The present disclosure relates generally to determining part wear, and, more particularly, to methods and systems for determining part wear using sensor data of a used or worn part and models associated with the part.
To facilitate earth working activities (e.g., mining, construction, dredging, or the like), machines are outfitted with ground-engaging tools. For instance, tools including but not limited to teeth, shrouds, and/or lips may be commonly provided to protect underlying equipment from undue wear and/or to perform other functions. By way of non-limiting example, an excavating bucket may be provided with excavating teeth and/or shrouds attached to a lip of the bucket to initiate contact with the ground, e.g., prior to the lip of the bucket. During use, such ground-engaging products can encounter heavy loading and/or highly abrasive conditions. These conditions cause the ground-engaging products to become worn and, eventually, to wear out or fail. Excessive wear can result in breakage and/or loss of the ground-engaging tools, which can result in decreased productivity, increased costs in repair and/or maintenance, and other problems. Accordingly, it may be desirable to monitor part wear, e.g., to understand and/or quantify wear part including to replace parts prior to failure.
Systems have been designed with a view toward attempting to determine wear associated with a part. For example, U.S. Pat. No. 9,613,413 to Hasselbusch et al. (“the '413 patent”) describes systems and methods for determining part wear using a mobile device. For instance, the '413 patent describes capturing digital images using a camera on the mobile device and determining distances, e.g., based on a number of pixels, of wear surfaces of the imaged part from a surface of a simulated surface of an unworn part and/or a spent/worn part. In examples of the '413 patent, the degree of wear may be determined based on these distances.
While the system described in the '413 patent may quantify wear, the distances calculated according to the techniques described therein may not accurately reflect wear patterns. For instance, wear can occur irregularly at different surfaces, and the techniques of the '413 patent may not account properly for such wear. By way of non-limiting example, the techniques described in the '413 patent may measure distances other than in the direction of wear, thereby returning an inaccurate wear percentage.
The present disclosure is directed to one or more improvements in the existing technology.
One aspect of the disclosure is directed to a computer-implemented method that includes receiving sensor data corresponding to a surface of a part. The sensor data includes information about a plurality of points on the surface. The method may also include receiving a first model associated with an unworn part corresponding to the part and receiving a second model associated with a wear limit part corresponding to the part. The first model may define a first contour of the unworn part and the second model may define a second contour of the wear limit part. The method may also include generating a bounding contour spaced from the surface, the first contour, and the second contour and determining, for a point of the plurality of points, at least one of a first distance between the point and a first position on the first contour; or a second distance between the point and a second position on the second contour. The method may also include determining, based on the at least one of the first distance or the second distance, a wear metric associated with the part, wherein the first distance and the second distance are along a line extending from the bounding contour and through the point.
Another aspect of the disclosure is directed to a system including one or more processors; and computer-readable media storing instructions that, when executed, cause the one or more processors to performs acts. The acts may include receiving information about a surface of a part and generating, based at least in part on the information, a first model of the part. The acts may also include comparing the first model to a second model including information about a surface of an unworn part corresponding to the part, a third model including information about a surface of a wear limit part corresponding to the part, and a fourth model associated with a bounding surface at least partially enveloping the first model, the second model, and the third model. The acts may also include determining, based on the comparing, a wear metric associated with the part.
Another aspect of this disclosure is directed to non-transitory computer-readable media storing instructions that, when executed, cause one or more processors to perform operations. The operations may include receiving information about an outer surface of a wear part. The information includes a plurality of points in a three-dimensional coordinate system. The operations may also include receiving a first model associated with a first three-dimensional representation of a surface of an unworn part corresponding to the wear part; receiving a second model associated with a second three-dimensional representation of a surface of a wear limit part corresponding to the wear part, the surface of the wear limit part corresponding to a wear limit associated with the part; and receiving a third model associated with a bounding contour at least partially enveloping the surface of the unworn part. The operations may also include determining, for individual points of the plurality of points, at least one of a first distance between a first position on the bounding contour and the individual point, a second distance between the first position on the bounding contour and a second position on the surface of the unworn part, or a third distance between the first position on the bounding contour and a third position on the surface of the wear limit part. The second distance and the third distance are measured along a direction extending from the first point on the bounding contour and through the individual point. The operations may also include determining, based at least in part on at least one of the first distance, the second distance, or the third distance, a wear metric for the part.
This disclosure generally relates to methods, systems, and techniques for determining wear of parts. While specific parts described herein may be parts on machines, e.g., ground-engaging machines, earth-moving machines, or the like, the techniques described herein may be applicable to any number of parts that wear over time, e.g., from abrasion, corrosion, or the like. Where possible, the same reference numerals are used through the drawings to refer to the same or like features.
