JP4164784B2 - Wire material design support apparatus, wire design support method, and computer-readable storage medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a wiring design support apparatus and a wiring design support method for a wire material, and for example, relates to a support apparatus and a wiring design support method that support optimal wiring design of various wire harnesses at a design site such as an automobile.
[0002]
[Prior art]
Various electronic devices such as vehicles such as automobiles and home appliances use a wire rod to connect between one electrical component and another electrical component or between one package and another package. .
[0003]
A typical wire material is a so-called wire harness in which a plurality of electric wires and communication wires are appropriately bundled into a single bundle by a protective member such as tape, and predetermined connectors are attached to both ends. Depending on the application (connection destination), the number of wires to be bundled, the thickness of each wire, the presence or absence of a branch point, and the like are different, so the rigidity as a wire harness varies.
[0004]
Conventionally, in a design site of a manufacturer that frequently uses such a wire harness, although a CAD (computer-aided design) system has been widely used for design of electrical components and packages, the wiring route, length, As for the design of the number of wires and communication lines to be combined into one, it is common for the designer to repeat trial production mainly based on intuition and experience.
[0005]
However, in recent years, in order to develop a product in a short period of time without making a prototype of the actual product as much as possible, a series of design work steps are being performed on a design support device using a computer or the like. Also in the wiring design of a wire harness, a support device that can easily realize an optimum design regardless of the experience of the designer is desired.
[0006]
[Problems to be solved by the invention]
Against this background, in current CAD systems, based on a plurality of points (coordinates) defined on a two-dimensional plane or three-dimensional space by an operator, a B-Spline curve, a Bezier curve, or A function that automatically calculates a curve or curved surface that satisfies (approximates) these points using a parametric method such as a NURBS curved surface has also been developed.
[0007]
However, although the shape simulation by these methods satisfies the coordinate data of a plurality of fixed points, it is a simulation by geometric processing. For example, when trying to apply the wiring harness to the wiring harness, It is difficult to manufacture the actual product as it is according to the generated shape because the mechanical weight such as the force generated at the fixed position of the connector etc. is not considered due to its own weight and hardness (rigidity) In many cases (unrealistic).
[0008]
As an example of the parametric method described above, Japanese Patent Application Laid-Open No. 7-182017 proposes a method for simulating the shape of a wire harness disposed along an arm of an industrial robot. In this method, the deformation shape of the wire harness is input by inputting parameters such as a plurality of fixed point positions on the arm of the wire harness to be simulated, tangent vectors at the fixed point positions, the length of the wire harness, and a deformation coefficient. Is automatically calculated, and interference with other peripheral devices is checked.
[0009]
However, in the above-described conventional example, a semi-fixed support member (clip) for fixing the wire harness, a branch provided in the same wire harness, a force generated at each fixing point when the wire harness is bent, and the like are taken into consideration. Absent.
[0010]
In addition, in the automatically calculated wire harness shape, the force applied to the connectors at both ends is not clear, so it is possible to grasp how much strength is required for fixing, or whether it is appropriate. Is difficult.
[0011]
SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a wire design support device, a wire design support method, and a computer-readable storage medium that can easily recognize a force applied to a fixed position of the wire material.
[0012]
[Means for Solving the Problems]
In order to achieve the above object, a wire material design support apparatus for a wire material according to the present invention is characterized by the following configuration.
[0013]
That is, based on a plurality of input fixed positions and the deformation coefficient of the wire material, the wire material design support device for the wire material, which includes an operation means for calculating and notifying the wire shape of the wire material satisfying these fixed positions. And when the said calculating means calculates the wiring shape of the target wire material, while calculating the force added to the said several fixed position by the wire material, information (force | force) about the calculated force The size and direction) are notified.
[0014]
At this time, when the information related to the force is notified, the calculation means may warn that if a predetermined value set in advance as the design strength at the fixed position is exceeded.
[0015]
In addition, for example, the calculation means may be configured to be able to designate degrees of freedom at the fixed positions as input items of the plurality of fixed positions with respect to the target wire rod.
[0016]
Further, as the degree of freedom in the fixed position, when it is possible to specify whether or not the wire rod can be rotated around the normal direction in the fixed position, when the fixed position is specified to be rotatable, the line As the force applied to the fixed position by the strip material, it is preferable to calculate a force that the strip material tries to rotate around the normal direction.
