In the mechanical part industrialization field, designers use computers to design and manufacture mechanical parts. The design of a mechanical part usually involves two steps. The first step is the functional design, which allows the designer to set the shape, dimensions, and features of the part to fulfill a functional specification. Designers usually accomplish this step with the use of Computer Aided Design (“CAD”). CAD programs allow designers to create and view three-dimensional representations of a part. Usually, CAD programs do not design the part based on how the part will be manufactured, but instead based on the functional specification of the part.
The second step in the design of a mechanical part is the part industrialization, which allows the designer to change the shape of the functional part so that it can be manufactured. Designers usually accomplish this step with the use of CAD. The part industrialization step depends on the manufacturing process and ideally saves the functional design of the part. Examples of manufacturing processes include molding, stamping, machining, forging, bending, and welding.
During the part industrialization step of a molding design, the designer usually changes the shape of the functional part to ensure proper manufacturing.
Draft angles can be used in the industrialization step to ease the extraction of a new part from the mold, ensure that the mold does not break, and ensure the part does not have bad surface quality. A draft angle can be added to faces in the mold that are parallel to the pulling direction. These faces are drafted (or bended) according to a given angle.
The draft angle typically should not fundamentally change the functional specification of the part. Otherwise, the mechanical specifications of the part can be lost during the manufacturing process. Furthermore, the sides of the drafted part should fit on the parting surface. Otherwise, small and sharp steps can remain on the final part, which, in most cases, have to be removed by hand in expensive post processing.
Small steps can also cause problems when the mold is used in another molding process.
As is shown in
Low-level graphic and geometric tools are currently used to change the points and faces of the designed part to implement the draft angle. Such low-level work can take long periods of time and can require many individual user interactions with the design program. These existing techniques involve complex surfacing tools and the skilled user usually has to build the drafted faces and fit the faces on the parting surface manually. This hand made geometry is generally fragile and rework is necessary when modifications are made to the functional part. This invention addresses some of these problems.
This invention relates to the industrialization of a designed part. In particular, the present invention presents a method and system for adding a draft angle to a molded part.
In one aspect of this invention, a computerized method of industrializing a designed part is presented. The method includes selecting a parting surface that divides the designed part, which includes a functional specification, into a first side and a second side. A draft angle is also selected. A change is computed in the first side and the second side using the selected draft angle. During the computation, the functional specification is maintained and the first side and second side meet on the parting surface. A face and a pulling direction can be selected on the designed part. The selected face can be parallel to the pulling direction for the first side. Faces adjacent to the selected face can also be used in the computation. The faces can be bound by a sharp edge. Once computed, the industrialized designed part can be displayed.
In another aspect of this invention, a selection is made between an optimal blend draft method and a driving/driven blend draft method. In the optimal blend draft method, a selected corner radius for smoothing a connection between two adjacent faces can be used in the computation. A transitions between a face on each side can include using a blending equation and the corner radius. The computation can include automatically switching a driving side between a first and second side to minimize material added. The draft angle can include a first minimum draft angle for the first side and a second minimum draft angle for the second side.
In the driving/driven blend draft method, the draft angle can include a nominal draft angle, which can be guaranteed. A selection of a driving side can be made. The computed designed part can be displayed and then recomputed based on new selections.
In another aspect of this invention, the functional specification can include a neutral element of the designed part, which remains unchanged during the computation. The computation can include calculating the shape with the neutral element using a formula with the parting surface, the draft angle, an equation for a cone on the side of the neutral element, an equation for a derivative of the cone, the cone's half angle, and a space variable.
In another aspect of this invention, the functional specification can include a reflective element of the designed part, which is tangent to the draft surface. The computation can include calculating the shape with the reflective element using a formula with the parting surface, the draft angle, an equation for a cone on the side of the reflective element, an equation for a derivative of the cone, and the reflect element.
