The invention relates to diagnostic analysis and, more particularly, to the diagnosis of manufacturing defects.
Manufacturing processes, and the products they create, sometimes suffer from defects. The job of detecting and eliminating these defects falls to manufacturing engineers, who, over the years, have developed statistical approaches in an attempt to address them. They have also developed various controls, ranging from process control to quality control to product control, for attempting to capture defective products before they reach customers.
These controls are based on identification of limits on the capabilities of the various processes that are used in the manufacture of a workpiece or product. For example, process control is based on the capability of the process that produces the workpiece. An illustration is provided in
So-called quality control procedures are directed to preventing “out-of-spec” parts reaching customers, but they do not necessarily reduce the number of rejects. Rather, these approaches seek to distinguish good parts from bad based on product features that appear to be readily measured, without revealing mechanisms responsible for product defects or physical insights that could more readily lead to the discovery of such mechanisms.
The present invention provides approaches for identifying the causes of manufacturing problems by breaking down the different phases of a manufacturing process, such as the different actions of a machine tool on a workpiece, so that each phase or action can be related to the formation of an element or a feature of the final workpiece, preferably providing a one-to-one correspondence between the forming of the shape of the feature and a process step or action that produces the shape. This procedure, then, helps reveal defects which process action produces it. Once the source of the defect is detected, both the source and the workpiece defect it causes can be addressed.
The present invention provides not only a method for detecting defects in a manufacturing process, but also a method for identifying where in the process the defects occur, so that appropriate corrective action can be identified, and such action taken, at the point of occurrence. This object is accomplished by relying on a process characterization approach that focuses on the actual effect of the process on a workpiece.
In one embodiment of an aspect of the present invention, a method for use in a system for diagnosing the causes of deviation from an intended form in a workpiece produced by a manufacturing process is provided. At least one form is defined for the workpiece and for a piece of manufacturing equipment that acts upon the workpiece to impart the form. A plurality of measurements for each workpiece is defined, each relative to a respective reference datum. The subsequent steps involve generating a record of the plurality of measurements corresponding to each workpiece and inferring from the comparison of the measurements for at least one of the workpieces the existence of an alert condition associated with the action of the manufacturing equipment on the workpiece.
Another embodiment of an aspect of the present invention involves a method for identifying evidence of deviation from specification in a workpiece produced by a manufacturing process, the manufacturing process being performed by respective manufacturing equipment. The method includes identifying a set of repeated portions of the workpiece, each instance of a repeated portion having forms, the form of one instance of a repeated portion being substantially the same form as the other instances. For each instance of the repeated portion, a set of measurements of the reproducible part is made relative to a respective reference datum. Each set of measurements is compared to a respective target range of values. Based on the comparison, the existence of evidence of deviation from specification is inferred.
In still another embodiment of the present invention, a method for assessing a condition of a workpiece acted upon by manufacturing equipment starts by identifying a set of forms, each form corresponding to an aspect of the action of the manufacturing equipment upon the workpiece. The subsequent steps involve making a plurality of measurements for each form; computing, for each plurality of measurements, a respective deviation from a corresponding reference datum; defining a deviation threshold; and, if a computed deviation exceeds the deviation threshold, inferring the existence of the condition attributable to the action of the manufacturing equipment on the workpiece.
In yet another embodiment of an aspect of the present invention, a method is provided for detecting deviations from an intended form in a mechanical part. The deviations are detected on the basis of measurements of geometric properties relative to a reference datum, the geometric properties imparted by a machine tool operating on the mechanical part. The method comprises the steps of: identifying a hierarchic set of geometric forms characterizing the mechanical part, each form corresponding to an action of the machine tool on the part; categorizing the geometric forms from a lowest order to a highest order; making a plurality of measurements corresponding to the lowest order form; for each plurality of measurements, computing a respective deviation from a defining datum; checking for an alert condition for each of the respective deviations; and if an alert condition is present, inferring a deviation from the intended form.
