It is commonplace to apply glutinous substances, such as sealants, adhesives, and fillers, to surfaces of structures or other objects for purposes of sealing, corrosion resistance, and/or fixation, among others. However, surface application of glutinous substances in an efficient, predictable, and uniform manner using manual techniques is difficult and time consuming.
Accordingly, apparatuses and methods, intended to address at least the above-identified concerns, would find utility.
The following is a non-exhaustive list of examples, which may or may not be claimed, of the subject matter according to the present disclosure.
One example of the subject matter according to the present disclosure relates to a brush for delivering a glutinous substance to a workpiece from an end-effector. The brush comprises a body, having a rotational axis and comprising a first channel that comprises an inlet and a first outlet. The inlet is coaxial with the rotational axis and the first outlet is offset from the rotational axis. Additionally, the brush comprises tufts, extending from the body and each comprising a tip and at least one bristle. The brush further comprises a first tube, communicatively coupled with the first outlet of the first channel of the body.
Another example of the subject matter according to the present disclosure relates to a method of delivering a glutinous substance to a workpiece from an end-effector. The workpiece comprises a surface and a fastener, having a head. The head of the fastener extends from the surface of the workpiece and comprises a lateral surface and an end surface. The method comprises using the end-effector to rotate a brush relative to the workpiece about a rotational axis of a body of the brush. The body of the brush comprises a first channel that comprises an inlet and a first outlet. The inlet is coaxial with the rotational axis and the first outlet is offset from the rotational axis. The body of the brush further comprises tufts, extending from the body and each comprising a tip and at least one bristle. The brush comprises a first tube, communicatively coupled with the first outlet of the first channel of the body. The method also comprises, while rotating the brush relative to the workpiece about the rotational axis of the body, causing the end-effector to urge the glutinous substance through the first channel of the body of the brush from the inlet of the first channel to the first outlet of the first channel and through the first tube, into contact with the tufts. Additionally, the method comprises, while urging the glutinous substance into contact with the tufts, using the end-effector to position the brush relative to the workpiece such that the rotational axis of the body of the brush is collinear with a central axis of the fastener and the glutinous substance, in contact with the tufts, is delivered onto the surface of the workpiece and the fastener.
Having thus described examples of the present disclosure in general terms, reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and wherein like reference characters designate the same or similar parts throughout the several views, and wherein:
In
In
In the following description, numerous specific details are set forth to provide a thorough understanding of the disclosed concepts, which may be practiced without some or all of these particulars. In other instances, details of known devices and/or processes have been omitted to avoid unnecessarily obscuring the disclosure. While some concepts will be described in conjunction with specific examples, it will be understood that these examples are not intended to be limiting.
Unless otherwise indicated, the terms “first,” “second,” etc. are used herein merely as labels, and are not intended to impose ordinal, positional, or hierarchical requirements on the items to which these terms refer. Moreover, reference to, e.g., a “second” item does not require or preclude the existence of, e.g., a “first” or lower-numbered item, and/or, e.g., a “third” or higher-numbered item.
Reference herein to “one example” means that one or more feature, structure, or characteristic described in connection with the example is included in at least one implementation. The phrase “one example” in various places in the specification may or may not be referring to the same example.
As used herein, a system, apparatus, structure, article, element, component, or hardware “configured to” perform a specified function is indeed capable of performing the specified function without any alteration, rather than merely having potential to perform the specified function after further modification. In other words, the system, apparatus, structure, article, element, component, or hardware “configured to” perform a specified function is specifically selected, created, implemented, utilized, programmed, and/or designed for the purpose of performing the specified function. As used herein, “configured to” denotes existing characteristics of a system, apparatus, structure, article, element, component, or hardware which enable the system, apparatus, structure, article, element, component, or hardware to perform the specified function without further modification. For purposes of this disclosure, a system, apparatus, structure, article, element, component, or hardware described as being “configured to” perform a particular function may additionally or alternatively be described as being “adapted to” and/or as being “operative to” perform that function.
Illustrative, non-exhaustive examples, which may or may not be claimed, of the subject matter according the present disclosure are provided below.