The computation can include using one or more of the following blending equations:
B(r0,a0,b0,a,b,u,v, . . . )=√{square root over (r02+∥S(u,v)−P(.)∥2)}{square root over (r02+∥S(u,v)−P(.)∥2)}√{square root over (r02+∥S(u,v)−Q(.)∥2)}{square root over (r02+∥S(u,v)−Q(.)∥2)}(a−a0)(b−b0)−r02,
wherein S(u,v) represents a parting surface, r0 represents a corner radius, P(.) represents a first curve or surface, Q(.) represents a second curve or surface, a0 represents a minimum first draft angle, b0 represents a minimum second draft angle, a represents a first draft angle, and b represents a second draft angle. The computation can include using a blending equation:
B(r0,a0,b0,a,b,u,v, . . . )=a−a0,
wherein a0 represents a minimum first draft angle and a represents a first draft angle. The computation can include using a blending equation:
B(r0,a0,b0,a,b,u,v, . . . )=b−b0,
wherein b0 represents a minimum second draft angle and b represents a second draft angle. The computation can include calculating a solution to an equation using marching methods or numerical continuation. The parting surface can be tangent continuous.
The described method can be implemented on a computer system including a computer, which includes a memory and a processor. Executable software residing in the computer memroy can be operative with the processor to implement the described method. The described method can also be implemented on a computer data signal embodied in a digital data stream. Similarly, the described method can be implemented on a data storage apparatus storing instructions to configure a computer to implement the described method.
This invention may have one or more of the following advantages. This invention can allow the designer to draft the faces crossing the parting surface in such a way to ensure that the functional specifications are maintained, the resulting surfaces are adjusted on the parting surfaces, and the minimum draft angle is preserved.
The method and system for adding the draft angle shortens the time spent in part industrialization because the correct shape is produced in one shot. The complexity of the CAD data is also reduced so that another user can easily understand the drafted part. What is done with a single solid modeling can feature require five to ten wire frame and surface features with the current technology. The invention can also create a solid part, which means that the system maintains the closed skin of the boundary of the solid. Solid modeling can accurately simulate real 3D objects. The geometry is more robust because of solid modeling integration. The system can also store the draft angle calculations and reapply them if the originally designed part is changed. Drafting a part with this invention can be easier, faster, and yield better geometry.
a and 13b illustrates the driving-driven draft method.
Context:
This invention relates to the industrialization of a designed part. In particular, the present invention presents a method and system for adding a draft angle to a designed part. The designed part is a computer model of the part that will be manufactured.
The user selects the parting surface 301, S(u,v), which is the surface between the first side 105 and second side 106 of the part that will be manufactured. The parting surface is tangent continuous, but not generally curvature continuous. Based on the parting surface, the user selects the two pulling directions 104 for the two sides 302. The first pulling direction, D1, and the second pulling direction, D2, are the directions the sides can be pulled apart after forming a single part from the two sides. Each pulling direction is a three-dimensional vector that defines an oriented direction in space.
The words “upper” and “lower” are used to describe the two sides 105 and 106 using a vertical pulling direction. The “upper” side signifies the first or top side, and the “lower” side signifies the second or bottom side. This is not a geometrical restriction. The pulling direction can be horizontal, vertical, or at any angle between horizontal and vertical.
Selection of the Faces to Draft:
The user also selects the face to draft 303. The selection process can be automatically extended. For example, the user can select a face to draft and the computer can extend this selection to all the neighboring faces that share a common tangent at the intersection with the selected face. The computer can then extend the selection to neighboring faces of the neighboring faces in a recursive process. In
Selection of the Reference Elements:
The user also selects functional specifications, which can be neutral elements and/or reflect faces 304. During the drafting operation, neutral curves remain unchanged. The neutral curves are typically sharp edges of the mechanical part (but not all sharp edges are necessarily neutral curves). These edges can exist on the part itself, or can result from the intersection of the part and a neutral element (e.g., place or surface). The user's selection of neutral elements is what saves the functional dimensions of the part. The upper neutral curve, P(s), and lower neutral curve, Q(t), can be used to ensure that those edges are not changed when the draft angle is added. Referring to
When no sharp edges are available for the drafted surface, reflect surfaces can be selected instead of the neutral elements. The user's selection of reflect surfaces defines where the drafted surfaces are connected to the part. The draft surface is tangent to the reflect surfaces. The user uses the upper reflect surface, P(s1,s2), and the lower reflect surface, Q(t1,t2), in place of the neutral curve in situations where no edge defines the functional dimensions of the part.