The machine 104 may be one of any of a variety of machines, but generally includes a machine having one or more parts that are susceptible to wear, e.g., resulting from forces acting on such parts during operation of the machine 104, and must be replaced over time as a result of such wear. The machine 104 is illustrated as a bucket loader which may have teeth secured proximate a lip of the bucket. For instance, an enlarged view 112 accompanying the depiction of the machine 104 shows a new part 114, which is a tooth, and a worn part 116, which corresponds to the new part 114 after some amount of work performed by the machine 104 (and the new part 114). Stated differently, the worn part 116 may depict an in-use part to be imaged using the senor 110, whereas the new part 114 may depict an “as manufactured” or nominal part. Although
The user 106 may be any person or entity associated with the machine 104. By way of nonlimiting example, the user 106 may be an owner, an operator, a technician, a repair person, a customer service representative, dealer personnel, or any other person concerned with the machine 104. As noted above, and explained in more detail herein, the user 106 may operate the sensor 110 to capture sensor data of wear parts, such as the worn part 116. In examples, the sensor 110 may be a three-dimensional camera or a range finding sensor, including but not limited to a radar sensor, a LiDAR sensor, or the like. By way of non-limiting example, the sensor 110 can be a time-of-flight sensor configured to generate depths associated with each captured pixel. In examples, the sensor 110 can be mounted, e.g., in association with an image capture station and the worn part 116 may be placed relative to the sensor 110 for sensing and/or image capture. In other implementations, the sensor 110 can be operable by the user 106 to capture sensor and/or image data about the worn part 116 e.g., with the worn part mounted on the machine 104. By way of non-limiting example, the sensor 110 may be a hand-held or otherwise moveable imager or sensor and the user 106 may situate the sensor 110, e.g., at the machine site 102, to capture images of the worn part 116.
The user device 108 may be a mobile device carried by or otherwise accessible to the user 106 at the machine site 102. In implementations, the user device 108 may be embodied as a smartphone, a mobile phone, a tablet computer, a personal digital assistant, a network-enabled camera or sensor, or other computing device. Moreover, and as described herein, the user device 108 may include functionality to determine a degree of wear of the worn part 116, e.g., relative to the new part 114. By way of nonlimiting example, the user device 108 can receive sensor data, e.g., point cloud data, generated by the sensor 110. In some examples, functionality of the sensor 110 and the user device 108 may be integrated into a single device, e.g., the user device 108 may have an integrated sensor 110. In other examples, the user device 108 may receive sensor data from the sensor 110, e.g., via a physical connection, a wireless connection, and/or a network 118.
As also illustrated in
The data processing system(s) 120 are generally configured to receive sensor data generated by the sensor 110 of the worn part 116 and determine a wear metric associated therewith. As used herein, “wear metric” may refer to any quantification of wear of a part. For instance, a wear metric may be a percentage wear, e.g., relative to a new part, such as the new part 114, and/or relative to a spent or “worn-out” part, which may correspond to the maximum wear allowable before expected failure or some other wear limit. The wear metric may also or alternatively be measured as a distance, e.g., corresponding to a distance associated with the wear, as detailed further herein. As illustrated in
In examples, the wear determination component 124 can receive sensor data, e.g., captured by the sensor 110, and compare the sensor data to the part model(s) 126. For example, the wear determination component may receive point cloud data including a number of points associated with depths captured by the sensor 110, e.g., when the sensor is a ranging-type sensor. The wear determination component 124 can determine positions in a coordinate system corresponding to the depths. By way of non-limiting example, the wear determination component 124 can determine positions associated with measured depths in a three-dimensional (e.g., x, y, z) coordinate system. For example, the measured depths may be associated with a surface of the worn part 114 and in some implementations, the wear determination component 124 can generate a three-dimensional model of the measured worn part 114 and orient the model in the coordinate system.
The wear determination component 124 may also be configured to align the sensor data with the part model(s) 126. In examples described herein, the part model(s) 126 may include one or more of a new part model, e.g., a model of the new part 114 and/or a wear limit part model. As detailed further herein, the new part model may include coordinates of a surface of a substantially new part and/or of a nominal part associated with the new part 114. The wear limit part model may include coordinates of a surface, e.g., of points on the surface, associated with a maximally worn part. For instance, the wear limit part model may describe an outer contour associated with a part that is at the brink of failure or otherwise expected to fail imminently. In other examples, the part model(s) 126 may include one or more additional models associated with other stages of wear of a wear part. By way of nonlimiting example, a part model may describe surfaces corresponding to other degrees of wear, including, but not limited to, configurations associated with a wear part that has 10% remaining life (that is 90% worn), or the like. In examples described herein, when measured points on the worn part 116 correspond to points on the wear limit model, the worn part 116 may be in need of replacement. As detailed further herein, selecting a wear limit part model may dictate when a part will be replaced, and thus selection of the wear limit part model may be based at least in part on a desired condition that will suggest replacement.
The wear determination component 124 may compare the sensor data, e.g., position of measured points on the surface of the measured worn part 116 to the part model(s) 126. In implementations, the data processing system(s) 120 may align the sensor data representing the measured worn part 116, e.g., the points generated by the sensor 110, with one or more of the part model(s) 126 to determine distances between the measured points and positions or locations on the part model(s) 126. In one example, the wear metric may be a percentage corresponding to a ratio of a first distance between a position on a new part model and a measured position (e.g., on the worn part 116) and a co-linear second distance between the position on the new part model and a position on the spent part model.