[0017]
In order to achieve the above object, the wire design support method for a wire material according to the present invention is characterized by the following configuration.
[0018]
That is, a wire design support method for a wire material that calculates and notifies the wire shape of the wire material that satisfies the fixed positions based on a plurality of fixed positions and the deformation coefficient of the wire material, and is intended When calculating the wiring shape of the wire material, the force applied to the plurality of fixed positions by the wire material is calculated, and information (magnitude and direction of the force) about the calculated force is notified. And
[0019]
In any of the above-described wire material design support apparatuses and methods, the wire shape of the target wire material is the wire material that has been input with the bending rigidity E of the wire material. Based on the diameter φ, it is preferable to calculate by using a predetermined biquadratic function relating to the curvature ρ of the wire rod and using the calculated bending stiffness E.
[0020]
Further, the present invention is characterized by a computer-readable storage medium in which program codes for realizing the above-described wiring material design support apparatus and wiring design support method by a computer are stored.
[0021]
【The invention's effect】
According to the present invention described above, it is possible to provide a wire design support device, a wiring design support method, and a computer-readable storage medium for a wire material that can easily recognize the force applied to the fixed position of the wire material.
[0022]
That is, according to the invention of claim 1 or claim 7, since the state of the force applied to the fixed position is notified by the magnitude and direction of the force (claims 2, 8), the state of the force It is possible to perform an optimum design considering the above.
[0023]
Moreover, according to the invention of Claim 3 or Claim 9, the improper fixation of a wire rod can be prevented beforehand.
[0024]
According to the invention of claim 4, a plurality of types of options can be prepared as the method for fixing the wire material, and the application of the wiring design support apparatus can be expanded.
[0025]
In addition, according to the invention of claim 5 or claim 10, as a method for fixing the filament material, a member capable of rotating the shaft can be selected, and the rotational force applied to the member can be recognized. .
[0026]
Moreover, according to the invention of Claim 6 or Claim 11, the shape of the wire material actually realizable can be calculated correctly.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, when the wiring design support device and the wiring design method for a wire material according to the present invention are designed for a wiring harness in which a plurality of electric wires are bundled into one and a predetermined connector is attached to each end. Embodiments applied to the above will be described in detail with reference to the drawings.
[0028]
Drawing 1 is a figure which illustrates the whole shape of the wire harness made into a design object in this embodiment. FIG. 2 is a diagram illustrating a cross-sectional shape of the wire harness illustrated in FIG. 1.
[0029]
The wire harness shown in FIG. 1 has a connector 11 connected to the electrical component 12 at each end and has three branch points (branch points).
[0030]
In the cross section of the wire portion of this wire harness, as shown in FIG. 2, the plurality of electric wires 15 are protective members such as a tape 16 or a binding member made of synthetic resin (not shown) (for example, curl or insulation lock (binder)). Etc. are summarized. For this reason, in the wire harness illustrated in FIG. 1, the number of electric wires that are basically gathered in the left part of FIG. Few. Further, the central portion of the wire harness is protected by a protective member 14 having a higher strength than other portions in order to prevent exposure of the electric wire 15 and the inner conductor (not shown) due to contact (friction) with an external interference. Protected.
[0031]
In the wire harness illustrated in FIG. 1, each connector 11 is detachably fixed at a predetermined fixing position according to the fixing position and the mounting direction of a pair of connectors (not shown) provided on the electrical component 12 side. Is done. The clip 13 shown in FIG. 1 is attached to a predetermined position such as an inner surface of a product housing or a stay, and the wire harness is fixed or semi-fixed (rotatable around an axis) at the predetermined position. It is the supporting member to hold | maintain.
[0032]
Then, each branch point on the wire harness is arranged at a position that can be balanced mechanically according to the rigidity of each part, the fixing position of each connector 11, the fixing position of each clip 13, and the supporting method thereof. Is done.
[0033]
FIG. 3 is a diagram illustrating the shape of the rotating clip that holds the wire harness to be designed in the present embodiment.