Selection of the Draft Method:
At this point, the user has two choices: either to choose which side of the part (as defined by the parting surface) will lead the drafting process, or let the system choose. The former method (known as the “driving/drive method”) is usually iterative in the sense that entering the minimum draft angle for the selected side (known as the “driving side”) does not automatically guarantee the sufficiency of the angle calculated by the system for the second side (known as the driven side). This can lead to an increased first draft angle, which can generate extra useless matter as is shown in
In the second method (known as the “optimal blend draft”), the system chooses for each face which side will be the driving side, in order to minimize the amount of added matter. This may lead to the upper and lower faces being alternatively the driving and driven side for the same part. When this occurs, a blending step is used to create a smooth connection between faces involved in the transition to avoid the creation of filling faces that would show sharp edges. The upper and lower draft angles are automatically calculated so that they respect the minimum draft angles entered by the user. The order of these various steps are usually not important and can remain transparent to the user. Both of these methods are described in further detail below.
Definition of the Angle Values and Calculation of the Draft Faces:
Depending on the selected method, the user then inputs either one nominal draft angle value in the case of the driving-driven method, or two minimum draft angle values and a blending corner radius in the case of the optimal draft method.
In the case of the optimal draft method, the user selects the upper and lower minimum draft angles 306. The upper draft angle, a0, and the lower draft angle, b0, are minimum values for the angles that the system will add to the drafted faces. Some of the examples presented show an extreme draft angle for illustration purposes. In practice, the draft angle is usually quite slight to maintain the functional dimensions of the part. For example, a draft angle of two degrees can be used in aluminum and plastic, a draft angle of about three degrees can be used in grey casting, and a draft angle of about five degrees can be used in forging.
In the optimal draft method, the user also inputs the corner radius 305. The corner radius, r0, defines the smoothness of the transitions between the faces of the same side when the system changes the driving side. Using the corner radius, the system can ensure that two idly adjacent faces on a side will not have a sharp edge along their common edge when the driving side is changed. The corner radius is introduced in this situation to smooth the transition between these two adjacent faces.
Based on the functional dimensions, the parting surface, the neutral curves, the reflect surfaces, the corner radius (if any), and the minimum draft angles, the system computes the drafted solid 307. When the draft angle is added to both sides of the part, a blending equation is added to blend (or smooth) each upper and lower draft surface. It should be noted that this smoothing step is done between faces belonging to each side of the parting surface only if there are changes between which side drives the drafting process. The numerical solution can be computed through standard marching methods, numerical continuation, or other numerical methods that use abstract non-linear systems that feature n equations and n+1 unknowns. The equations are described below.
In the case of the driving-driven method, the user selects either the upper or lower draft angles 306, which becomes the nominal value for the angle that the system will add to the drafted faces. Because all faces from the selected side will be driving the calculation, there is no creation of filling faces and no need for a blending corner radius.
An example of a displayed part is shown in
b shows an example of the result obtained after selection of an increased draft angle. Viewing
Computation Steps:
In the optimal blend draft method, the system drafts the two sides together in such a way that the minimum angle requiremnt is satisfied along the draft surfaces, and both sides fit on the parting surface. This feature is optimal because the minimum amount of material can be added to the part. This method shows possible transitions between the upper and lower sides using a blending equation. For example, for the first pair of upper and lower faces, the system may choose the upper face and use the a0 value. For the next pair, the system may choose the lower face and use b0 value, as is shown in
The blending equation, B(r0,a0,b0,a,b,u,v, . . . )=0, is usually at least continuously differentiable and often twice continuously differentiable The blending equation can depend on the derivatives of the parting surface, neutral curves, and the reflect surfaces. The blending equation can capture the fact that the draft angles, a and b, are both greater than the minimum values, a0 and b0. If one of the draft angles is much greater than its minimum value (i.e., a>>a0 or b>>b0), the other angle provided by the equation should be close to (but still larger than) its minimum value (b≈b0 or a≈a0).
A generic shape of the blending equation is given in the following equation:
B(r0,a0,b0,a,b,u,v, . . . )=√{square root over (r02+∥S(u,v)−P(.)∥2)}{square root over (r02+∥S(u,v)−P(.)∥2)}√{square root over (r02+∥S(u,v)−Q(.)∥2)}{square root over (r02+∥S(u,v)−Q(.)∥2)}(a−a0)(b−b0)−r02 Equation 1,
where a≧a0 and b≧b0.
The neutral curve and the reflect surface cannot be defined at the same time on the same side. For this reason, the possible cases of surfaces include: (i) neutral curves on upper and lower sides; (ii) reflect surfaces on upper and lower sides; (iii) neutral curve on the upper side and reflect surface on the lower side; and (iv) reflect surface on the upper side and neutral curve on the lower side.