The bounding surface determination component 128 may generate, receive, or otherwise access a bounding surface or bounding contour according to implementations of this disclosure. As detailed further herein, the bounding surface or contour may be a model, like the part model(s) 126 used by the wear determination component 124 to determine a wear metric. In examples, the bounding surface determination component 128 can generate or select a bounding surface, model or contour that at least partially envelopes, e.g., that is bigger than, the part model(s) 126 and/or the measured worn part 116. As described herein, the bounding surface determined by the bounding surface determination component 128 may define orientations along which distances are measured to determine wear. By way of nonlimiting example, a bounding contour may serve as an additional model that may be aligned by the wear determination component 124 with the part model(s) 126 and the measured points of the worn part 116 (or a model of the worn part 116 based on the measured points). In some instances, lines normal to the bounding surface may serve as directions along which distances, e.g. distances between a measured point and one or more points on the part model(s) 126, may be measured. Thus, the bounding surface may function to orient directions of measurement. According to implementations described herein, orienting the directions in this manner may provide more accurate results compared to conventional models. For instance, some conventional models may measure a distance between a measured point and a closest point on a part model. However, such processes may result in an inaccurate calculation of wear, which may result in overuse of parts e.g., causing disruptive failures, and/or underuse of parts, thereby increasing cost.
Depending upon the configuration of the environment 100, the data processing system(s) 120 may have different roles or different degrees of involvement in carrying out the disclosed techniques. For instance, aspects of the environment 100 may be configured as a server-based environment or a cloud-based environment that perform the disclosed wear determination techniques as part of the service over the network(s) 118. In such a server- or cloud-based environment, the data processing system(s) 120 (e.g., the server or cloud), may receive sensor data from the sensor 110 and/or from the user device 108 (which may receive the sensor data from the sensor 110). In this example, the data processing system(s) 120 may then process the sensor data to determine the degree of wear of parts, and return results of the processing to the user device 108 over the network(s) 118. Thus, in a server- or cloud-based environment, the data processing system(s) 120 may perform the bulk of the computing operations, while the user device 108 may function as a portal (e.g., via an application or browser) that allows the user 106 to access the services of the data processing system(s) 120 over the network(s) 118. In some examples, the user device 108 may access, e.g., download, a software application that allows the user 106 to access the data processing system(s) 120 and/or two interact with data received from the data processing system(s) 120, as detailed further herein.
The environment 100 also includes the dealer computing device(s) 122, which may represent one or more computing systems associated with a dealer that sells or rents the machine 104 and/or parts for the machine 104, including the new part 114. In some implementations, the dealer may have a relationship with the user 106. For instance, the user 106 may be a customer or potential customer and/or some other individual having an interest in knowing a status of the machine 104. In some implementations, the dealer may desire to know when a wear part of the machine 104, such as the illustrated tooth, has become sufficiently worn so that it can inspect or service the machine 104 and/or provide replacement parts or services relative to the machine 104. As with other elements of the environment 100, the dealer computing device(s) 122 may include any number or combination of computing elements enabling communication, storage, and processing to carry out the disclosed techniques. Among other things, the dealer computing device(s) 122 may include a fulfillment component 130, which may be configured to automatically order a replacement part, e.g., the new part 114, and/or scheduled maintenance associated with the machine 104 in response to the data processing system(s) 120 determining that a wear part is worn to somewhere threshold. In at least some examples, the dealer computing device(s) 122 may also incorporate the data processing system(s) 120. For instance, the dealer computing device(s) 122 may be a centralized monitoring and/or service provider capable of determining that parts are worn as well as taking actions, including providing replacement parts, in response to such wear determination. In at least some examples, the dealer computing device(s) 122 may receive notifications, such as emails or text messages, from other elements of the environment, e.g., the data processing system(s) 120 and/or the user device 108, indicating that a wear part of machine is sufficiently worn, e.g. that the wear metric meets or exceeds a threshold wear metric. In response to such notifications, the dealer computing device(s) 122 may, e.g., using the fulfillment component 130, determine an adequate or appropriate replacement part and arrange for presentation of the replacement part to the user 106 at the machine site 102. In other instances, the dealer computing device(s) 122 may provide other instructions to the user device 108, e.g. instructing a user with one or more actions to take in response to the determined wear metric. Such instructions may be for the user 106 to bring the machine 104 in for inspection, service, or the like and/or to arrange for a technician, who may be associated with the dealer, to visit the machine location 102. The dealer computing device(s) 122 may also prompt the user, e.g., via a message or other transmission to the user device 108, to order a replacement part.