[0034]
As an example of the clip 13, a rotary clip 13A having a cross-section in FIG. 3A and a top view in FIG. 3B has two support legs having a semicircular cross-section, and a wire above the support leg. A resin-made clip on which a pedestal capable of holding the harness 17 is formed. By inserting these two support legs into a circular mounting hole provided in the base 18, an axis passing through the center of the circle is obtained. It can be rotated. In the present embodiment, in the following description, a rotatable support member such as the rotating clip 13A is generically referred to as a rotating clip.
[0035]
Further, as a clip for fixing the wire harness without rotating at a predetermined position, for example, a square mounting hole is provided in the base 18 and two supports of the rotating clip 13A shown in FIG. A fixed clip can be realized by forming the leg cross section into a quadrangle in accordance with the size of the square mounting hole. In the following description, such clips are collectively referred to as fixed clips.
[0036]
Here, it summarizes about the support member which supports a wire harness, and the freedom degree at the time of fixing with the support member.
[0037]
FIG. 4 is a diagram showing a list of types of support members handled in the calculation of the shape of the wire harness according to the present embodiment and the degree of freedom thereof, and the vertical columns show the above-described connectors and fixing clips as fixing methods of the wire harness. , Rotating clip, and not strictly a fixing method, but shows a bifurcation point (free end) as a comparison. Further, in the horizontal column, when there is a resultant force at a position where the wire harness is fixed by the supporting members in the three-dimensional coordinates xyz, whether or not the fixed position can be moved according to the resultant force, It shows whether or not the fixed position can rotate in the direction corresponding to the resultant moment when there is a moment (composite moment) at the fixed position.
[0038]
As can be seen from the figure, the wire harness cannot move or rotate in any direction (0 degrees of freedom) at the fixed position by the connector and the fixed clip, while the moment at the fixed position by the rotating clip is (2 degrees of freedom). On the other hand, the branch point can be moved and rotated in any direction (6 degrees of freedom).
[0039]
The purpose of the present embodiment is to optimally wire the wire harness having the above-mentioned branch while being held using such a rotating or fixing clip. Here, the outline of the present embodiment will be described.
[0040]
The wire design support device for a wire material according to the present embodiment is based on the diameter of the wire harness and the like when simulating the shape of the wire harness that satisfies the coordinates of the fixing points such as the connector and the fixing clip input by the operator. The bending rigidity E when the wire harness is bent is calculated, the force F and the moment M generated in each part of the wire harness are calculated based on the bending rigidity E and the torsional rigidity C, and these calculated values are used. Calculate the shape of the wire harness. As a result, unlike the conventional wire harness simulation calculation performed only with geometric elements, the simulation calculation more realistic can be realized by adding geometric elements and mechanical elements. .
[0041]
<Relational expression of elastic body model>
In this embodiment, when the wire harness having thickness and elasticity is bent, the force F, the moment E, and the shape generated in each part are calculated by using an elastic body model given by Konapasek. Adopt a vector formula. This vector expression is described in detail in the literature by M. Konapasek and JWS Hearl (fiber Sci & Technology, 5, 1, 1972). Here, the relational expression is outlined with reference to FIG. .
[0042]
FIG. 5 is a diagram for explaining a vector expression of an elastic body model employed in the present embodiment.
[0043]
In the above document, Kanapaso et al. Approximated that the thin rod as the elastic body has no thickness in order to calculate the force F, moment E, and shape of the elastic body having thickness and elasticity, We have proposed a method to calculate the large deformation of the thin rod by a relatively small amount of calculation by integrating the geometrical shape analysis methods.
[0044]
In this method, the shape to be followed by the thin bar can be expressed by the following expression by paying attention to a minute section. In the following description, the vector is represented by a bold line in the present embodiment, and is represented by an upper bar in the drawing.
[0045]
・ Relationship between the position on the center line of the thin bar and the tangential direction at that position
w = r / ds (r ′) (1),
In the above equation (1), r is a position from the predetermined reference point O on the center line of the thin bar. s is a distance (length) measured along the center line from the starting point of the thin bar. W represents a tangential direction representing the direction of the thin bar at the position. In the following description, the minute change (differentiation) d / ds of s is represented by “′”.
[0046]
・ Relationship between curvature ρ and direction change:
u ′ = ω × u, v ′ = ω × v, w ′ = ω × w, ω = pu + qv + rw (2),
In the above equation (2), p is a curvature in the u direction, q is a curvature in the v direction, and r is a torsional curvature around w. u and v are coordinate system vectors combined with w.
