marker ring 1200 in response to such an indication.
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In some examples, the processing circuitry 1522 may store the position(s) and/or orientation(s) in memory circuitry 1520. In some examples, the processing circuitry 1522 may build a model of the marker ring 1200 using the sensor data, and/or the determined position(s) and/or orientation(s) of the marker(s) 199 on the marker ring 1200. In some examples, the model may include positions and/or orientations of the markers 199 relative to one another, and/or translations between positions and/or orientations of the markers 199. Thereby, using the model, the processing circuitry 1522 may be able to determine where one (e.g., visible) first marker 199 is positioned and/or oriented using sensor data relating to the first marker 199, and then translate knowledge of the first marker 199 into the position and/or orientation of a second (e.g., invisible and/or obstructed) marker 199, without any sensor data relating to the second marker 199.
After determining the position and/or orientation of the marker(s) 199 on the marker ring 1200 at block 1918, the processing circuitry 1522 defines the orientation of the welding-type tool 1100 at block 1920. As discussed above, the orientation of the welding-type tool 1100 may be represented and/or conceptualized via a tool orientation vector 1702 (see, e.g.,
In some examples, the processing circuitry 1522 may use sensor data from an accelerometer monitoring sensor 1502 (e.g., measuring acceleration due to gravity) to determine which direction is straight downwards. However, this may yield less accurate results if the support platform 202 and/or calibration block 2000 is not positioned on a perfectly horizontal surface, as the direction of gravity may not be approximately perpendicular to the surface 201 of the support platform 202 and/or the block face 2002.
In some examples, the processing circuitry 1522 may use the stored model of the calibration block 2000 to determine the direction the welding-type tool 1100 is oriented. For example, the stored model may store a base position of the pillar 2006 (e.g., where the pillar 2006 begins) relative to the marker(s) 199 on the most visible block face 2002, as well as the peak position of the pillar 2006 relative to the marker(s) 199 on the most visible block face 2002. Using the stored model information and the previously determined position(s) and/or orientation(s) of the marker(s) 199, the processing circuitry 1522 may identify the peak and base positions of the pillar 2006, and define the tool orientation vector 1702 as extending from the peak position of the pillar 2006 to the base position of the pillar 2006.
Alternatively, the processing circuitry 1522 may analyze the saved model to identify two markers 199 on the most visible block face 2002 that are vertically aligned when that block face 2002 is in the previously determined orientation. Thereafter, the processing circuitry 1522 may define the tool orientation vector 1702 as extending from the position of the upper marker 199 (or some position offset from the marker 199) to the position of the lower marker 199 (or some position equally offset) using the previously determined positions of the markers 199.
In some examples, the processing circuitry 1522 may use the determined positions and/or orientations of one or more markers 199 on the marker ring 1200 to determine the direction the welding-type tool 1100 is oriented (e.g., tool orientation vector 1702). For example, using the sensor data detected by the monitoring sensor 1502 as the welding-type tool 1100 is rotated in block 1916, the processing circuitry 1522 may be able to identify several positions of a marker 199 on the marker ring 1200 during the rotational movement. In some examples, the processing circuitry 1522 may be able to identify additional positions of the marker 199 on the marker ring 1200 by identifying positions of other secondary markers 199 on the marker ring 1200 (e.g., at times when the primary marker 199 is obscured), and using a generated model of the marker ring to estimate the position of the primary marker 199.
In some examples, the processing circuitry 1522 may be able to define and/or approximate a circle having a perimeter that approximately intersects the identified positions of the marker 199 on the marker ring 1200. Thereafter, the processing circuitry 1522 may be able to identify a central position of the circle that is approximately equidistant (e.g., within 0-3 millimeters) from the identified positions of the marker 199 on the marker ring 1200 and/or collinear with an axis of the nozzle assembly 1104 (and/or contact tip 1106). In some examples, the processing circuitry 1522 may define the tool orientation vector 1702 as being parallel to a vector extending from the central position of the circle to the defined tool position (e.g., peak point of the pillar 2006). In some examples, the processing circuitry 1522 may go through the same process with several or all of the markers 199 on the marker ring 1200 to identify several circle centers and subsequent vectors, and use a statistical technique (e.g., mean, mode, etc.) to identify one tool orientation vector 1702 from the several.
In some examples, the processing circuitry 1522 may alternatively, or additionally, identify a normal vector to the circle, using known geometric techniques, and define the tool orientation vector 1702 as being parallel to the normal vector. In some examples, to the extent there are two normal vectors, the processing circuitry 1522 may use the normal vector that points closer to the defined tool position (e.g., peak point of pillar 2006). In some examples, the processing circuitry 1522 may go through the same process with several or all of the markers 199 on the marker ring 1200 to identify several normal vectors, use a statistical technique (e.g., mean, mode, etc.) to identify one normal vector from the several, and use that one normal vector to define the direction the welding-type tool 1100 is oriented.
In the example of
In some examples, the processing circuitry 1522 may use the previously determined orientation(s) of the marker(s) 199 (e.g., from block 1920) to determine the translation(s). In some examples, the processing circuitry 1522 may capture new sensor data (e.g., via the monitoring sensor 1502), identify one or more new orientations of the marker(s) 199 on the marker ring 1200, and use those one or more new orientations to determine the translation(s). In some examples, the processing circuitry 1522 may define some overall orientation of the marker ring 1200 relative to its markers 199 (e.g., using the generated model of the marker ring 1200) and determine a translation between the orientation of the marker ring 1200 as a whole and the orientation of the welding-type tool 1100.