In
At operation 202, the process 200 can include receiving sensor data for a wear part. For example, in the example environment 100 described above in connection with
At operation 210, the process 200 can include receiving one or more part models. For instance, the part models can include a new part model and a worn or wear limit part model. The new part model may be associated with a new or unused part, such as the new part 114. The worn or wear limit part model may correspond to a minimum acceptable surface associated with the worn part 114. An example 212 accompanying the operation 210 illustrates a new part model 214 and a wear limit part model 216. As with the depiction in the example 204, the new part model 214 and the wear limit part model 216 are illustrated as two-dimensional models, for clarity. As will be appreciated, however, the new part model 214 and the wear limit part model 216 can be three-dimensional models in implementations of this disclosure. Each of the new part model 214 and the wear limit part model 216 generally describes surfaces or contours of surfaces associated with the same part, but at different times in the parts useful life. For instance, the new part model 214 generally corresponds to a brand-new or nominal part. For examples, the surfaces associated with or defined by the new part model may be derived from technical specification and/or renderings of the part. In contrast, the wear limit part model 216 generally describes contours of a corresponding worn part. In implementations, the wear limit part model 216 may describe a spent or completely worn part, e.g., descriptive of a part contour or surface that may be expected to fail imminently. In other implementations, the wear limit part model 216 may correspond to some other contour at some other degree of wear of the original part. By way of nonlimiting example, the wear limit part model 216 may be configured by the user 106 or some other individual associated with the machine 104 to designate aspects of a contour that correspond to the end of a useful life of the part. In a simplistic example, the new part model 214 may correspond to an off-the-shelf part whereas the wear limit part model 216 may correspond to a part that is expected to fail imminently and thus should be replaced immediately. In some examples, the new part model 214 may correspond to manufacturing specifications or a nominal description of a new part, such as the new part 114. In contrast, the wear limit part model 216 may correspond to a contour at which each point on a ground engaging, e.g., outside, surface should be subject to no further wear.
At an operation 218, the process 200 may include generating a bounding model. Aspects of this disclosure may use a bounding model to determine orientations and/or directions along which wear can be measured, as detailed further herein. An example 220 accompanying the operation 218 schematically illustrates a number of representative bounding models. More specifically, the example 220 includes representation of a first bounding model 222a, second bounding model 220b, and a third bounding model 222c. Collectively, the first bounding model 222a, the second bounding model 222b, and the third bounding model 222c are referred to herein as the bounding models 222. Generally, the bounding models 222 represent surfaces that at least partially envelop the part models, e.g., the new part model 214 and the wear limit part model 216, as well as the measured surface 206 of the worn part 116. In implementations, the bounding surfaces 222 may depend upon the type of part being measured, expected wear patterns associated with the measured part, and/or other factors.
At an operation 224, the process 200 can include determining wear by comparing part data to the part models using the bounding model. An example 226 accompanying the operation 224 demonstrates techniques for determining a wear metric using the sensed data, the part model(s), and the bounding models. As conceptualized in the example 226, the operation 224 may include aligning the new part model 214, the wear limit part model 216, the surface 206 of the worn part 116, and the bounding model 222. For example, such alignment may be performed using a common feature of the models, such as a mounting hole, a mounting surface, or the like. In the example 226, the first bounding model 222a is used, and the example 226 specifically demonstrates determining a wear metric associated with the third measured point 208c on the surface 206. As described above, the third measured point 208c has a known depth, e.g. as measured by the sensor 110, and the depth associated with the third measured point 208c can be located in a coordinate system. Positions, including a position 228 along the new part model 214, positions, including a position 230 on the wear limit part model 216, and positions, including a position 232 on the bounding model 222a can also be determined in the coordinate system. In the example 226, a line 234 extends from the position 232 on the bounding model 222a to the position 230 on the wear limit part model. In this example, the line 234 is perpendicular or normal to the bounding model 222a at the position 232.
In some examples, a wear metric associated with the third measured point 208c may be based at least in part on distances between the third measured point 208c and one or both of the position 228 on the new part model 214 and/or the position 230 on the wear limit part model 216. For instance, the example 226 illustrates a first distance d1 as a distance between the position 228 on the new part model 214 and the measured point 208c and a second distance d2 as a distance between the measured point 208c and the position 230 on the wear limit part model 216. In implementations, a wear metric associated with the third measured point 208c may be a ratio of the first distance d1 to the combined distance of d1 plus d2. This ratio may correspond to a percentage of wear for the part, e.g., because it is the ratio of worn material (at the third measured point 208c) to the total material, relative to the wear limit. As will be appreciated, because the sum of d1 and d2 is constant, e.g., because the new part model 214 and the wear limit part model 216 are fixed, predetermined models, when d1 is relatively smaller, the wear percentage will be relatively smaller, e.g., less of the part will be worn, whereas when d1 is relatively larger, the wear percentage will be relatively greater, e.g., more of the part will be worn. Other wear metrics also are contemplated. For example, in other implementations, the ratio of d2 to the sum of d1 and d2 may be representative of a percentage of the part (at the measured point 208c) that remains of the part. In still further implementations, the wear metric may be some other quantification associated with (or determined from) the distances d1, d2. For example, the amount of remaining (or worn) part may be associated with a time associated with continued use of the part. For instance, the wear part may have a useful part life measured in hours and the percentage of remaining part life (e.g., the ratio of d2 to d1 plus d2) can be expressed as a remaining number of hours of expected use for the part 116. While examples described herein may contemplate a ratio as a technique for determining a wear metric, other techniques also are contemplated. For instance, empirical data relative to the use of certain wear parts may inform a wear characteristic or other wear pattern and one or both of the distances d1, d2, may be used to look up a wear percentage or other wear metric based on such empirically developed information. Although some example implementations of
In the example 226, the orientation of the line 234 is based on characteristics of the bounding model 222a. For instance, in some examples, the line 234 is normal to the bounding model 222a at the point 232. In arrangements, the bounding model may be selected based on an expected wear pattern for the part. By way of non-limiting example, the bounding model 222 may be chosen to orient lines, like the line 234, in a manner best indicative of wear for the part, as described further herein.