If a neutral curve is involved, the shape of the upper drafted surface is governed by the equations:
g(a,P(s)−S(u,v))=0
<g′(a,P(s)−S(u,v))|P′(s)>=0 Equation 2,
where a is the current value of the upper draft angle, b is the current value of the lower draft angle, g(a,X)=0 and h(a,X)=0 are the implicit equations of the upper and the lower cones respectively, and g′(a,X) and h′(a,X) are the derivative of the cones functions with respect to the space variable. The upper cone's axis is the upper pulling direction, a is the cone's half angle, and X is the space variable.
Similar equations govern the lower drafted surface when a neutral curve is involved:
h(b,Q(t)−S(u,v))=0
<h′(b,Q(t)−S(u,v))|Q′(t)>=0 Equation 3.
If a reflect surface is involved, the shape of the upper drafted surface is governed by the equations:
Similar equations govern the lower drafted surface when a reflect surface is involved:
The blending equation, B(r0,a0,b0,a,b,u,v, . . . )=0, is then added to finish setting up the full system. It involves both the upper and lower draft angle values, the corner radius, the parameters of the parting surface, and the parameters of the neutral curve and/or the reflect surface.
The system sets up equations to solve based on the selected sides and types. In the first situation, when neutral curves are involved on both sides, the equations are:
g(a,P(s)−S(u,v))=0
<g′(a,P(s)−S(u,v))|P′(s)>=0
h(b,Q(t)−S(u,v))=0
<h′(b,Q(t)−S(u,v))|Q′(t)>=0
B(r0,a0,b0,a,b,u,v,t)=0 Equation 6.
This system can feature five scalar equations and six scalar unknowns: (u,v,s,t,a,b). Under usual regularity conditions, the solution is a parameterized arc in a six dimensional space:
σ(u(σ),v(σ),s(σ),t(σ),a(σ),b(σ)) Equation 7,
from which the drafted surfaces are easily computed. The upper drafted surface is the ruled surface parameterized by:
U(σ,λ)=P(s(σ))+λ(S(u(σ),v(σ))−P(s(σ))) Equation 8,
and the lower drafted surface is the ruled surface parameterized by
L(σ,μ)=Q(t(σ))+μ(S(u(σ),v(σ))−Q(t(σ))) Equation 9.
When neutral curves are involved on both sides, the blending function in is
B(r0,a0,b0,a,b,u,v,s,t)=√{square root over (r02+∥S(u,v)−P(s)∥2)}{square root over (r02+∥S(u,v)−P(s)∥2)}√{square root over (r02+∥S(u,v)−Q(t)∥2)}{square root over (r02+∥S(u,v)−Q(t)∥2)}(a−a0)(b−b0)−r02 Equation 10
In another situation, when reflect surfaces are involved on both sides, the equations are:
This system features seven scalar equations and eight scalar unknowns: (u,v,s1,s2,t1, t2,a,b). Under regularity conditions, the solution is a parameterized arc in an eight dimensional space:
σ(u(σ),v(σ),s1(σ),s2(σ),t1(σ),t2(σ),a,(σ),b(σ)) Equation 12,
from which the drafted surfaces are easily computed. The upper drafted surface is the ruled surface parameterized by:
U(σ,λ)=P(s1(σ),s2(σ))+λ(S(u(σ),v(σ))−P(s1(σ),s2(σ))) Equation 13,
and the lower drafted surface is the ruled surface parameterized by
L(σ,μ)=Q(t1(σ),t2(σ))+μ(S(u(σ),v(σ))−Q(t1(σ),t2(σ))) Equation 14.
The blending equation for the situation where the reflect surfaces are involved on both sides is
B(r0,a0,b0,a,b,u,v,s1,s2,t1,t2)=√{square root over (r02+∥S(u,v)−P(s1,s2)∥2)}{square root over (r02+∥S(u,v)−P(s1,s2)∥2)}√{square root over (r02+∥S(u,v)−Q(t1,t2)∥2)}{square root over (r02+∥S(u,v)−Q(t1,t2)∥2)}(a−a0)(b−b0)−r02 Equation 15.