After determining the orientation translation(s) at block 1922, the marker ring calibration process 1900 proceeds to block 1924. At block 1924, the processing circuitry 1522 determines one or more translations between the position(s) of the marker(s) 199 on the marker ring 1200 and the position of the welding-type tool 1100 defined at block 1914 (e.g., peak of the pillar 2006). In some examples, the translation(s) may comprise one or more distances, directions, and/or vectors that may be added to, or subtracted from, the positions(s) of the marker(s) 199 to convert the position(s) of the marker(s) 199 to the position of the welding-type tool 1100.
In some examples, the processing circuitry 1522 may use the previously determined position(s) of the marker(s) 199 to determine the translation(s). In some examples, the processing circuitry 1522 may capture new sensor data (e.g., via the monitoring sensor 1502), identify one or more new positions of the marker(s) 199 on the marker ring 1200, and use those one or more new positions to determine the translation(s). In some examples, the processing circuitry 1522 may define some overall position of the marker ring 1200 relative to its markers 199 (e.g., using the generated model of the marker ring 1200) and determine a translation between the position of the marker ring 1200 as a whole and the position of the welding-type tool 1100. As shown, the marker ring calibration process 1900 ends after determination of the position translation(s) at block 1924.
In the example of
In some examples, even when using the alignment fixture 400, the position(s) of the workpiece(s) 122 and/or joint 124 may be variable in a direction parallel to the joint 124. That is, different joints 124 (and/or workpieces 122) may have different lengths (i.e., distance between ends), and/or may be differently positioned along their lengths. In some examples, the welding technique monitoring system 200 may use determined position(s) of the welding-type tool 1100 during a welding-type operation to determine the position(s) of the workpiece(s) 122 and/or joint 124 in a direction parallel to the joint 124. In some examples, some default position(s) may be assumed. As the height above the support platform 202 and/or positioning of the joint 124 in a direction parallel to the abutting edge(s) 218 and/or end edge(s) 216 have a far more substantial impact on the welding technique parameter values, it is more important these positions remain consistent than the position(s) in a direction parallel to the joint 124.
After prompting to properly position and/or align the joint 124 using the joint alignment fixture 400 at block 2202, the joint calibration process 2200 proceeds to block 2204. In some examples, the joint calibration process 2200 may proceed to block 2204 in response to some input from the operator 118 (e.g., received via the UI 1506) indicating that the joint 124 has been properly positioned and/or aligned. In some examples, the joint calibration process 2200 may proceed to block 2204 in response to the processing circuitry 1522 determining from sensor data captured via the monitoring sensor 1502 that the joint alignment fixture 400 has been engaged (e.g., by analyzing the visibility and/or positioning of one or more portions and/or markers 199 of the joint alignment fixture 400).
At block 2206 of the joint calibration process 2200, the processing circuitry 1522 prompts the operator 118 (e.g., via the UI 1506) to secure the workpiece(s) 122 via the clamps 204 so that the joint 124 remains properly positioned and/or aligned. In some examples, the processing circuitry 1522 further prompts for the operator 118 to disengage the joint alignment fixture 400 after securing the workpiece(s) 122 so that the joint alignment fixture 400 will not impede the remaining portions of the joint calibration process 2200.
In the example of
At block 2206, the processing circuitry 1522 prompts the operator 118 (e.g., via the UI 1506) to position a calibration device proximate a first end of the joint 124. In some examples, the calibration device is some device that can be detected by the monitoring sensor 1502 and/or whose position can be determined by the processing circuitry 1522 (e.g., via an analysis of sensor data relating to the calibration device). In some examples, the welding-type tool 1100 may be used as the calibration device. In some examples, the calibration block 2000 may be used as the calibration device. In some examples, a separate device may be used as the calibration device.
In some examples, after the calibration device is positioned proximate a first end of the joint 124, the monitoring sensor 1502 captures first (e.g., image) sensor data of and/or relating to the calibration device. In some examples, the monitoring sensor 1502 may capture the first sensor data in response to some input from the operator 118 (e.g., received via the UI 1506) indicating that the calibration device has been positioned proximate the first end of the joint 124. In some examples, the monitoring sensor 1502 may capture the first sensor data in response to the processing circuitry 1522 determining (e.g., via analysis of previously captured sensor data) that the calibration device has stayed approximately stationary for a threshold period of time. In some examples, the monitoring sensor 1502 may continuously capture sensor data, and the processing circuitry 1522 may simply define the most recently captured sensor data as being first sensor data in response to the processing circuitry 1522 determining that the calibration device has stayed approximately stationary for a threshold period of time.
In the example of
In the example of
In some examples, the processing circuitry 1522 may use the position(s) of one or more markers 199 on the calibration device to determine the position of the joint 124. In some examples, the processing circuitry 1522 may use a point at some predetermined offset from the position(s) of the calibration device and/or the marker(s) 199 on the calibration device (e.g., where the offset is stored in memory circuitry 1520 and/or as part of model of the calibration device).
In some examples the processing circuitry 1522 may use a statistical combination (e.g., average) of first and second positions of the calibration device (and/or first and/or second positions of marker(s) 199 on the calibration device) to determine the position(s) of the joint 124. In some examples, the processing circuitry 1522 may use only the first position or second position of the calibration device. As discussed above, the processing circuitry 1522 may determine position relative to the height above the support platform 202 and/or in a direction parallel to the abutting edge(s) 218 and/or end edge(s) 216.