As further illustrated in
As also described herein, correspondence of the points is determined based at least in part on the bounding model 308. More specifically, the bounding model 308 may inform the orientation of the lines that pass through the measured points 310, which in turn determine the wear limit points 312 and the new points 314 to be considered when determining the wear metric. In the example, a first bounding point 316a, a second bounding point 316b, a third bounding point 316c, and a fourth bounding point 316d (collectively, the bounding points 316) are illustrated on the bounding model 308. A first line 318a extends from the first bounding point 316a through the first measured point 310a, a second line 318b extends from the second bounding point 316b through the second measured point 310b, a third line 318c extends from the third bounding point 316c through the third measured point 310c, and a fourth line 318d extends from the fourth bounding point 318d through the fourth measured point 310d. Collectively, the first line 318a, the second line 318b, the third line 318c, and the fourth line 318d may be referred to as the lines 318. In the illustrated example, each of the lines 318 extends normal to the bounding surface defined by the bounding model 308. In some examples, techniques described herein can determine locations (e.g., locations of points) along the lines 318 and match those locations to measured points 310 to determine a correspondence of measured points 310 to bounding points 316. The wear limit points 312 and the new points 314 may similarly be determined by identifying points on the wear limit model 306 and the new part model 304, respectively, that lie on the lines 318. Although in this example, each of the lines 318 is normal or perpendicular to the bounding model 308, the lines 318 may be otherwise oriented in other implementations. By way of non-limiting example, the lines 318 may be angled at some degree relative to the bounding surface defined by the bounding model 308 other than 90-degrees.
As noted herein, the bounding model 308 may provide an orientation for each of the lines 318 to better estimate part wear. For instance, some techniques may use models like the new part model 304 and/or the wear limit model 306 to determine a wear metric, but such models may calculate the worn distance (e.g., the distance of one of the measured points 302 to the new part model 304) as the distance between the respective one of the measured points 310 and a closest point on the new part model 308. Consider, for example, the third measured point 310c. In the example of
Moreover, by identifying the shape and/or contour of the bounding model 308, different result may be achieved. In some examples, it may be desirable than any line normal to the bounding model will pass through each of the measured surface 302, the new model 304, and the wear limit model 306. To achieve such an arrangement, the bounding model 308 may have substantially the same shape as the wear limit model 306. Of course, and as discussed herein, other shapes, including hemi-spheres and/or other concave shapes are contemplated and can be used.
As described above in connection with
Moreover, although the wear metric table 320 represents wear as a wear percentage, the table 320 may include additional or alternate metrics. For instance, the inverse of the illustrated percentage may be included as a “remaining part percentage” or similar metric. In other examples, the wear metric table 320 can include metrics other than those expressed as percentages. By way of non-limiting example, the wear metric may be expressed as a thickness (e.g., in millimeters, centimeters, inches, or the like) of material removed (e.g., a length associated with the distance from individual of the measured points 310 to a corresponding one of the new points 314) or of material remaining (e.g., a length associated with the distance from individual of the measured points 310 to a corresponding one of the wear limit points 312). In some examples, metrics other than wear percentage may be particularly of interest and/or may be more intuitive for some machine operators and/or technicians. For instance, the wear metric table 320 shows a relatively wide range of wear percentages, e.g., 45% to 85%, whereas the thickness of the material at each of the measured points 310 (e.g., measured from the wear limit model 306) is relatively uniform. Stated differently, and using specific point on
Techniques described herein may include providing information about the wear determined according to implementations described in connection with
The interface 400 may further include a wear representation 404, which may be a visual depiction of the sensed part, e.g., corresponding to the sensor data generated by the sensor 110, along with information about wear determined by the data processing system(s) 120 according to techniques described herein. In the example, the wear representation 404 includes a color-coded heat map or similar representation generally showing the amount of wear. More specifically, the wear representation includes a number of points 406 that are color-coded to demonstrate wear. More specifically, points 406 associated with sections of the part that are more worn are represented as relatively darker points in the wear representation 404 whereas points 406 associated with sections of the part that are less worn are relatively lighter. Although the image is shown in black and white, other implementations may use other color coding schemes. By way of non-limiting example, the wear representation 404 may use shades of red to show points 406 associated with wear over 65%, shades of green to show points 406 having wear below 35% and shades of yellow to show points 406 associated with wear between 35% and 65%. Of course, these colors and values are for example only; other colors and/or values may be used. Moreover, the points 406 may be relatively smaller, e.g., pixel-sized, and/or may be replaced by some other graphical representation. In some examples, each of the points 406 may correspond to one or the measured points 208, 310 although such is not required. Generally, the wear representation 404 may provide an intuitive graphic that allows the user 106 to readily understand the health of the measured part.