When a neutral curve is involved on the upper side and a reflect surface is involved on the lower side, the equations are:
This system features six scalar equations and seven scalar unknowns: (u,v,s,t1,t2,a,b). Under usual regularity conditions, the solution is a parameterized arc in an seven dimensional space:
σ(u(σ),v(σ),s(σ),t1(σ),t2(σ),a(σ),a(σ),b(σ)) Equation 17,
from which the drafted surfaces are easily computed. The upper drafted surface is the ruled surface parameterized by:
U(σ,λ)=P(s(σ))+λ(S(u(σ),v(σ))−P(s(σ))) Equation 18,
and the lower drafted surface is the ruled surface parameterized by:
L(σ,μ)=Q(t1(σ),t2(σ))+μ(S(u(σ),v(σ))−Q(t1(σ),t2(σ))) Equation 19.
The blending equation when a neutral curve is involved on the upper side and a reflect surface is involved on the lower side is:
B(r0,a0,b0a,b,u,v,s,t1,t2)=√{square root over (r02+∥S(u,v)−P(s)∥2)}{square root over (r02+∥S(u,v)−P(s)∥2)}√{square root over (r02+∥S(u,v)−Q(t1,t2)∥2)}{square root over (r02+∥S(u,v)−Q(t1,t2)∥2)}(a−a0)(b−b0)−r02 Equation 20.
Reflect-neutral equations are shown in the following set of equations.
This system features six scalar equations and seven scalar unknowns: (u,v,s1,s2t,a,b). Under usual regularity conditions, the solution is a parameterized arc in a seven dimensional space:
σ(u(σ),v(σ),s1(σ),s2(σ),t(σ),a(σ),b(σ)) Equation 22,
from which the drafted surfaces are easily computed. The upper drafted surface is the ruled surface parameterized by:
U(σ,λ)=P(s1(σ),s2(σ))+λ(S(u(σ),v(σ))−P(s1(σ),s2(σ))) Equation 23
and the lower drafted surface is the ruled surface parameterized by:
L(σ,μ)=Q(t(σ))+μ(S(u(σ),v(σ))−Q(t(σ))) Equation 24
The blending equation when a reflect surface is involved on the upper side and a neutral curve is involved on the lower side is:
B(r0,a0,b0,a,b,u,v,s1,s2,t)=√{square root over (r02+∥S(u,v)−P(s1,s2)∥2)}{square root over (r02+∥S(u,v)−P(s1,s2)∥2)}√{square root over (r02+∥S(u,v)−Q(t1)∥2)}{square root over (r02+∥S(u,v)−Q(t1)∥2)}(a−a0)(b−b0)−r02 Equation 25.
Finally, after the equations are solved and, if necessary, the user accepts the computed part, the system can display the drafted part 308.
In the driving/driven draft method, there is no transition, and basically no need for a blending equation. To ease the mathematical formulation and implementation, however, the blending equation can still be used. In some implementations, only the driving/driven draft method can be made available to the user. In this case, the equation can be limited to a statement that the draft angle on the driving side has the nominal value selected by the user, namely:
B(r0,a0,b0,a,b,u,v, . . . )=a−a0=0 Equation 26.
If the upper side is driving, or lower side is driving, then the blending equations is:
B(r0,a0,b0,a,b,u,v, . . . )=b−b0=0 Equation 27.
All other equations as described in the previous section remain unchanged.
Although as already mentioned, the driving/driven method is not always as efficient as the optimal one, the simplified Equations 2 and 3 can lead to some savings in computation time and can be a useful trade-off between cost and efficiency in certain applications.
This invention can be applied as a feature provided in the CAD system. This feature can be edited for changes, inactivated, updated, or deleted like any other associative feature. In particular, if the user later changes the dimensions of the functional part, the system can replay the geometry with the new functional dimensions and effectively recalculate the draft angles for the part. The methods disclosed can also be used on complicated parts as is shown in
The methods and systems disclosed can be implemented on a single computer, a networked computer or system, or any computing device designed to work with CAD or similar design systems. A number of embodiments of the present invention have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the invention.
Number | Name | Date | Kind |
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5189781 | Weiss et al. | Mar 1993 | A |
5552995 | Sebastian | Sep 1996 | A |
6484063 | Liou et al. | Nov 2002 | B1 |
Number | Date | Country |
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WO 0128781 | Apr 2001 | WO |
Number | Date | Country | |
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20020183877 A1 | Dec 2002 | US |