In some examples, the processing circuitry 1522 may identify the orientation of the joint 124 as being parallel to a vector extending between the first and second positions of the calibration device, and/or a marker 199 on the calibration device. In some examples, the processing circuitry 1522 may identify the orientation of the joint 124 as being parallel to a vector extending between points at predetermined offsets from the first and second positions of the calibration device and/or the marker(s) 199 (e.g., where the offsets are stored in memory circuitry 1520 and/or as part of model of the calibration device). In some examples, the processing circuitry 1522 may identify the orientation of the joint 124 as being parallel to a statistical combination of several vectors extending between first and second positions of several markers 199 on the calibration device (and/or several points offset from the markers 199). In some examples, the processing circuitry 1522 may only use one position and orientation of the calibration device (and/or marker(s) 199 on the calibration device) to identify orientation of the joint 124 (e.g., by defining the orientation of the joint 124 as being a vector intersecting the calibration device and/or marker(s) 199 at a predetermined angle stored in memory circuitry 1520 and/or as part of model of the calibration device).
In the example of
Once sensor data of and/or relating to the marker stand 208 is obtained, the joint calibration process 2200 proceeds to block 2216. At block 2216, the processing circuitry analyzes the sensor data to determine a position and/or orientation of the marker stand 208 (and/or one or more markers 199 on the marker stand 208) relative to the monitoring sensor 1502. After determining the position and/or orientation of the marker stand 208 (and/or its markers 199), the joint calibration process 2200 proceeds to block 2218 where the processing circuitry 1522 determines the position and/or orientation of the joint 124 relative to the marker stand 208 (and/or its markers 199).
In some examples, in order to determine the position and/or orientation of the joint 124 relative to the marker stand 208 (and/or its markers 199), the processing circuitry 1522 may define an origin of a marker stand coordinate system 2302 (and/or marker reference frame) that is anchored to the marker stand 208 and/or its markers 199 (see, e.g.,
In some examples, the processing circuitry 1522 may define the origin of the marker stand coordinate system 2302 to be the position of one of the markers 199 on the marker stand 208, or some offset (e.g., saved in memory circuitry 1520). In some examples, the processing circuitry 1522 may define the axes of the marker stand coordinate system 2302 using the three dimensional orientation of one of the markers 199 on the marker stand 208 (or some angular offset therefrom).
In some examples, the processing circuitry 1522 may define the axes of the marker stand coordinate system 2302 using the positions of several markers 199 on the marker stand 208. In some examples, defining the axes using positions of markers 199 may help to avoid and/or reduce tracking jitter (e.g., slight changes in a tracked object's position and/or orientation in different sensor data samples, despite the object remaining stationary, due to noise and/or other tracking errors). In some examples, tracking jitter may be more pronounced when tracking orientation and less pronounced when tracking position (and even less pronounced when tracking positions of spaced apart markers 199), so there may be some accuracy and/or precision advantages to using position to define the axes of the marker stand coordinate system 2302.
For example, the processing circuitry 1522 may define one axis of the marker stand coordinate system 2302 as a vector extending between two approximately horizontally aligned markers 199 on the marker stand 208, a second axis as a vector extending between two approximately vertically aligned markers 199 on the marker stand 208, and the third axis as a vector perpendicular to the first two vectors. In some examples, two sets of horizontally and/or vertically aligned markers 199 may be used, and the axes defined according to a statistical analysis (e.g., mean, median, mode, etc.). In some examples, the memory circuitry 1520 may store a model of the marker stands 208 and/or their markers 199 to aid the processing circuitry 1522 in selecting the pairs of markers 199 for the axes definition. However, this example method for defining the axes relies on the markers 199 being both horizontally and/or vertically aligned, which may not always be the case and/or be difficult to implement in practice.
As another example, the processing circuitry 1522 may define a plane using positions of three of the markers 199 on the marker stand 208, and define the first axis as being the normal vector of the plane. In some examples, multiple planes and/or multiple normal vectors may be calculated using different (and/or all) sets of three markers 199 on the marker stand 208, and the first axis may be defined according to the outcome of a statistical analysis (e.g., mean, median, mode, etc.) of the multiple normal vectors. The second axis may be defined similar to the first example, using a pair of vertically or horizontally aligned markers 199, or a statistical analysis of two pairs of vertically or horizontally aligned markers 199. In some examples, this method may benefit from relative consistency in manufacturing flat planar surfaces from which to construct a marker stand 208, as well as reduction in potential for jitter through statistical analysis of multiple vectors.
The example of
In the example of
Additionally, because the saved position and orientation of the joint 124 is anchored to the marker stand 208 (and/or marker stand coordinate system 2302) rather than the monitoring sensor 1502 (and/or monitoring sensor coordinate system 2304), the system 200 can accurately determine the position(s) and/or orientation of the joint 124 even if the monitoring sensor 1502 (and/or monitoring device 1500) is moved. Therefore, if the monitoring device 1500 is removed (e.g., for maintenance) then reinserted into the monitoring device housing 206, moved around within the monitoring device housing 206, or replaced entirely, there is no additional calibration is necessary. The system 200 can simply re-detect where the marker stand 208 is relative to monitoring sensor 1502, and re-compute the translation needed to transition from the monitoring sensor coordinate system 2304 to the marker stand coordinate system 2302, given the new position and/or orientation of the monitoring sensor 1502 (and/or marker stand 208).
In some examples, the memory circuitry 1520 may additionally store joint identifying information (as discussed above) with the joint data 1524, and associate the joint identifying information with the joint data 1524. In some examples, the joint identifying information may be received from the operator 118 via the UI 1506. In some examples, the joint identifying information may be automatically determined by the processing circuitry 1522, such as, for example in response to the processing circuitry 1522 recognizing joint identifying information during an analysis of sensor data captured during the joint alignment process 2200.