Referring generally to
Brush 200 is configured to facilitate ease and efficiency associated with the application of glutinous substances onto surfaces of workpieces. Inlet 209, being coaxial with rotational axis 238 of body 202, allows flow of glutinous substance 168 through first channel 208 as brush 200 rotates about rotational axis 238. First outlet 280 of first channel 208 of body 202, being offset from rotational axis 238, helps distribute glutinous substance 168 to locations offset from rotational axis 238. First tube 210 facilitates flow of glutinous substance 168 from first outlet 280 of first channel 208 of body 202 to workpiece 170. Tufts 222 promote the spreading and uniform distribution of glutinous substance 168 on workpiece 170.
In some examples, body 202 of brush 200 includes shaft 204 and head 206. Shaft 204 may be configured to be coupled to end-effector 102 in co-rotatable engagement with end-effector 102. Head 206 has a larger cross-sectional area, in a plane perpendicular to rotational axis 238, than shaft 204. Inlet 209 can be defined by shaft 204 and first outlet 280 can be defined by head 206. In one example, body 202 of brush 200 has a one-piece monolithic construction. In such an example, body 202 can be made of metal. In yet some examples, body 202 can have a multi-piece construction. According to certain examples, shaft 204 is made of metal. According to some examples, tufts 222 are spaced-apart from each other.
Referring generally to
First tube 210, being more flexible than body 202, absorbs potential impacts with workpiece 170, while brush 200 delivers glutinous substance 168 to workpiece 170, more effectively than body 202. For example, first tube 210 can be configured to flex upon an impact with workpiece 170 while brush 200 delivers glutinous substance 168 to workpiece 170.
Referring generally to
First channel 208, being cross-sectionally circumferentially closed, facilitates discrete containment of the flow of glutinous substance 168 through body 202.
Referring generally to
First tube 210, extending from body 202 a shorter distance than at least one of tufts 222 along rotational axis 238 of body 202, helps to promote spreading and uniform distribution of glutinous substance 168 delivered from first tube 210 to workpiece 170 by at least one of tufts 222.
Referring generally to
First tube 210, being parallel to rotational axis 238 of body 202, facilitates flow of glutinous substance 168 onto workpiece 170 in a direction parallel to rotational axis 238 of body 202.
Referring generally to
First tube 210, being oblique to rotational axis 238 of body 202, enables first tube 210 to flex into an orientation parallel to rotational axis 238 of body 202 when brush 200 is being rotated. For example, while brush 200 is being rotated, contact with workpiece 107 by first tube 210 may cause first tube 210 to flex from being oblique to rotational axis 238 of body 202 to being parallel to rotational axis 238 of body 202. When first tube 210 is in an unflexed state, first central axis 270 of first tube 210 can form angle θ4 with rotational axis 238.
Referring generally to
At least two of tufts 222, being oblique to each other, promotes broader coverage of glutinous substance 168 on workpiece 170. For example, one tuft 222 can form angle θ1 with rotational axis 238, another tuft 222 can form angle θ2 with rotational axis 238, and yet another tuft 222 can form angle θ3, where at least two of angle θ1, angle θ2, and angle θ3 are different from each other.
Referring generally to
At least one of tufts 222, being parallel to rotational axis 238 of body 202, and at least another one of tufts 222, being oblique to rotational axis 238 of body 202, promote broader coverage of glutinous substance 168 on workpiece 170.
Referring generally to
Tip 227 of at least the first one of tufts 222, being farther away from rotational axis 238 of body 202 than any other portion of at least the first one of tufts 222, facilitates coverage of glutinous substance 168 on workpiece 170 at locations on workpiece 170 farther away from rotational axis 238 than where at least the first one of tufts 222 extends from body 202. Tips 227 of tufts 222 are positioned second distance D2 away from rotational axis 238.
Referring generally to
Tip 227 of at least the second one of tufts 222, being closer to rotational axis 238 of body 202 than any other portion of at least the second one of tufts 222, facilitates coverage of glutinous substance 168 on workpiece 170 at locations on workpiece 170 closer to rotational axis 238 than where at least the second one of tufts 222 extends from body 202.