[0047]
・ Relationship between curvature ρ and moment:
M _u = A ・ p, M _v = B · q, M _w = C · r (3),
In the above equation (3), A and B are bending stiffness values. C is a torsional rigidity value. M _u , M _v , M _w Are the u, v, and w direction components of the moment M.
[0048]
-Relational expression of balance between force F and moment M:
M _{(d + ds)} -M _s + Mds + {w × F} ds = 0,
F _{(d + ds)} -F _s + Fds = 0 (4),
In the above equation (4), m is a self-moment. F is a force acting on the distance s from the starting point of the thin bar. f is the weight of the thin rod.
[0049]
In each of the above formulas, if the numerical analysis is performed by giving the position and tangent direction of the end points of the thin bar as boundary conditions, the shape, force F, and moment M of the center line of the thin bar can be calculated.
[0050]
Next, values to be substituted into the relational expression in order to calculate the shape of the wire harness using the above-described relational expression of Kanapaso will be described.
[0051]
<Relation formula of bending stiffness E>
When each relational expression of the above elastic body model is applied to the wiring design of the wire harness illustrated in FIG. 1, the thickness varies depending on the portion of the target wire harness as described above. E is also different. Therefore, in the present embodiment, the following biquadratic functions relating to the curvature ρ described below are employed when the respective relational expressions of the elastic body model are employed in the calculation of the shape of the wire harness.
[0052]
Flexural rigidity E (N · cm ² ) = F (φ, ρ) = G (a ₀ (Φ) + a ₁ (Φ) ρ + a ₂ (Φ) ρ ² ) × K, (5),
In the biquadratic function of equation (5) above,
a ₀ (Φ) = 5.76φ + 1.04φ ² ,
a ₁ (Φ) = − 0.28φ−0.0559φ ² ,
a ₂ (Φ) = 0.0047φ + 0.000638φ ² ,
Each coefficient is a value empirically obtained based on experiments. Φ is the diameter (mm) of the wire harness. ρ is curvature (1 / mm) × 10 ^Three The two fixed positions (coordinate values) set are determined according to the shape in the length direction of the wire harness so that both ends of the target wire harness satisfy the two fixed positions (coordinate values). G is the acceleration of gravity (≈9.8) (m / sec ² ). K is a coefficient (≦ 1.0) determined according to the type of the protective member.
[0053]
In the relational expression of the bending rigidity E, a ₀ (Φ) to a ₂ Each formula of (φ) is an equation obtained empirically based on an experiment by the applicant of the present application for a plurality of types of wire harnesses having different thicknesses, the number of electric wires, or the presence or absence of a protective material, The value of the bending stiffness E calculated by the biquadratic function of equation (5) decreases as the curvature ρ of the target wire harness increases.
[0054]
In the present embodiment, the bending stiffness E calculated by the equation (5) is commonly used as the bending stiffness values A and B included in the above equation (3). Here, the reason will be described. The above equation (3) includes the bending stiffness values A and B because the equation (3) indicates the directionality of the bending property of the elastic body model (for example, a material having an elliptical cross section is a long axis) This is because, for example, the characteristics are hard in the direction and soft in the short axis direction, etc., if the number of wires bundled inside is the same as in this embodiment, bending rigidity and torsion When handling a wire harness that can be regarded as having substantially the same rigidity, it is not necessary to strictly consider the direction of bending.
[0055]
<Torsional rigidity value C>
Note that the torsional stiffness value C to be substituted into the above equation (3) can be calculated by a higher order equation based on the thickness (diameter) of the wire harness. Based on the experimental values, a quadratic relational expression including a coefficient calculated by a method such as multivariate analysis is adopted. However, since this method itself is general, detailed description thereof is omitted.
[0056]
<Weight of wire harness>
The weight per unit length of the wire harness varies depending on the type and number of electric wires (wires) bundled inside the wire harness. In addition, if the use of the wiring harness and the electrical components of the connection destination are limited to some extent (for example, calculating the shape of the wiring harness disposed in the engine room of the automobile), the wire harness to be used Since the type and the number of wires to be bundled can be limited, variations in the type and number of wires can be considered by replacing the thickness (diameter) of the wire harness. Therefore, in the present embodiment, the relationship between the thickness and the weight per unit length is measured in advance for the variation of the wire harness, and the thickness of the wire harness whose shape is to be obtained is determined by the operator using the measurement result. If input, the weight per unit length of the wire harness is automatically selected. Alternatively, as described above, once the electrical component to be connected is determined, the wire harness to be used can be limited. Therefore, the operator selects the use of the wire harness whose shape is to be determined and the electrical component to be connected. The weight per unit length of the wire harness to be selected may be automatically selected.