In another embodiment of an aspect of the present invention, a method is provided for characterizing the ability of a machine tool to reproduce a product without deviating from a specification intended for at least a portion of the product, the characterization based upon taking geometric measurements. The method involves identifying a set of geometric forms present in the product; selecting a first of the set of geometric forms; making a plurality of measurements corresponding to the selected geometric form; for each plurality of measurements, computing a deviation from a respective reference datum; checking for an alert condition for each of the respective deviations; if an alert condition is present, adjusting the machine tool and repeating the method from the step of making additional measurements corresponding to the same selected geometric form iteratively until no further alert condition is found. If no alert condition is present, the method is repeated from the step of selecting the next set of geometric forms by incrementing to the next form until all geometric forms have been selected and no further alert condition is found.
The present invention also provides a method for representing measured deviations for features attributable to the forming of a physical object, in a suitable frame of reference. The method involves identifying an order for the features; providing a first region for comparing measurements corresponding to the features of the object; providing a second region associated with the first region; wherein the first region comprises frames of reference for the set of objects with respect to which the measurements are represented; and wherein, in the second region, the order of the object features is represented in correspondence with the measurements represented in the first region, and representing the measurements in a corresponding frames of reference, in conjunction with respective representations of the order of the measured objects.
a shows a conventional shaft.
b is a frequency plot of a range of diameters of the shaft of
a is a top-view of an assembly of a shaft and its sleeve.
b is a frequency plot of a range of diameters of the shaft of
c is a cross-sectional view of the assembly of
d is a side view of the sleeve of
e is a side view of a defective shaft.
f is an enlarged view of the defective shaft of
a is an isometric view of a shaft showing a defective cross-sectional area, according to the present invention.
b shows a hierarchic arrangement of a category of geometric elements, or forms, in an embodiment of an aspect of the present invention.
a shows an arrangement of geometric forms and reproductive forms, in an embodiment of the present invention.
b shows a shaft and its housing.
a is an isometric view of an engine block deck.
b is a graph of the distribution of measurements associated with surface profile of the engine block deck of
c is an isometric view of the engine block deck of
d is an isometric view of the engine block deck of
e is an isometric view of the engine block deck of
f is a multi-form chart, comprising a combination of a multi-form graph and a multi-form table showing the plot of the various elements, or geometric forms, that constitute the engine block deck of
g is a generalized multi-form chart of
a is a condensed chart showing a hierarchical arrangement of the forms of the engine block deck of
b shows the finding of an exemplary defect in one of the forms used in a graphic analysis of
The present invention provides a diagnostic method for detecting defects in a manufacturing process through an ability to control the process of creating shapes in a workpiece. A workpiece comprises elements, which may be portions and features, which are characterized by respective geometric forms. The method, broadly speaking, is accomplished through characterization of the manufacturing process, specifically characterizing the manufacturing process as a plurality of aspects or steps that correspond to actions involved in forming of the various elements of a work product. Then, actions of the manufacturing process associated with work product defects are identified. Where the manufacturing process involves forming a piece of hardware, an element of a workpiece may be a portion or feature of the workpiece characterized by a geometric form. Through a systematic and preferably (though not necessarily) hierarchically ordered set of measurements of the elements of an apparently defective product, one or more defective forms associated with the actions of the manufacturing equipment on the workpiece can be detected. In this manner, the source of a defect may be more efficiently and directly arrived at, and corrective action may more readily be taken at the point of occurrence of the defect.
According to an aspect of the present invention, a method for identifying geometric forms for a workpiece that is acted upon by manufacturing equipment begins by characterizing the process steps used in producing that workpiece or product. For this purpose, a flow diagram is constructed. Corresponding to each process step (that is, corresponding to each action of the machine tool) in the process flow diagram, a corresponding physical form of an aspect of the workpiece is identified and diagrammed. A practitioner may find it advantageous to begin this exercise with the least complicated geometric form that, together with successively higher order forms, identify the overall the relevant geometry of the workpiece. A form may, for example, be a set of points that define radii of a shaft, a set of radii that together define an arc of the shaft, a plurality of arcs that form circles (or closed curves, at any rate), and the set of circles that define the shaft, or a segment of it. Any variance of the actual workpiece data corresponding to a form, relative to a limit imposed by a specification, also referred to here as a reference datum, may provide evidence of a corresponding workpiece defect, the cause of which may be an aspect of the process step associated with that workpiece form. The overall variance of actual measurements from a datum can be distributed equally between the selected process steps or allocated according to the expected influence of the forms on the functioning of the workpiece. However, no one form should be allocated more than 50% of the variance.