Referring generally to
Second plurality of tufts 224, extending from body 202 at locations on body 202 that lie along curvilinear path 251, promote application of glutinous substance 168 onto surface 237 of workpiece 170 around head 232 of fastener 230 and onto at least lateral surface 233 of head 232 of fastener 230. Tufts 222 extend from body 202 at locations first distance D1 away from rotational axis 238.
In some examples, fastener 230 has central axis 239 and comprises shank 234, extending at least partially through workpiece 170, and head 232, extending from workpiece 170. Head 232 comprises end surface 235 that may comprise a recess or depression. According to certain examples, lateral surface 233 of head 232 of fastener 230 is parallel to central axis 239 of fastener 230 and end surface 235 of head 232 of fastener 230 is perpendicular to central axis 239 of fastener 230.
Referring generally to
Tips 227 of first group of tufts 225 of second plurality of tufts 224, being equidistant from rotational axis 238 of body 202, promote uniform coverage of glutinous substance 168 onto lateral surface 233 of head 232 of fastener 230.
Referring generally to
Tips 227 of first group of tufts 225, each being differently spaced from a virtual plane perpendicular to rotational axis 238 of body 202, provides for broader or complete coverage of lateral surface 233 of head 232 of fastener 230 along central axis 239 of fastener 230.
As used herein, “virtual” means having attributes of an entity without possessing its physical form. For example, a virtual reference plane is an intangible or imaginary plane, rather than a physical one, with respect to which, e.g., location and/or orientation of other physical and/or intangible entities may be defined.
Referring generally to
Tips 227 of second group of tufts 226, being equidistant from a virtual plane perpendicular to rotational axis 238 of body 202, promotes uniform coverage of glutinous substance 168 on surface 237 of workpiece 170 around head 232 of fastener 230.
Referring generally to
Tips 227 of second group of tufts 226, each being differently spaced from rotational axis 238 of body 202, promotes broader coverage of surface 237 of workpiece 170 away from rotational axis 238 of body 202 in directions perpendicular to rotational axis 238.
Referring generally to
End faces 247 of first group of tufts 225, being parallel to rotational axis 238 of body 202, promote uniform coverage of glutinous substance 168 onto lateral surface 233 of head 232 of fastener 230. End faces 247 of second group of tufts 226, being perpendicular to rotational axis 238 of body 202, promote uniform coverage of glutinous substance 168 on surface 237 of workpiece 170 around head 232 of fastener 230.
Referring generally to
Spiral path 241 promotes positioning of second plurality of tufts 224 around fastener 230 and accommodates coupling of second plurality of tufts 224 to body 202. For example, curvilinear path 251, being spiral path 241, provides body 202 with enough material to accommodate the formation of receptacles 297 in body 202, which receive and retain respective ones of plurality of tufts 224.
Referring generally to
Circular path 243 promotes positioning of second plurality of tufts 224 around fastener 230.
Referring generally to
Locations on body 202 that lie along circular path 243, being equidistant from rotational axis 238 of body 202, facilitate positioning of second plurality of tufts 224 around fastener 230.
Referring generally to
Laying first plurality of tufts 223 at locations on body 202 along linear path 245 facilitates application of glutinous substance 168 onto end surface 235 of fastener 230.
Referring generally to
Linear path 245 not intersecting rotational axis 238 of body 202 provides ability to apply glutinous substance 168 to less than all portions of end surface 235 of head 232 of fastener 230. For example, it may be desirable to not apply glutinous substance 168 to a tool engagement recess in end surface 235 of head 232 of fastener 230.
Referring generally to, e.g.,
Linear path 245 intersecting rotational axis 238 of body 202 facilitates application of glutinous substance 168 to all portions of end surface 235 of head 232 of fastener 230, including a portion of end surface 234 proximate central axis 239 of fastener 230.
Referring generally to, e.g.,
Each of first plurality of tufts 223, being oblique to rotational axis 238 of body 202, promotes coverage of glutinous substance 168 on end surface 235 of head 232 of fastener 230. For example, each of first plurality of tufts 223, being oblique to rotational axis 238 of body 202, may facilitate application of glutinous substance 168 on unique or hard-to-reach features on end surface 235 of head 232 of fastener 230.