In the example of
In some examples, if there is no identical match, the processing circuitry 1522 may find the joint identifying information that most and/or best matches the new joint identifying information, and use that associated joint data 1524 as the relevant joint data 1524. In some examples, the processing circuitry 1522 may apply one or more corrections to the position and/or orientation information represented by the joint data 1524 to compensate for differences between the new joint identifying information and the matched joint identifying information.
After identifying the relevant joint data 1524 at block 2402, the joint identification process proceeds to block 2404. At block 2404, the processing circuitry 1522 decodes the joint data 1524 to determine the position(s) and/or orientation of the joint 124 relative to the marker stand 208, the markers 199 on the marker stand 208, and/or the marker stand coordinate system 2302. Thereafter, at block 2406, the monitoring sensor 1502 captures sensor data of and/or relating to the marker stand 208 and/or the markers 199 on the marker stand 208. Afterwards, the processing circuitry 1522 identifies the positions and/or orientations of one or more markers 199 on the marker stand 208 at block 2408, and then determines the marker stand coordinate system 2302 based on those positions and/or orientations at block 2410. Following this step, the processing circuitry 1522 determines a translation between the marker stand coordinate system 2302 and the sensor coordinate system 2304 at block 2412, then transitions the position(s) and/or orientation of the joint 124 to the monitoring system coordinate system 2304 at block 1414 using the translation. In some examples, the operations of blocks 2404-2414 are similar, or identical, to those of blocks 2212-2218 previously discussed above (e.g., in a somewhat inverted order), and so further discussion is omitted in the interest of brevity.
In the example of
Once the position and/or orientation of the welding-type tool 1100 is determined, the test weld process 2500 proceeds to block 2504, where the processing circuitry 1522 determines whether the welding-type tool 1100 is within a threshold test range of the joint 124. In some examples, the threshold test range may be representative of a maximum distance between the joint 124 and the welding-type tool 1100 for a welding-type operation (e.g., maximum possible arc length), and/or a distance slightly beyond. In some examples, the determination as to whether the welding-type tool 1100 is within the threshold test range may involve determining a distance between the position of the joint 124 (e.g., determined during the joint identification process 2400) and the position of the welding-type tool 1100 (e.g., determined at block 2502), and comparing the distance with the threshold test range.
In the example of
If, on the other hand, the welding-type tool 1100 is determined to be within the threshold test range of the joint 124, the test weld process 2500 proceeds to block 2506 where the processing circuitry 1522 determines whether the welding-type tool 1100 is pointed at the monitoring sensor 1502. In some examples, having the welding-type tool 1100 pointed towards the monitoring sensor 1502 during a welding-type operation may result in sparks that may travel over the filter housing top wall 910 of the light filter housing 900, and/or interfere with capture of sensor data by the monitoring sensor 1502. The interference may be especially pronounced if the sparks get between the monitoring sensor 1502 and the marker ring 1200 (e.g., due to the proximity of the sparks and/or the sparks' unfiltered brightness). This interference may result in sensor data errors, monitoring errors, and/or feedback errors, and so is best avoided. However, if the welding-type tool 1100 is pointed away from the monitoring sensor 1502 during the welding-type operation, the light from any sparks may be attenuated by distance and/or substantially blocked by the welding-type tool 1100 and/or the operator 118, reducing the chance of interference.
In some examples, determining whether the welding-type tool 1100 is pointed at the monitoring sensor 1502 may involve determining whether the tool orientation vector 1702 would intersect a sensor plane 2602 of the monitoring sensor 1502 if the tool orientation vector 1702 were extended (e.g., infinitely). In some examples, the sensor plane 2602 may be a plane perpendicular to a sensor axis 2604 at an approximate middle of a field of view of the monitoring sensor 1502. In some examples, the processing circuitry 1522 may determine the sensor plane 2602 using sensor data captured by the monitoring sensor 1502. In some examples, the sensor plane 2602 may be known, predetermined, and/or saved in memory circuitry 1520.
In the example of
In the example of
In some examples, the remedial instructions output at block 2508 may indicate that, or how, the welding technique monitoring system 200 should be configured to ensure that the welding-type tool 1100 is pointed away from the monitoring sensor 1502 during a welding-type operation. For example, the instructions may explain that the alignment platform 202b can be rotated so that the welding-type tool 1100 can be pointed away from the monitoring sensor 1502 when the operator 118 is handling the welding-type tool 1100 with their preferred hand. As another example, the instructions may explain that the welding technique monitoring system 200 is currently configured for operation with a particular hand, and instruct the operator 118 to change the hand they are using to handle the welding-type tool 1100 if they wish to continue using the current configuration. In some examples, the processing circuitry 1522 may analyze sensor data of and/or relating to the marker stand 208 and/or the joint alignment fixture 400 (and/or their respective markers 199) to determine for which particular hand the welding technique monitoring system 200 is currently configured. After block 2508, the test weld process 2500 ends.
However, unlike the welding technique monitoring system 200 of
In some examples, using two monitoring devices 1500 positioned at opposite ends of the support platform 202 may allow for the second alternative welding technique monitoring system 2700 to be used to monitor left or right handed welding-type operations, with no need for the clamps 204 to be repositioned or the support platform 202 to be reconfigured (e.g., reoriented). With two monitoring devices 1500, regardless of which direction the welding-type tool 1100 is pointed, the welding-type tool 1100 should be always be pointed away from at least one of the monitoring sensors 1502 of at least one of the monitoring devices 1500. Thus, at least one monitoring sensor 1502 of at least monitoring device 1500 should not be interfered with, and/or impeded by, sparks coming between the welding-type tool 1100 and monitoring sensor 1502 during a welding-type operation.