[0057]
<Wiring design support device>
Here, the configuration of the wiring design support apparatus according to the present embodiment, in which the wiring shape of the wire harness is calculated according to the procedure described later using the above-described values and relational expressions, will be described.
[0058]
FIG. 12 is a block configuration diagram of the wire design support apparatus for the wire material according to the present embodiment.
[0059]
In the figure, 22 is a display such as a CRT, and 23 is a keyboard as input means. A ROM 24 stores a boot program and the like. Reference numeral 25 denotes a RAM that temporarily stores various processing results. Reference numeral 26 denotes a storage device such as a hard disk drive (HDD) that stores a program for calculating the wiring shape of the wire harness as will be described later. Reference numeral 27 denotes a communication interface for communicating with an external device via the communication line 30. Reference numeral 28 denotes a printer for printing processing results and the like. These components are connected via an internal bus 29, and a CPU (central processing unit) 21 controls the entire wiring design support device according to a program stored in a storage device 26.
[0060]
As the wiring design support device for the wire material, a general-purpose software capable of executing software that realizes a wiring shape calculation process of a wire harness, which will be described later (consisting roughly of a basic shape calculation process and a balanced shape calculation process). A computer can be used.
[0061]
<Basic shape calculation process>
Next, a process for calculating the shape of one wire harness having the same thickness (diameter) whose both ends should be fixed at a predetermined position (including the case of a free end) using the above-described relational expressions will be described. To do. This processing (hereinafter referred to as basic shape calculation processing) is performed in the wiring design support apparatus shown in FIG. 12, as will be described later, for shape simulation during wiring of a wire harness having branches and different thicknesses of each part, This is a basic process when the recalculation is repeated until each part is mechanically balanced.
[0062]
FIG. 6 is a diagram for explaining the shape of one wire harness calculated in the basic shape calculation process according to the present embodiment and the parameters to be input by the operator in order to calculate the shape.
[0063]
FIG. 7 is a flowchart showing basic shape calculation processing in the present embodiment.
[0064]
In the figure, Step S1: The operator is prompted to input various predetermined data for basic shape calculation. Specifically, input of data for the following items is required.
1: Thickness (diameter) φ (mm) of the wire harness to be processed
2: Coordinate value in the global coordinate system of the fixed position 1 with respect to the external interference surface of the wire harness to be processed,
3: Tangent direction 1 representing the fixed direction at the fixed position 1,
4: Normal direction 1 representing the direction of the fixed position 1 (may be automatically calculated according to the input tangential direction 1),
5: Coordinate value in the global coordinate system of the fixed position 2 with respect to the interference surface outside the wire harness to be processed,
6: Tangent direction representing the fixing direction at the fixed position 2, 2,
7: Normal direction 2 indicating the direction of the fixed position 2 (may be automatically calculated according to the input tangent direction 2),
8: Type of protective member (tape etc.) that covers the wire harness to be processed,
9: Length L (mm) of the wire harness to be processed (if the automatically calculated length is adopted, it is not necessary to input)
10: Designation of whether or not to calculate the shape in consideration of the twist (moment) generated in the wire harness by fixing the wire harness to be processed at the fixing positions 1 and 2 (by this basic shape calculation processing) Multiple input basic shapes (input when calculating the balance shape described later by connecting multiple wire harnesses),
11: Types of fixing members (including free ends representing branches) used when fixing the wire harness to be processed at the fixing positions 1 and 2;
As a method of inputting the coordinate values of the fixed positions 1 and 2, the data of the interference surface (wire frame model, solid model, etc.) designed in advance in another process is read in this step and displayed on the display 22. At the same time, a desired position on the displayed model may be selected with a pointing device such as a mouse, or a coordinate value may be directly input.