Referring generally to, e.g.,
Each of first plurality of tufts 223, being parallel to rotational axis 238 of body 202, promotes coverage of glutinous substance 168 on end surface 235 of head 232 of fastener 230.
Referring generally to, e.g.,
End face 247 of at least one of tips 227 of first plurality of tufts 223, being oblique to rotational axis 238 of body 202, promotes application of glutinous substance 168 to portions of end surface 235 of head 232 of fastener 230 that are oblique to rotational axis 238.
Referring generally to, e.g.,
End faces 247 of at least two of tips 227 of first plurality of tufts 223, being oblique to each other, promote application of glutinous substance 168 to portions of end surface 235 of head 232 of fastener 230 that are oblique to each other. For example, one of end faces 247 of at least two of tips 227 of first plurality of tufts 223 that are oblique to each other may apply glutinous substance 168 to a first side of a recess formed in end surface 235 and another of at least two of tips 227 of first plurality of tufts 223 that are oblique to each other may apply glutinous substance 168 to a second side of the recess, opposite the first side.
Referring generally to, e.g.,
At least two of first plurality of tufts 223 having different lengths promotes application of glutinous substance 168 to portions of end surface 235 of head 232 of fastener 230 at different elevations relative to each other. For example, at least two of first plurality of tufts 223 having different lengths promotes application of glutinous substance 168 to a recess formed in end surface 235 of head 232 of fastener 230.
Referring generally to, e.g.,
Angular orientations of at least some of tufts 222 relative to a virtual plane perpendicular to rotational axis 238 of body 202, being different, promotes application of glutinous substance 168 to different portions of surface 237 of workpiece 170 and/or lateral surface 233 of head 232 of fastener 230. Application of glutinous substance 168 to different portions of surface 237 of workpiece 170 and/or lateral surface 233 of head 232 of fastener 230 facilitates broader coverage of glutinous substance 168 on workpiece 170.
Referring generally to, e.g.,
Angular orientations of at least some of tufts 222 relative to a virtual plane perpendicular to rotational axis 238 of body 202, being identical, promotes uniform application of glutinous substance 168 to workpiece 170.
Referring generally to, e.g.,
At least some of tufts 223 having different lengths promotes application of glutinous substance 168 to portions of workpiece 170 at different elevations relative to each other. Additionally, at least some of tufts 223 having different lengths allows tufts 223 to be oblique relative to each other, but still uniformly apply glutinous substance 168 co-planar portions of workpiece 170.
Referring generally to, e.g.,
Second outlet 282 of second channel 211 of body 202, being offset from rotational axis 238, helps distribute glutinous substance 168 to locations offset from rotational axis 238. Second tube 212 facilitates flow of glutinous substance 168 from second outlet 282 of second channel 211 of body 202 to workpiece 170. Inlet 209 forming part of both first channel 208 and second channel 211 simplifies distribution of glutinous substance 168 from end-effector 102 to multiple outlets of body 202 offset from rotational axis 238 of body 202, and further facilitates flow of glutinous substance 168 through first channel 208 and second channel 211 as brush 200 rotates about rotational axis 238.
Referring generally to, e.g.,
Second tube 212, being more flexible than body 202, absorbs potential impacts with workpiece 170, while brush 200 delivers glutinous substance 168 to workpiece 170, more effectively than body 202. For example, second tube 212 can be configured to flex upon an impact with workpiece 170 while brush 200 delivers glutinous substance 168 to workpiece 170.
Referring generally to, e.g.,
Second channel 211, being cross-sectionally circumferentially closed, facilitates discrete containment of the flow of glutinous substance 168 through body 202.
Referring generally to
Second tube 212, extending from body 202 a shorter distance than at least one of tufts 222 along rotational axis 238 of body 202, helps to promote spreading and uniform distribution of glutinous substance 168 delivered from second tube 212 to workpiece 170 by at least one of tufts 222.
Referring generally to
Second tube 212, being parallel to rotational axis 238 of body 202, facilitates flow of glutinous substance 168 onto workpiece 170 in a direction parallel to rotational axis 238 of body 202.