In examples where sparks do not interfere with and/or impede either monitoring device 1500 (and/or either monitoring sensor 1502), the data detected by the monitoring devices 1500 may allow for more consistent, accurate, and/or precise tracking and/or monitoring, due to the redundancy. In such examples, the monitoring devices 1500 may communicate with one another (e.g., via their respective communication interfaces 1504) to time synchronize the redundant sensor data.
In
In some examples, a single monitoring device 1500 may be used instead of two monitoring devices 1500. In such examples, the single monitoring device 1500 may be moved between the first and second monitoring device housings 206 as needed for left/right handed welding-type operations. In some examples, only one monitoring device 1500 and one monitoring device housing 206 may be used, and the monitoring device housing 206 (with the monitoring device 1500 inside) may simply be configured for removal from one end, and reattachment to the other end, of the support platform 202 (e.g., as discussed above).
In the examples of
For example, some monitoring devices 1500 may have a monitoring sensor 1502 that is positioned more to one side or another (rather than in the center) of the monitoring device 1500. In such instances, a housing stand 2702 may be used to set one of the monitoring device housings 206 at a different height than the other monitoring device housing 206. The different heights provided by the housing stand(s) 2702 may ensure that the monitoring sensors 1502 are aligned (and/or at the same height/distance above the surface 201 of the support platform 202), despite being offset in opposite directions.
In some examples, one or both housing stands 2702 may be removable from and/or attachable to the surface 201 of the support platform 202 (e.g., similar to that which is discussed above with respect to the monitoring device housing 206 and support platform 202). In some examples, the monitoring device housings 206 may be removable from and/or attachable to the housing stands 2702 (e.g., similar to that which is discussed above with respect the monitoring device housings 206 and support platform 202). In some examples, different housing stands 2702 may be swapped in and/or out to position the monitoring device housing(s) 206 and/or monitoring sensor(s) 1502 at the appropriate height and/or elevation above the surface 201 of the support platform 202. As used here, the height or elevation above the surface 201 of the support platform 202 refers to the distance and/or space away from the surface 201 of the support platform 202 in a direction perpendicular to the plane of the surface 206 of the support platform 202.
In the examples of
The second alternative welding technique monitoring system 2700 also differs from the welding technique monitoring system 200 in that the second alternative welding technique monitoring system 2700 lacks a light filter 902 and/or light filter housing 900. Instead, light blockers 2704 are attached to the support platform 202. Each light blocker 2704 is shown as having a blocker base attached to, and extending parallel to, the support platform 202. Extending up from, and perpendicular to, the blocker base is a light blocking wall. As shown, the light blockers 2702 are aligned with one another, with the monitoring positions of the monitoring sensors 1502, and with the expected position/orientation of the welding joint 124.
In some examples, each light blocker 2704 is configured to block (e.g., arc) light from being directly visible by the monitoring sensor 1502, while still allowing the marker(s) 199 on the marker ring 1200/1300/1400/3200 to be visible. In some examples, each light blocker 2704 is comprised of an opaque material that is impenetrable to light. As shown, each light blocker 2704 is positioned between the expected monitoring position of the monitoring sensor 1502 and the expected position of the welding joint 124. Thus, when (e.g., arc) light is produced proximate the welding joint 124, light that would've otherwise been directly visible to and/or directly detected by the monitoring sensor 1502 is instead blocked from direct view by the light blocker 2704.
In some examples, the monitoring sensor(s) 1502 may nevertheless detect (e.g., arc) light produced by the welding-type operation, despite the arc blockers 2704. Though the arc blockers 2704 may block the monitoring sensor(s) 1502 from directly observing or detecting the (e.g., arc) light generated by the welding-type operation at the welding joint 124, the (e.g., arc) light may still illuminate and/or brighten the surrounding environment. Thus, the monitoring sensor(s) 1502 may observe and/or detect the (e.g., arc) light indirectly by observing and/or detecting the illumination and/or brightness of the surrounding environment.
In some examples, the monitoring sensor(s) 1502 may capture sensor data relating to the surrounding environment, and the technique monitoring process 1600 may analyze characteristics and/or properties of the sensor data to determine (e.g., at block 1606) whether a welding-type operation is taking place. For example, the technique monitoring process 1600 may determine a welding-type operation is occurring (and/or has started) when sensor data indicates the (e.g., average, mode, medium, etc.) brightness of the environment has increased beyond a threshold, and/or that the brightness has increased at a rate that exceeds a threshold rate. As another example, the technique monitoring process 1600 may determine a welding-type operation is not occurring (and/or has stopped) when the sensor data indicates the brightness of the environment has decreased below a threshold, and/or that the brightness has decreased at a rate that exceeds a threshold rate (e.g., in terms of absolute value of the rate(s)).
In some examples where the captured sensor data is representative of a captured image, the technique monitoring process 1600 may analyze characteristics and/or properties of the image to determine (e.g., at block 1606) whether a welding-type operation is taking place. In particular, the technique monitoring process 1600 may analyze certain values of one or more Red Blue Green (RGB) color model representations to determine whether a welding-type operation is taking place. For example, the RGB color values in a hue, saturation, value (HSV), and/or hue, saturation, level (HSL), color model representation may be analyzed to determine whether a welding-type operation is taking place.
In such examples, a welding-type operation may be determined to have begun or ceased when there is an upward or downward spike (e.g., over a threshold slope/rate) of the (e.g., average, mode, medium, etc.) hue, saturation, and/or value/level in the captured image. While the value and/or level might seem to be the best indicator of a welding-type operation (as value/level are generally seen as synonymous with brightness), surprisingly empirical evidence seems to indicate that changes in hue might be better used as an indicator of whether a welding-type operation has started/stopped.