[0065]
Further, the value of the protective member K described above is stored in advance in the storage device 26 according to the type of the protective member, and the coefficient K to be used is determined by selecting the type of the protective member in this step. It is determined.
[0066]
Furthermore, the storage device 26 stores in advance the thickness of the wire harness determined according to the number of wires bundled as one wire harness, and the number of wires to be bundled in the wire harness to be processed in this step. By making the selection, the diameter of the wire harness may be automatically determined.
[0067]
Further, the storage device 26 stores in advance a table representing the degree of freedom of each fixing member described with reference to FIG. 4 as a constraint condition, and either one of the fixed positions 1 and 2 is determined in this step. When the member is selected by the operator, the wiring design support apparatus can recognize the degree of freedom of each fixed position.
[0068]
Step S2, Step S3: The data of each item input in Step S1 is subjected to general validity checks (Step S2) such as confirmation of the number of input items and confirmation of the number of digits, and then the CPU 21 It is read into the main memory (step S3).
[0069]
Step S4: The bending rigidity E is calculated by substituting the thickness of the wire harness to be processed input (or determined) in Step S1 and the selected coefficient K into the relational expression (5) described above. To do. At this time, efficient calculation is realized by using the maximum curvature of the wire harness to be processed as the curvature ρ to be substituted.
[0070]
Furthermore, in step S4, the weight per unit length of the wire harness to be processed is calculated. In calculating the weight, the relationship between the thickness of the wire harness and the weight per unit length is stored in advance as a lookup table in the storage device 26 or the like, and the lookup table is input in step S1. What is necessary is just to obtain | require by referring according to thickness. Then, as described above, the torsional rigidity value C is calculated by substituting the diameter of the wire harness input in step S1 into a quadratic expression empirically obtained through experiments.
[0071]
Step S5: Substituting the tangent direction and normal direction at the fixing positions 1 and 2 of the wire harness to be processed input in Step S1 and the values calculated in Step S4 into the above-described kanapaso relational expression. Thus, the shape as the elastic body model when the wire harness is fixed at the fixing positions 1 and 2 and the force F and the moment M generated therein are calculated.
[0072]
Step S6: The data of the predetermined items input in step S1, and the force F and moment M calculated in step S5 are stored in the storage device 26. More specifically, at least the thickness φ of the wire harness, the calculated (or input) length L, the normal direction vector of the fixed positions 1 and 2, and the twist representing the twist amount between these two locations. The rate (m / radian) and the calculated force F are saved (all input data may be saved).
[0073]
Step S7: The calculated shape (basic shape) of the wire harness to be processed is displayed on the display 22, and the force F applied to the fixed positions 1 and 2 is displayed as a vector representing the magnitude and direction of the force.
[0074]
FIG. 13 is a view showing a display example of the shape and force F of the wire harness calculated in the basic shape calculation process according to the present embodiment. In the wire harness shown in FIG. The fixing position 2 shown on the lower side shows a case of a fixing clip. From each fixing position, the magnitude of the force generated at the fixing positions 1 and 2 by bending the wire harness bent in the shape shown in FIG. The direction is displayed.
[0075]
According to the basic shape calculation process described above, the resultant force F generated in the calculated basic shape is displayed, so that the operator can determine the direction and magnitude of the force necessary to fix the fixing member such as the connector, The positional relationship with the interfering object can be easily recognized visually, and support at the time of design can be improved.
[0076]
FIG. 14 is a diagram showing a comparative example of the shape of the wire harness calculated in the basic shape calculation process according to the present embodiment and the shape of the wire harness calculated by a general CAD system. It can be seen that the shape of the wire harness by the system is an unnaturally twisted shape as compared with the shape of the wire harness according to the present embodiment because bending rigidity and its own weight are not considered.
[0077]
<Balance shape calculation process>
Next, a process of calculating a mechanical balance shape when the wire harness whose shape has been calculated by the basic shape calculation process described above is fixed at its end (including the case of a free end) (hereinafter referred to as balance shape calculation). Processing) will be described.
[0078]
First, when the wire harness whose shape is calculated in the basic shape calculation process described above is arranged in the three-dimensional space of the global coordinate system, the force and moment generated at the end of the wire harness (fixed position 1 or 2) are as follows: F _i , M _i It is represented by
[0079]
Moreover, when a certain edge part is comprised with the several wire harness and comprises the branch point, the resultant force and moment which generate | occur | produce at the branch point are calculated | required by the following calculations as a general formula.