Referring generally to
Third outlet 284 of third channel 213 of body 202, being offset from rotational axis 238, helps distribute glutinous substance 168 to locations offset from rotational axis 238. Third tube 214 facilitates flow of glutinous substance 168 from third outlet 284 of third channel 213 of body 202 to workpiece 170. Inlet 209 forming part of first channel 208, second channel 211, and third channel 213 simplifies distribution of glutinous substance 168 from end-effector 102 to multiple outlets of body 202 offset from rotational axis 238 of body 202, and further facilitates flow of glutinous substance 168 through first channel 208, second channel 211, and third channel 213 as brush 200 rotates about rotational axis 238.
Referring generally to
Third tube 214, being more flexible than body 202, absorbs potential impacts with workpiece 170, while brush 200 delivers glutinous substance 168 to workpiece 170, more effectively than body 202. For example, third tube 214 can be configured to flex upon an impact with workpiece 170 while brush 200 delivers glutinous substance 168 to workpiece 170.
Referring generally to
Third channel 213, being cross-sectionally circumferentially closed, facilitates discrete containment of the flow of glutinous substance 168 through body 202.
Referring generally to
Third tube 214, extending from body 202 a shorter distance than at least one of tufts 222 along rotational axis 238 of body 202, helps to promote spreading and uniform distribution of glutinous substance 168 delivered from third tube 214 to workpiece 170 by at least one of tufts 222.
Referring generally to
Third tube 214, being parallel to rotational axis 238 of body 202, facilitates flow of glutinous substance 168 onto workpiece 170 in a direction parallel to rotational axis 238 of body 202.
Referring generally to
First tube 210 extending from body 202 a longer distance than second tube 212, and second tube 212 extending from body 202 a longer distance than third tube 214, promotes the delivery of glutinous substance 168 to workpiece 170 at different elevations relative to workpiece 170. In some examples, first tube 210 extends from body 202 a longer distance than second tube 212, and second tube 212 extends from body 202 a longer distance than third tube 214, to accommodate the delivery of glutinous substance 168 to different features of workpiece 170, some at different elevations relative to each other. For example, first tube 210 may be distanced along rotational axis 238 to deliver glutinous substance 168 to surface 237 of workpiece 170, second tube 212 may be distanced along rotational axis 238 to deliver glutinous substance 168 to lateral surface 233 and a portion of end surface 235 of head 232 of fastener 230, and third tube 214 may be distanced along rotational axis 238 to deliver glutinous substance 168 to a portion of end surface 235 of head 232 of fastener 230.
Referring generally to
First tube 210 is located on body 202 a greater distance away from rotational axis 238 than second tube 212, and second tube 212 is located on body 202 a greater distance away from rotational axis 238 than third tube 214, facilitates the delivery of glutinous substance 168 to workpiece 170 at different locations on workpiece 170. For example, first tube 210 may be spaced fourth distance D4 away from rotational axis 238 to deliver glutinous substance 168 to surface 237 of workpiece 170, second tube 212 may be spaced fifth distance D5 away from rotational axis 238 to deliver glutinous substance 168 to lateral surface 233 and a portion of end surface 235 of head 232 of fastener 230, and third tube 214 may be spaced distance D6 away from rotational axis 238 to deliver glutinous substance 168 to a portion of end surface 235 of head 232 of fastener 230.
Referring generally to
Fourth outlet 271 of first tube 210, being perpendicular to first central axis 270 of first tube 210, promotes flow of glutinous substance 168 from fourth outlet 271 of first tube 210 in direction parallel to first central axis 270 of first tube 210.
Referring generally to
Fifth outlet 273 of second tube 212, being oblique to second central axis 272 of second tube 212, promotes flow of glutinous substance 168 from fifth outlet 273 of second tube 212 in direction oblique to second central axis 272 of second tube 212. According to one example, fifth outlet 273 of second tube 212, being oblique to second central axis 272 of second tube 212, facilitates flow of glutinous substance 168 from fifth outlet 273 of second tube 212 towards a corner of head 232 of fastener 230 that separates lateral surface 233 from end surface 235 of head 232.