In particular, the hue has been observed to dramatically spike up or down when a welding-type operation begins or ends, and otherwise stay approximately constant. Though saturation and value/level quantities also spike at the beginning and/or end of a welding-type operation, their steady state quantities after the spike have been observed to fluctuate far more than hue. Because the rate of change (and/or slope) of the (e.g., average, mode, medium, etc.) hue is approximately zero except when a welding-type operation begins or ends (unlike saturation and/or value/level), it may be easier to use hue as an indicator of welding-type operation than saturation and/or value/level.
In some examples where the monitoring sensor 1502 is a camera and/or optical sensor, camera/sensor exposure values may also be used to determine whether a welding-type operation is occurring. In some examples, camera/sensor exposure refers to how long a camera/sensor receives light before capturing (e.g., image) data. In some cameras and/or image sensors the exposure time is automatically set and/or adjusted to keep the average brightness and/or intensity of each image approximately the same. Thus, if there is suddenly a bright light (e.g., as might occur when a welding-type operation begins), the exposure time may be automatically (and/or drastically) decreased (e.g., at more than a threshold rate). And if the light suddenly disappears (e.g., as might occur when a welding-type operation ends), the exposure time may be automatically (and/or drastically) increased (e.g., at more than a threshold rate). Thereby, automatic changes in exposure time may be used to determine whether a welding-type operation has started/stopped, and/or is underway.
Using the above methods, the technique monitoring process 1600 can identify if a welding-type operation is occurring when light blockers 2704 are used instead of light filters 902. In some examples, the light blockers 2704 may be cheaper alternatives to light filters 902, and yet sufficiently effective to still allow for efficient monitoring. In some examples, the light blockers 2704 may also be relatively low profile, and thereby take up significantly less space than the light filters 902. Due to the lower profile, the light blockers 2704 may allow for the monitoring device 1500 to be located closer to the welding joint 124 than when using the light filters 902, which may increase monitoring accuracy.
However, unlike the second alternative welding technique monitoring system 2700, the marker stands 208 of the third alternative welding technique monitoring system 2800 are shown as being attached to (and/or part of) alternative monitoring device housings 2806, rather than being attached to the support surface 202. In the examples of
The third alternative welding technique monitoring system 2800 is also shown as having alternative light blockers 2804, instead of the light blockers 2704 of the second alternative welding technique monitoring system 2700. And rather than being attached to the support platform 202, the alternative light blockers 2804 are shown in
By combining the marker stands 208 and alternative light blockers 2804 with the alternative monitoring device housings 2806, the third alternative welding technique monitoring system 2800 reduces the amount of clutter on the support platform 202. The reduced clutter provides more space on the support platform 202 for the operator 118 to maneuver the welding-type tool 1100. The reduced clutter also makes the support platform 202 easier to clean should the support platform 202 become soiled (e.g., with spatter, debris, etc.). The reduced clutter also makes it possible to position the monitoring device 1500 even closer to the expected position of the welding joint 124, which may further increase monitoring accuracy.
In the examples of
In some examples, each monitoring device platform housing 2808 includes housing connectors 2812 configured for tool-less connection with complementary housing connectors 2814 of the monitoring device removable housing 2810. In the example of
In some examples, the housing connectors 2812 and/or complementary housing connectors 2814 may be arranged in a poka yoke configuration. The poka yoke configuration may ensure that each monitoring device removable housing(s) 2810 may only be connected to each monitoring device platform housing 2808 in a particular orientation. This may be particularly helpful where there is only one monitoring device removable housing 2810 (e.g., housing one monitoring device 1500), and that one monitoring device removable housing 2810 must be moved between (and connected to/disconnected from) both monitoring device platform housings 2808. In such situations, it may be important that the monitoring device removable housing 2810 connects with a particular monitoring device platform housing 2808 in a particular orientation to ensure correct positioning and/or orientation of the monitoring sensor 1502 (e.g., facing the expected position of the welding joint 124 and at approximately the same position relative to the opposing markers 199/marker stand(s) 208 as when connected to the opposite monitoring device platform housing 2808).
As shown, the housing connectors 2812x of both monitoring device platform housings 2808 are aligned with one another on the left side of the page, while the housing connectors 2812y of both monitoring device platform housings 2808 are aligned with one another on the right. In this configuration, the monitoring device removable housing 2810 must be flipped about its longitudinal axis 2900 when moving between monitoring device platform housings 2808 in order to align its complementary connector 2814y (i.e., channel) with the housing connector 2812y (i.e., rail), and align its complementary connector 2814x (i.e., rail) with the housing connector 2812x (i.e., channel).
Importantly, this flip of the monitoring device removable housing 2810 about the longitudinal axis 2900 keeps the expected position of the monitoring sensor 1502 facing the welding joint 124, and at approximately the same position relative to the opposing markers 199/marker stand(s) 208, regardless of to which monitoring device platform housing 808 the monitoring device removable housing 2810 is connected. Were the monitoring device removable housing 2810 allowed to instead be rotated about its lateral axis (e.g., perpendicular to the longitudinal axis 2900), the expected monitoring position of the monitoring sensor 1502 would still be facing the welding joint 124, but would be at a different position relative to the opposing markers 199/marker stand(s) 208 than when connected with the opposing monitoring device platform housing 808. Such a difference in relative positioning may negatively impact the joint calibration process 2200 and/or joint identification process 2400 when moving the monitoring device 1500 to accommodate a change in right/left handed welding-type operations. Thus, the poka yoke configuration ensures correct positioning and alignment of the monitoring sensor 1502 when the monitoring device 1500 and monitoring device removable housing 2810 is moved between monitoring device platform housings 2808.