Accordingly, the geometric forms are measured. They may include, without limitation, radii, arc, closed curves (such as circles, ellipses, etc.) and surfaces. For each selected form, deviation of the allocated variance from the datum is computed. The form having the greatest degree of deviation is postulated to be associated with a defect responsible for causing the unacceptable variance from the datum. A defect, if of sufficient severity, may give rise to an alert condition. An alert conduction can be any condition recognized for the manufacturing process as one that may trigger an observation or other response from an entity with responsibility for at least some aspect of the process. An alert condition may be inferred, for example, if a deviation exceeds a defined threshold based on a preselected rule. The rule may vary depending upon the characteristics of the form. For example, for an arc, the rule may state the limits of the angle that subtends the arc. Attention can then be focused on the errant process step causing the unacceptable deviation, and an appropriate adjustment identified and implemented. Following one or more iterations of the adjustment process, the tendency of the machine tool to generate the detected defects can be remedied.
Aspects of an embodiment of a method according to the present invention are shown in
d shows a side view of sleeve 110, with shaft 100 withdrawn from the sleeve. The shaft itself is shown in
Having met the upper limit and lower level specifications, both shafts, therefore, are expected to pass quality control. At the same time, however, it is evident from
f shows an exploded isometric view of defective shaft 140. Examination of the shaft reveals that the radius form R 153 and the arc form S 155 in the plane of each of the circles C 150 are “true” within their respective specifications. Although all the forms, up to and including the circle form, meet their respective specifications, the cylinder form 140, generated by the repetitive action of a machine tool, such as a lathe, is out of true, its axis of revolution lying along 144 shown in
A need for corrective action can arise at any one of the steps described above.
In one embodiment, shown in
An embodiment of a method according to the present invention applied to the fabrication of a mechanical shaft is shown in the flow diagram of
When there is no alert condition, a second set of forms is selected at step 490 by incrementing to next form in hierarchy 495, and returning to step 410. In the example shown in
In similar steps of
When there is no alert condition, a second set of forms is selected at step 690 by incrementing to next form in hierarchy 695, and returning to step 610. Steps 620-660 are repeated. If the deviation for the measurements exceeds a threshold value, step 670, then the action of the machine corresponding to the production of the form is adjusted accordingly at step 680. The process is continued iteratively for the remaining forms until measurements for all forms are completed, any alert condition remedied, and until no further adjustment of the process machine is needed 700. At step 710, the machine is ready to produce forms according to a shop print, and, consequently, the workpiece should be defect-free.
a shows a recast of the geometric forms 830 of
In one embodiment, a method for identifying defects through a process characterization approach according to the present invention is described with reference to an example involving an automobile engine block deck 900, shown in
A specified flatness profile for the deck surface 910 shown in
An examination of the block deck surface reveals that the simplest measurable forms that constitute the surface comprise: 1) a point on the surface, 2) line segments defined by a plurality of points, and (3) lines defined by line segments. Points 940 and line segments 950 are shown in
In the illustrated embodiment shown in
For multi-form analysis of additional engine block decks, the multi-form table and the accompanying multi-form graph are extended laterally L, and the measurements are repeated in exactly the same manner as described above. A continuation for a second deck is shown in
As shown in
An analysis of the data plotted in a multi-form deviation chart makes it possible to identify form(s) having the greatest variance, that is, with the accompanying alert condition. The methods of the present invention show that non-random alert conditions generally are most likely to appear, if at all, in geometrical forms. On the other hand, random alert conditions, when they occur, are mostly found in reproductive forms, such as in reproduced workpieces themselves, or in spatial or temporal forms. Accordingly, the corresponding process step(s) or action(s) of the manufacturing equipment is (are) adjusted. This is shown in
While the invention has been shown and described with reference to particular embodiments, those skilled in the art will understand that various changes in form and details of the methods according to the present invention may be made without departing form the spirit and scope of the invention.
Number | Date | Country | |
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Parent | 10236450 | Sep 2002 | US |
Child | 10997379 | Nov 2004 | US |