Referring generally to
Sixth outlet 275 of third tube 214, being perpendicular to third central axis 274 of third tube 214, promotes flow of glutinous substance 168 from sixth outlet 275 of third tube 214 in direction parallel to third central axis 274 of third tube 214.
Referring generally to, e.g.,
Method 300 facilitates delivery of glutinous substance 168 to workpiece 170 from end-effector 102 using brush 200 that is configured to facilitate ease and efficiency of the delivery of glutinous substance 168 onto surfaces of workpieces. Inlet 209, being coaxial with rotational axis 238 of body 202, allows flow of glutinous substance 168 through first channel 208 as brush 200 rotates about rotational axis 238. First outlet 280 of first channel 208 of body 202, being offset from rotational axis 238, helps distribute glutinous substance 168 to locations offset from rotational axis 238. First tube 210 facilitates flow of glutinous substance 168 from first outlet 280 of first channel 208 of body 202 to workpiece 170. Tufts 222 promote the spreading and uniform distribution of glutinous substance 168 on workpiece 170.
Referring generally to
Second plurality of tufts 224, extending from body 202 at locations on body 202 that lie along curvilinear path 251, promote application of glutinous substance 168 onto surface 237 of workpiece 170 around head 232 of fastener 230 and onto at least lateral surface 233 of head 232 of fastener 230. Laying first plurality of tufts 223 at locations on body 202 along linear path 245 facilitates application of glutinous substance 168 onto end surface 235 of fastener 230.
Referring generally to
Positioning first tube 210 of brush 200 such that lateral surface 233 of head 232 of fastener 230 is located between central axis 239 and first tube 210 facilitates the delivery of glutinous substance 168 to surface 237 of workpiece 170 around head 232 of fastener 230.
Referring generally to
Fourth outlet 271 of first tube 210, facing surface 237 of workpiece 170, promotes flow of glutinous substance 168 from fourth outlet 271 of first tube 210 onto surface 237 of workpiece 170 in direction perpendicular to surface 237 of workpiece 170.
Referring generally to
Fourth outlet 271 of first tube 210, being located, along rotational axis 238, between surface 237 of workpiece 170 and end surface 235 of head 232 of fastener 230 helps to promote delivery of glutinous substance 168 from fourth outlet 270 of first tube 210 to surface 237 of workpiece 170.
Referring generally to
Second outlet 282 of second channel 211 of body 202, being offset from rotational axis 238, helps distribute glutinous substance 168 to locations offset from rotational axis 238. Second tube 212 facilitates flow of glutinous substance 168 from second outlet 282 of second channel 211 of body 202 to workpiece 170. Inlet 209 forming part of both first channel 208 and second channel 211 simplifies distribution of glutinous substance 168 from end-effector 102 to multiple outlets of body 202 offset from rotational axis 238 of body 202, and further facilitates flow of glutinous substance 168 through first channel 208 and second channel 211 as brush 200 rotates about rotational axis 238. Aligning second tube 212 with lateral surface 233 of head 232 of fastener 230 in direction along rotational axis 238 promotes delivery of glutinous substance 168 onto both lateral surface 233 and end surface 235 of head 232 of fastener 230.
Referring generally to
Fifth outlet 273 of second tube 212, facing intersection of lateral surface 233 of head 232 of fastener 230 and end surface 235 of head 232 of fastener 230, facilitates delivery of glutinous substance 168 towards intersection of lateral surface 233 of head 232 of fastener 230 and end surface 235 of head 232 of fastener 230. In one example, delivering glutinous substance 168 towards intersection of lateral surface 233 of head 232 of fastener 230 and end surface 235 of head 232 of fastener 230 results in glutinous substance 168 being applied onto both lateral surface 233 and end surface 235 of head 232 of fastener 230.
Referring generally to
Positioning second tube 212 such that a plane co-planar with end surface 235 of head 232 of fastener 230 intersects fifth outlet 273 of second tube 212 promotes delivery of glutinous substance 168 onto both lateral surface 233 and end surface 235 of head 232 of fastener 230.