In some examples, housing stands 2702 may be used with the third alternative welding technique monitoring system 2800, similar to that which is described above with respect to the second alternative welding technique monitoring system 2700. For example, complementary housing connectors 2814 (e.g., channels) may be formed in a housing stand 2702, such that it may connect with the monitoring device platform housing 2808 prior to connection of the monitoring device removable housing 2810. In such examples, the housing stands 2702 may increase the elevation of the monitoring device removable housing 2810 (and/or monitoring device 1500) as needed.
In the examples of
However, even when outside a field of detection (and/or field of view) of the monitoring sensor 1502, (e.g., arc) light produced by the welding-type operation may still impinge upon the monitoring sensor 1502. Where the monitoring device 1500 is a camera and/or optical sensor, this situation may result in a phenomenon called “lens flare,” where bands of light appear in a captured image and/or video, obscuring the scene(s) depicted in the image/video. In the examples of
In the examples of
While the alternative light blockers 2804 cover a portion of the marker stands 208, there is still enough room on the marker stands 208 for three markers 199 to be shown on each monitoring device platform housing 2808, which is sufficient to determine a marker stand coordinate system (e.g., at block 2410 of the joint identification process 2400). Additionally, in some examples, a marker 199 may be inscribed/attached atop the alternative light blocker 2804.
In the examples of
In
While the angle of the monitoring device 1500 and positioning of the alternative light blocker 2804 may reduce the likelihood that (e.g., arc) light produced by the welding-type operation will directly impinge upon the monitoring sensor 1502, the monitoring sensor 1502 may nevertheless indirectly detect the (e.g., arc) light illuminating the surrounding environment, as discussed above. This indirect detection may enable the third alternative welding technique monitoring system 2800 to determine when a welding-type operation begins and/or ends, as discussed above.
While, in the examples of
The disclosed welding technique monitoring system 200 (and/or first alternative welding technique monitoring system 600, second alternative welding technique monitoring system 2700, and/or third alternative welding technique monitoring system 2800) is a lightweight, compact, self-contained, and highly portable means of monitoring welding technique and/or providing feedback. The relatively lightweight and compact systems 200/600/2700/2800 can be easily transported to different welding stations/sites, providing a marked advantage over legacy monitoring systems that use heavy welding stands that are difficult to move. The joint alignment fixture 400/500/700 and marker stands 208 enable the systems 200/600/2700/2800 to consistently and repeatedly monitor welding technique relative to a particular type of joint 124, with only a single, simple calibration. And the systems 200/600/2700/2800 can continue accurate monitoring (with no additional calibration) even if the monitoring sensor 1502 and/or support platform 202 is moved. Additionally, the use of a light filter 902 and/or light blocker 2704/2804 enables the systems 200/600/2700/2800 to detect a welding-type operation without the need to worry about establishing communication between the system 200/600 and welding-type equipment 104. The systems 200/600/2700/2800 are further configured for use with existing (rather than potentially expensive custom), welding-type tools 1100, thereby keeping the systems 200/600/2700/2800 low cost and highly portable. The systems 200/600/2700/2800 are further configured to use off the shelf monitoring devices 1500 (e.g., mobile devices) for all the electronic functions, thereby simplifying equipment and/or power/battery management.
The present methods and/or systems may be realized in hardware, software, or a combination of hardware and software. The present methods and/or systems may be realized in a centralized fashion in at least one computing system, or in a distributed fashion where different elements are spread across several interconnected computing or cloud systems. Any kind of computing system or other apparatus adapted for carrying out the methods described herein is suited. A typical combination of hardware and software may be a general-purpose computing system with a program or other code that, when being loaded and executed, controls the computing system such that it carries out the methods described herein. Another typical implementation may comprise an application specific integrated circuit or chip. Some implementations may comprise a non-transitory machine-readable (e.g., computer readable) medium (e.g., FLASH drive, optical disk, magnetic storage disk, or the like) having stored thereon one or more lines of code executable by a machine, thereby causing the machine to perform processes as described herein.
While the present method and/or system has been described with reference to certain implementations, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the present method and/or system. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the present disclosure without departing from its scope. Therefore, it is intended that the present method and/or system not be limited to the particular implementations disclosed, but that the present method and/or system will include all implementations falling within the scope of the appended claims.
While this disclosure sometimes refers to up, down, left, and right for the sake of explanation, persons of ordinary skill will recognize that this a shorthand that might be more precisely described using elements of the welding technique monitoring system 200 and geometric principles (e.g., where up is a direction defined by a vector extending between the surface 201 of the support platform 202 and the filter housing top wall 910 of the light filter housing 900, where the vector extends approximately perpendicular to the surface 201 of the support platform 202, down is the opposite direction, and left/right are opposite vectors approximately parallel to the end edges 216 and/or abutting edges 218 of the support platform 202 and/or approximately perpendicular to up/down).
As used herein, “approximately,” with respect to an angle, means within three degrees of the angle, unless otherwise specified. With respect to position, “approximately” means within three millimeters of that position, unless otherwise specified.
As used herein, “and/or” means any one or more of the items in the list joined by “and/or”. As an example, “x and/or y” means any element of the three-element set {(x), (y), (x, y)}. In other words, “x and/or y” means “one or both of x and y”. As another example, “x, y, and/or z” means any element of the seven-element set {(x), (y), (z), (x, y), (x, z), (y, z), (x, y, z)}. In other words, “x, y and/or z” means “one or more of x, y and z”.