The interface 400 can also include additional information to help the user 106 to understand the health of the measured part. As illustrated in
Also in examples, the interface 400 may further have interactive controls for taking or instructing actions relative to the measured part. For example, an “order replacement” user interface element 410 may be a selectable region displayed on the interface 400 that, when selected by the user 106, causes a replacement part to be ordered. For example, the user device 108 may generate and transmit a signal to the dealer computing device(s) 122 to order a replacement part from the dealer. In some examples, selection of the order replacement user interface element may open a new user interface (not shown) via which the user 106 can place an order, check inventory, and/or take some additional action. The interface 400 also is illustrated as including an “analyze new part” interface element 412. This element may be a selectable region displayed on the interface 400 that, when selected by the user 106, may render an interface similar to the interface 400, but pertaining to a different measured part. For example, when a machine like the machine 104 includes multiple teeth, the user 106 may be able to receive information about different of the teeth by selecting the element 412. By way of non-limiting example, selection of the element 412 may cause rendering of a pop-up menu or similar visual listing the wear parts that may be investigated by the user 106. Although not illustrated, the interface 400 can also promote or enable different actions by the user 106 relative to wear parts. For example, in instances in which the sensor 110 is integrated into or in communication with the user device 108, the interface 400 may facilitate the capture of sensor data using the sensor 110. Moreover, and as noted above, in some implementations functionality associated with the wear determination component 124 can be performed by the user device 108. In these examples, the interface 400 may include one or more interface elements that cause the user device 108 to execute instructions to determine wear metrics associated with a wear part.
The remote computing device(s) 502 can include processor(s) 510 and memory 512 communicatively coupled with the processor(s) 510. In the illustrated example, the memory 512 of the remote computing device(s) 502 stores a wear determination system 514, a graphical user interface (GUI) generation system 516, and a bounding model generation system 518. Although these systems are illustrated as, and will be described below as, separate components, functionality of the various systems may be attributed differently than discussed. Moreover, fewer or more systems and components may be utilized to perform the various functionalities described herein. The memory 512 may also include data stores 520, which may include models 522. Though depicted in
In at least one example, the wear determination system 514 can include functionality to determine a wear metric associated with a wear part, such as the worn part 116. For example, the wear determination system 514 may be substantially the same as the wear determination component 124 discussed above. In examples, the wear determination system 514 can received sensor data of a measured part, align the sensor data with one or more models 522 stored in the data stores 520. The models 522 can include a new part model and a worn part model. In example implementations, the worn part model can correspond to a wear limit for the part.
In some examples, the GUI generation system 516 can include functionality to generate one or more interactive interfaces, such as the GUI 400 for presentation on the user device 508. In some examples, the GUI generation system 516 may receive information from the wear determination system 514 and/or the models 522 to generate the GUIs. By way of nonlimiting example, and with reference to
The bounding model generation system 518 may include functionality to determine a bounding model, structure or contour that may be used as a reference to determine a wear metric, as described herein. In examples, the bounding model generation system may be the same as the bounding surface determination component 128. For instance, the bounding model generation system 518 may determine the bounding structure based on the part under consideration and/or other factors. As detailed herein, the bounding model can be used as a reference contour that orients measurements used to determine wear. In some examples, the bounding model generation system 518 can retrieve the bounding model from memory, e.g., from one of the models 522. In other examples, the bounding model generation system 518 may determine the bounding model using a model, such as a wear limit part model.
The remote computing device(s) 502 may also include communication connection(s) 524 that enable communication between the remote computing device(s) 502 and other local or remote device(s), including but not limited to the dealer computing device(s) 122. For instance, the communication connection(s) 524 can facilitate communication with the user device 508, such as via the network(s) 504. The communication connection(s) 524 can enable Wi-Fi-based communication such as via frequencies defined by the IEEE 802.11 standards, short range wireless frequencies such as BLUETOOTH®, other radio transmission, or any suitable wired or wireless communications protocol that enables the respective computing device to interface with the other computing device(s).
In some implementations, the remote computing device(s) 502 can send information, such as instructions to generate GUIs, to the user device 508, via the network(s) 504. The user device(s) 508 can receive such information from the remote computing device(s) 502 and display the GUIs on a display 528 of the user device 508. In some implementations, the user device 508 can perform some of the functions attributed to the remote computing device(s) 502, including generating the GUIs, for example. To facilitate creation of the GUIs, the user device 508 may receive information from the remote computing device(s) 502. In at least one example, the user device 508 can include one or more processors 530 and memory 532 communicatively coupled with the processor(s) 530. In the illustrated example, the memory 532 of the user device 508 may store a wear determination component 534 and/or include data stores 536. In examples, the wear determination component 534 can be substantially the same as the wear determination system 514 and the data stores 536 can include some or all of the same information stored in the data stores 520.
The user device 508 may also include communication connection(s) 538 that enable communication between the user device 508 and other local or remote device(s). For instance, the communication connection(s) 538 can facilitate communication with the remote computing device(s) 502, such as via the network(s) 504. The communications connection(s) 538 can enable Wi-Fi-based communication such as via frequencies defined by the IEEE 802.11 standards, short range wireless frequencies such as BLUETOOTH®, other radio transmission, or any suitable wired or wireless communications protocol that enables the respective computing device to interface with the other computing device(s).