Referring generally to
Fifth outlet 273 of second tube 212, being oblique relative to surface 237 of workpiece 170, lateral surface 233 of head 232 of fastener 230, and end surface 235 of head 232 of fastener 230, provides for delivery of glutinous substance 168 onto both lateral surface 233 and end surface 235 of head 232 of fastener 230.
Referring generally to
Third outlet 284 of third channel 213 of body 202, being offset from rotational axis 238, helps distribute glutinous substance 168 to locations offset from rotational axis 238. Third tube 214 facilitates flow of glutinous substance 168 from third outlet 284 of third channel 213 of body 202 to workpiece 170. Inlet 209 forming part of first channel 208, second channel 211, and third channel 213 simplifies distribution of glutinous substance 168 from end-effector 102 to multiple outlets of body 202 offset from rotational axis 238 of body 202, and further facilitates flow of glutinous substance 168 through first channel 208, second channel 211, and third channel 213 as brush 200 rotates about rotational axis 238. Third tube 214 of brush 200, being positioned between central axis 239 of fastener 230 and lateral surface 233 of head 232 of fastener 230, facilitates the delivery of glutinous substance 168 to end surface 235 of head 232 of fastener 230.
Referring generally to
Sixth outlet 275 of third tube 214, facing end surface 235 of head 232 of fastener 230, promotes flow of glutinous substance 168 from sixth outlet 275 of third tube 214 onto end surface 235 of head 232 of fastener 230 in direction perpendicular to end surface 235 of head 232 of fastener 230.
Referring generally to
Sixth outlet 275 of third tube 214, being parallel with end surface 235 of head 232 of fastener 230, promotes flow of glutinous substance 168 from sixth outlet 275 of third tube 214 onto end surface 235 of head 232 of fastener 230 in direction perpendicular to end surface 235 of head 232 of fastener 230.
Examples of the present disclosure may be described in the context of aircraft manufacturing and service method 1100 as shown in
Each of the processes of illustrative method 1100 may be performed or carried out by a system integrator, a third party, and/or an operator (e.g., a customer). For the purposes of this description, a system integrator may include, without limitation, any number of aircraft manufacturers and major-system subcontractors; a third party may include, without limitation, any number of vendors, subcontractors, and suppliers; and an operator may be an airline, leasing company, military entity, service organization, and so on.
As shown in
Apparatus(es) and method(s) shown or described herein may be employed during any one or more of the stages of the manufacturing and service method 1100. For example, components or subassemblies corresponding to component and subassembly manufacturing (block 1108) may be fabricated or manufactured in a manner similar to components or subassemblies produced while aircraft 1102 is in service (block 1114). Also, one or more examples of the apparatus(es), method(s), or combination thereof may be utilized during production stages 1108 and 1110, for example, by substantially expediting assembly of or reducing the cost of aircraft 1102. Similarly, one or more examples of the apparatus or method realizations, or a combination thereof, may be utilized, for example and without limitation, while aircraft 1102 is in service (block 1114) and/or during maintenance and service (block 1116).
Different examples of the apparatus(es) and method(s) disclosed herein include a variety of components, features, and functionalities. It should be understood that the various examples of the apparatus(es) and method(s) disclosed herein may include any of the components, features, and functionalities of any of the other examples of the apparatus(es) and method(s) disclosed herein in any combination, and all of such possibilities are intended to be within the scope of the present disclosure.
Many modifications of examples set forth herein will come to mind to one skilled in the art to which the present disclosure pertains having the benefit of the teachings presented in the foregoing descriptions and the associated drawings.
Therefore, it is to be understood that the present disclosure is not to be limited to the specific examples illustrated and that modifications and other examples are intended to be included within the scope of the appended claims. Moreover, although the foregoing description and the associated drawings describe examples of the present disclosure in the context of certain illustrative combinations of elements and/or functions, it should be appreciated that different combinations of elements and/or functions may be provided by alternative implementations without departing from the scope of the appended claims. Accordingly, parenthetical reference numerals in the appended claims are presented for illustrative purposes only and are not intended to limit the scope of the claimed subject matter to the specific examples provided in the present disclosure.
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