As utilized herein, the terms “e.g.,” and “for example” set off lists of one or more non-limiting examples, instances, or illustrations.
As used herein, the terms “coupled,” “coupled to,” and “coupled with,” each mean a structural and/or electrical connection, whether attached, affixed, connected, joined, fastened, linked, and/or otherwise secured. As used herein, the term “attach” means to affix, couple, connect, join, fasten, link, and/or otherwise secure. As used herein, the term “connect” means to attach, affix, couple, join, fasten, link, and/or otherwise secure.
As used herein the terms “circuits” and “circuitry” refer to physical electronic components (i.e., hardware) and any software and/or firmware (“code”) which may configure the hardware, be executed by the hardware, and or otherwise be associated with the hardware. As used herein, for example, a particular processor and memory may comprise a first “circuit” when executing a first one or more lines of code and may comprise a second “circuit” when executing a second one or more lines of code. As utilized herein, circuitry is “operable” and/or “configured” to perform a function whenever the circuitry comprises the necessary hardware and/or code (if any is necessary) to perform the function, regardless of whether performance of the function is disabled or enabled (e.g., by a user-configurable setting, factory trim, etc.).
As used herein, a control circuit may include digital and/or analog circuitry, discrete and/or integrated circuitry, microprocessors, DSPs, etc., software, hardware and/or firmware, located on one or more boards, that form part or all of a controller, and/or are used to control a welding process, and/or a device such as a power source or wire feeder.
As used herein, the term “processor” means processing devices, apparatus, programs, circuits, components, systems, and subsystems, whether implemented in hardware, tangibly embodied software, or both, and whether or not it is programmable. The term “processor” as used herein includes, but is not limited to, one or more computing devices, hardwired circuits, signal-modifying devices and systems, devices and machines for controlling systems, central processing units, programmable devices and systems, field-programmable gate arrays, application-specific integrated circuits, systems on a chip, systems comprising discrete elements and/or circuits, state machines, virtual machines, data processors, processing facilities, and combinations of any of the foregoing. The processor may be, for example, any type of general purpose microprocessor or microcontroller, a digital signal processing (DSP) processor, an application-specific integrated circuit (ASIC), a graphic processing unit (GPU), a reduced instruction set computer (RISC) processor with an advanced RISC machine (ARM) core, etc. The processor may be coupled to, and/or integrated with a memory device.
As used, herein, the term “memory” and/or “memory device” means computer hardware or circuitry to store information for use by a processor and/or other digital device. The memory and/or memory device can be any suitable type of computer memory or any other type of electronic storage medium, such as, for example, read-only memory (ROM), random access memory (RAM), cache memory, compact disc read-only memory (CDROM), electro-optical memory, magneto-optical memory, programmable read-only memory (PROM), erasable programmable read-only memory (EPROM), electrically-erasable programmable read-only memory (EEPROM), a computer-readable medium, or the like. Memory can include, for example, a non-transitory memory, a non-transitory processor readable medium, a non-transitory computer readable medium, non-volatile memory, dynamic RAM (DRAM), volatile memory, ferroelectric RAM (FRAM), first-in-first-out (FIFO) memory, last-in-first-out (LIFO) memory, stack memory, non-volatile RAM (NVRAM), static RAM (SRAM), a cache, a buffer, a semiconductor memory, a magnetic memory, an optical memory, a flash memory, a flash card, a compact flash card, memory cards, secure digital memory cards, a microcard, a minicard, an expansion card, a smart card, a memory stick, a multimedia card, a picture card, flash storage, a subscriber identity module (SIM) card, a hard drive (HDD), a solid state drive (SSD), etc. The memory can be configured to store code, instructions, applications, software, firmware and/or data, and may be external, internal, or both with respect to the processor.
The term “power” is used throughout this specification for convenience, but also includes related measures such as energy, current, voltage, and enthalpy. For example, controlling “power” may involve controlling voltage, current, energy, and/or enthalpy, and/or controlling based on “power” may involve controlling based on voltage, current, energy, and/or enthalpy.
As used herein, welding-type refers to actual live, and/or simulated, welding (including laser welding and/or hot wire welding), cladding (including laser cladding), brazing, plasma cutting, induction heating, carbon arc cutting or gouging, hot wire preheating, and/or resistive preheating.
As used herein, a welding-type tool refers to a tool suitable for and/or capable of actual live, and/or simulated, welding (including laser welding and/or hot wire welding), cladding (including laser cladding), brazing, plasma cutting, induction heating, carbon arc cutting or gouging, hot wire preheating, and/or resistive preheating.
As used herein, welding-type power refers to power suitable for actual live welding (including laser welding and/or hot wire welding), cladding (including laser cladding), brazing, plasma cutting, induction heating, carbon arc cutting or gouging, hot wire preheating, and/or resistive preheating.
As used herein, a welding-type power supply and/or welding-type power source refers to a device capable of, when input power is applied thereto, supplying output power suitable for actual live welding (including laser welding and/or hot wire welding), cladding (including laser cladding), brazing, plasma cutting, induction heating, carbon arc cutting or gouging, hot wire preheating, and/or resistive preheating; including but not limited to transformer-rectifiers, inverters, converters, resonant power supplies, quasi-resonant power supplies, switch-mode power supplies, etc., as well as control circuitry and other ancillary circuitry associated therewith.
This application claims priority to, and the benefit of, U.S. Provisional Patent Application No. 63/462,312, filed Apr. 27, 2023, entitled “Light Filters for Portable Welding Technique Monitoring Systems,” the entire contents of which are hereby incorporated by reference.
Number | Date | Country | |
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63462312 | Apr 2023 | US |