[0080]
Force F = ΣF _i ... (6),
Moment M = ΣM _i ... (7),
Next, the balance conditions at the ends of the wire harness having the above-described dynamic relationship will be described.
[0081]
In the case of a branch point (free end): the resultant force F and the resultant moment M calculated by the above formulas (6) and (7) are both zero.
In the case of a rotating clip: the moment component obtained by projecting the resultant moment M calculated by the above equation (7) onto the rotation axis (ie, normal direction) of the rotating clip is zero.
In the case of the above-described rotating clip, it is constrained so that the shaft can rotate. Similarly, when the end point is a connector or a fixing clip, it is constrained with a degree of freedom of 0, so there is no need to consider the balance condition.
[0082]
Here, the dynamic relationship in the case of a branch point where a plurality of wire harnesses are connected will be specifically described with respect to the above-described dynamic balance relationship.
[0083]
FIG. 8 is a diagram illustrating the shape of a wire harness having a branch that is a target of the balance shape calculation process in the present embodiment.
[0084]
The wire harness shown in the figure is, as an example, a wire harness having one branch point Pa that is selected by the operator as an object of the balanced shape calculation process. For example, in the wire harness, the branch harness Pa is a boundary. Five wires are bundled inside the left wire harness, and on the right side at the branch point Pa, a wire harness in which two wires are bundled, and a wire harness in which three wires are bundled, Goodbye
[0085]
The operator calculates a plurality of basic shapes constituting the wire harness prior to performing the balanced shape calculation process on the entire wire harness. That is, the wire harness illustrated in FIG. 8 is formed by connecting five wire harnesses (wire harnesses 1 to 5) calculated as basic shapes by the basic shape calculation process. Here, if the structure of the wire harnesses 1 to 5 is described,
Wire harness 1: A wire harness in which the fixing position 1 is a connector 11A and the fixing position 2 is a clip 13B (fixed clip or rotating clip).
Wire harness 2: The fixed position 1 is a clip 13B (fixed clip or rotating clip), the fixed position 2 is a wire harness at a branch point Pa, and is protected by a protective member 14.
Wire harness 3: The fixed position 1 is a branch harness Pa and the fixed position 2 is a wire harness of the connector 11B.
Wire harness 4: The fixing position 1 is the branch point Pa, and the fixing position 2 is the clip 13C (fixed clip or rotating clip).
Wire harness 5: The wire harness of the clip 13C at the fixed position 1 and the connector 11C at the fixed position 2.
[0086]
FIG. 9 is a diagram for explaining the forces and moments generated in the wire harnesses 2 to 4 constituting the branch point Pa included in the wire harness shown in FIG. Although the end points of the wire harnesses 2 to 4 shown in the figure are actually connected at the branch point Pa that is the same position, they are represented separately for convenience of explanation and illustration.
[0087]
At the branch point Pa shown in FIG. 9, the force F is applied to the fixing position 2 of the wire harness 2. _Three And moment M _Three Is generated, and the force F is applied to the fixing position 1 of the wire harness 3. ₁ And moment M ₁ Is generated, and the force F is applied to the fixing position 1 of the wire harness 4. ₂ And moment M ₂ Has occurred. These forces and moments are values obtained by the basic shape calculation process for the wire harnesses 2 to 4.
[0088]
Here, considering the case of FIG. 9 by applying the above formulas (6) and (7), the resultant force F at the branch point Pa is the force F ₁ , Force F ₂ And force F _Three Is obtained by adding the vectors. The moment M at the branch point Pa is the moment M ₁ , Moment M ₂ And moment M _Three Is obtained by adding the vectors.
[0089]
Then, in order for the branch point Pa from which the resultant force and the resultant moment can be calculated by such calculation to form a certain shape in which a dynamic balance is established, the position of the branch point Pa arranged in the three-dimensional space of the global coordinate system. Is obtained (placed) at a position where the calculated resultant force F and resultant moment M are both zero.
[0090]
In addition, when the above-described dynamic balance shape is applied to the rotating clip, the direction (direction) of the rotating clip fixed on the rotating shaft is calculated by calculating the calculated moment and the moment component projected onto the rotating shaft is zero. Obtained by rotating until.