As also illustrated in
The processor(s) 510 of the remote computing device(s) 502 and the processor(s) 530 of the user device 508 can be any suitable processor capable of executing instructions to process data and perform operations as described herein. By way of example and not limitation, the processor(s) 510, 530 can comprise one or more Central Processing Units (CPUs), Graphics Processing Units (GPUs), or any other device or portion of a device that processes electronic data to transform that electronic data into other electronic data that can be stored in registers and/or memory. In some examples, integrated circuits (e.g., ASICs, etc.), gate arrays (e.g., FPGAs, etc.), and other hardware devices can also be considered processors in so far as they are configured to implement encoded instructions.
The memory 512 and the memory 532 are examples of non-transitory computer-readable media. The memory 512, 532 can store an operating system and one or more software applications, instructions, programs, and/or data to implement the methods described herein and the functions attributed to the various systems. In various implementations, the memory can be implemented using any suitable memory technology, such as static random-access memory (SRAM), synchronous dynamic RAM (SDRAM), nonvolatile/Flash-type memory, or any other type of memory capable of storing information. The architectures, systems, and individual elements described herein can include many other logical, programmatic, and physical components, of which those shown in the accompanying figures are merely examples that are related to the discussion herein.
Although various systems and components are illustrated as being discrete systems, the illustrations are examples only, and more or fewer discrete systems may perform the various functions described herein. Moreover, functionality ascribed to the remote computing device(s) 502 may be performed at the user device 508 and/or functionality ascribed to the user device 508 may be performed by the remote computing device(s) 502.
In more detail,
At operation 602, the process 600 can include receiving sensor data of a wear part. For example, the data processing system(s) 120 may receive sensor data generated by the sensor 110 of a wear part, such as the worn part 116, in use on the machine 104. In examples, the user 106 may be prompted to capture specific views of the worn part 116 using the sensor 110. By way of non-limiting example, the sensor 110 may be mounted on a stanchion or other frame that is configured to arrange the sensor 110 relative to the worn part 116. In at least some examples, the sensor data may be point cloud data comprising a plurality of points and depths associated with the points (e.g., depths relative to sensor 110). In examples, the sensor 110 may be a range-finding sensor, such as a time-of-flight sensor, a LiDAR sensor, a radar sensor, 3D scanner, or the like.
At operation 604, the process 600 can include receiving models for unworn and/or wear limit parts. For example, the data processing system(s) 120 may retrieve, access, or otherwise receive information, e.g., in the form of one or more part models, that describe or are otherwise associated with, the worn part 116. In some examples, the part models can include a new part model, such as the new part models 214, 304, which may be representative of the new part 114. Such new part model may include coordinates or extents of a surface of a new, e.g., substantially unused, part. In examples, the new part model may be characterized by nominal or “to specification” measurements. The part models can also or alternatively include a wear limit part model, such as the wear limit part models 216, 306. Such wear limit part models may include coordinates or extents of a surface of a part worn to a wear limit, which may be a predetermined wear limit. In examples, the wear limit may correspond to a limit associated with an imminent failure of the part or some other wear limit. In at least some examples, the wear limit may be determined empirically.
At operation 606, the process 600 can include determining a bounding contour or bounding model enveloping the models. For example, the data processing system(s) 120 may retrieve, access, generate, or otherwise determine a bounding model, like the bounding models 222, 308. As described herein, the bounding model may define orientations or directions along which wear is to be determined by the wear determination components 124, 514, 534. In examples, the bounding model may be any generally convex shape, structure, or surface that at least partly envelopes measured points and surfaces defined by the model(s) received at the operation 604. In some instances, the bounding model may closely approximate the shape of the wear limit part model, but larger.
At operation 608, the process 600 can include determining, for individual points in the sensor data, a wear metric. For example, the operation 608 can include aligning the sensed points (or a model representing the sensed points or other sensor data), the model(s), and the bounding contour in a coordinate system, e.g., a three-dimensional coordinate system, and measuring distances between the models along lines oriented in accordance with the bounding model. For instance, for each of the measured points 208, 310, a distance may be determined from the point to one or both of a point on the new model, e.g., one of the new points 228, 314, and/or a point on the wear limit model, e.g., one of the wear limit points 230, 312. Such distances are measured along the lines 234, 318, which lines are oriented according to the bounding structure 222, 308. In at least some examples, the lines 234, 318 can be lines normal to the bounding structure or model and passing through the measured points 208, 310, as described herein. The wear metric may further be determined based at least in part on these distances. For instance, in the example of
At operation 610, the process 600 can determine whether the wear metric associated with individual measured points meets or exceeds a threshold wear limit. For example, the operation 610 may be a type of filter that removes outliers. By way of non-limiting example, points in the sensor data may be associated with surrounding components or objects in an environment of the wear part of interest and such returns can return wear metrics in excess of a predetermined threshold, e.g., greater than 100%. In examples, it may be desirable to retain all points that return a wear percentage up to and including a value over 100%. In some instances, a portion of the worn part may be worn more than the wear limit, e.g., when the wear limit corresponds to coordinates of a surface of a wear part that suggest part replacement, but may not be associated with part failure. Similarly, returns associated with positions of mounting holes, mounting features, features that are not expected to wear, or other apertures can be calculated to have excessive wear, may be filtered out by the operation 610.
In examples, if it is determined at the operation 610 that the individual point meets or exceeds the wear threshold, an operation 612 can include disregarding the point. As noted above, points having exceptionally high wear metrics, e.g., greater than or equal to 125% in some examples, may be assumed to be anomalous, and thus may be omitted from further consideration.
Alternatively, if at the operation 610 it is determined that the wear metric does not meet or exceed the threshold, the process 600 can include, at operation 614, generating a representation of the part with per-point wear metrics. That is, the measured points that are not filtered out at the operation 610 may be used to identify to the user 106 wear associated with the part.
At operation 616, the process 600 can include causing display of a graphical user interface including the representation. For example, the data processing system(s) 120 can generate a graphical user interface, like the graphical user interface 400, and send information that causes the user device 108 to render the graphical user interface 400 on its display. In examples, the interface 400 can display additional information about the wear part, including one or more additional wear metrics, information about the wear part, e.g., a type or model, instructions and/or controls for ordering replacement parts, or other information.
At operation 702, the process 700 can include determining a wear metric for a wear part. For example, the operation 702 can include all or portions of the processes 200, 600 described herein. In implementations, the wear metric can be a per-point wear metric, e.g., for individual of multiple measured points, or can be a single metric associated with the entire part. By way of non-limiting example, a wear metric descriptive of the entire part can be an average or weighted-average of all or a subset of all per-point wear metrics. In at least one example, a wear metric for a part may be an average of some predetermined number (e.g., the highest 30) or percentage (e.g., the top 10% of all points) of determined wear metrics. In other examples, the wear metric for the part can be a greatest calculated wear metric over measured points. Other metrics also are contemplated herein, and will be appreciated by those having ordinary skill in the art with the benefit of this disclosure.
At operation 704, the process 700 can include determining whether the wear metric meets or exceeds a wear threshold. For example, an operator, foreman, administrator, manufacturer, technician, or other entity associated with the wear part or a machine using the wear part may determine that parts having wear above a predetermined threshold, e.g., above 85%, 90%, 95% etc. wear, should be replaced. Thus, the operation 704 can determine whether the wear metric determined at the operation 702 meets or exceeds this threshold.
If, at the operation 704 it is determined that the wear metric does not meet or exceed the threshold, the process 700 returns to the operation 702 to continue to determine part wear, Specifically, in this scenario the part is still usable.
In contrast, if, at the operation 704 it is determined that the wear metric meets or exceeds the threshold wear, at operation 706 the process 700 can include ordering a replacement part. For example, the data processing system(s) 120 and/or the user device 108 may send a signal or other information to the dealer computing device(s) 122 to instruct the dealer computing device(s) 122 to send a replacement part and/or schedule maintenance to install the new replacement part. In other instances, the dealer computing device(s) 122 may receive information about the wear metric, and determine that the wear part should be replaced. In some examples, the threshold wear metric may be determined based at least in part on a length of time to obtain a replacement wear part. For instance, when a replacement wear part is stocked at a location proximate the worksite at which the machine is operating, the part may be allowed to approach a relatively higher wear percentage, e.g., because it may be immediately replaced if it fails. Alternatively, if replacement parts are not available on-site, the threshold wear metric may be relatively lower, e.g., to allow additional time to receive a replacement part.
At operation 708, the process 700 can include replacing the wear part. For example, a technician or other entity may be scheduled to replace the wear part with the replacement part ordered at the operation 706. As described herein, maintaining machines with wear parts that are not overly worn can increase machine efficiency and performance.
Although not explicitly included in
The disclosed systems and methods find application in any environment in which a user wishes to determine the degree of wear of a wear part. By using a sensor to capture sensor data of the wear part, e.g. depth of points on a surface of the wear part, and determine the degree of wear from the sensor data, the disclosed systems and methods allow the user to easily assess the part, even in the absence of detailed knowledge about the part, the part's wear characteristics, or the machine.
For example, and with reference to
Techniques described herein may improve efficiency at work sites, such as the machine site 102, and/or improve efficiency of machines, like the machine 104. By way of example and not limitation, techniques described herein can ensure that wear parts are properly maintained and/or replaced, which can lead to more efficient use of the machine 104, including but not limited to reduced fuel consumption and/or wear of other, ancillary parts. For instance, when teeth such as those shown in the enlarged view 112 in
One having ordinary skill in the art will appreciate the computer programs for implementing the disclosed techniques may be stored on and/or read from computer-readable storage media. The computer-readable storage media may have stored thereon computer-executable instructions which, when executed by a processor, cause the computer to perform, among other things the processes disclosed herein. Exemplary computer-readable storage media may include magnetic storage devices, such as a hard disk, a floppy disk, magnetic tape, or other magnetic storage device known in the art; optical storage devices, such as CD-ROM, DVD-ROM, or other optical storage devices known in the art; and/or electronic storage devices, such as E PROM, a flash drive, or another integrated circuit storage device known in the art. The computer-readable storage media may be embodied by one or more components of the environment 100.
It will be apparent to those skilled in the art that various modifications and variations can be made to the disclosed payload overload control system without departing from the scope of the disclosure. Other embodiments will be apparent to those skilled in the art from consideration of the specification and practice of the embodiments disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope of the disclosure being indicated by the following claims and equivalents thereof.