[0091]
In order to calculate a position (or orientation) that satisfies the above-described balance condition, a method for calculating an optimum value (optimum solution) that is generally performed by computer processing can be employed. That is, when applied to the present embodiment, for example, the resultant force and moment are calculated for a shape obtained by a certain basic shape or a combination of a plurality of basic shapes as described above, and whether or not the calculation result satisfies the condition. Determine whether. If not satisfied, rotate or move the target end (free end) by a predetermined amount, recalculate the basic shape at the new position after the rotation or movement, and use the new basic shape. The resultant force and moment are calculated again as described above, and it is determined whether or not the calculation result satisfies the condition. While repeating such a process, if the calculation result is determined to be the reverse of the previous determination at a certain point, rotate or move the end (free end) in a direction opposite to the previous, a small amount, Processing such as repeating the same processing may be performed until the condition is satisfied.
[0092]
Next, the procedure of the balanced shape calculation process that realizes the above description will be described.
[0093]
FIG. 10 is a flowchart showing a balanced shape calculation process in the present embodiment.
[0094]
In the figure, Step S11: The operator is prompted to input various predetermined data for calculating the balance shape. Specifically, input of data for the following items is required.
1: Designation of the basic shape for calculating the balance shape, or the shape of the wire harness consisting of multiple basic shapes,
2: Type data (fixed position identification data for rotating clips, free ends, etc.)
The fixed position type data may be read together with the shape data if already set in each basic shape calculation process.
[0095]
Steps S12 and S13: The data of each item input in step S11 is subjected to general validity checks (step S12) such as confirmation of the number of input items and confirmation of the number of digits, and then the CPU 21 It is read into the main memory (step S13).
[0096]
Step S14: The wire harness specified in Step S11 is read in Step S13 (based on the above formulas (6) and (7) based on the force and moment at the fixed position and branch point (free end)) The resultant force F and the resultant moment M are calculated.
[0097]
Step S15: Whether or not the resultant force F and the resultant moment M calculated in Step S14 satisfy the above-described predetermined balance condition is determined based on all end portions (fixed points and fixed points) included in the wire harness input in Step S11. Judge for free end).
[0098]
Step S16: When the determination in step S15 is NO (when there is an end portion that does not satisfy the predetermined balance condition), the process proceeds to step S16, and when YES (all end portions satisfy the predetermined balance condition) ), The process proceeds to step S18.
[0099]
Step S17: Each end point (fixed point and free end) is moved and rotated by a predetermined amount in the direction of the resultant force F and the resultant moment M calculated for the end point based on the restriction of the predetermined balance condition.
[0100]
Step S18: Based on the position of each end point (fixed point and free end) after movement and rotation, the force generated at the shape and the end is recalculated, and the process returns to step S14. At this time, the shape recalculation may be performed by calling the processing after step S4 of the basic shape calculation processing (FIG. 7).
[0101]
Step S19: A shape (balanced shape) in which each end point satisfies a predetermined balance condition is displayed on the display 22, and a force F applied to each end point is displayed as a vector representing the magnitude and direction of the force. At this time, when the force applied to the connector and the fixing clip is larger than a predetermined value set in advance, processing such as changing the color of the vector to be displayed or displaying characters etc. is performed to notify that effect. Thus, the operator can easily recognize that an excessive force is applied to a fixed position (end point) having zero degrees of freedom.
[0102]
FIG. 15 is a diagram illustrating a display example of the shape of the wire harness and the force F calculated in the balanced shape calculation process according to the present embodiment.
[0103]
The wire harness shown in the figure shows only one end of the wire harness having a branch point because of the size that can be illustrated, and the magnitude and direction of the generated force are displayed at each fixed position. ing.
[0104]
Step S20: When a branch point is included in the wire harness specified in step S11, the breaking force at the branch point is displayed.
[0105]
FIG. 11 is a diagram for explaining the display of the breaking force at the branch point. When the balance condition is satisfied at the branch point, the two wire harnesses having narrower branch destinations are respectively generated at the branch point. Force F ₁ And F ₂ Is added to the vector, and the result is displayed as an arrow or numerical value. In the case of the example shown in FIG. ₁ Is F ₂ Since it is considerably larger, the breaking force and the numerical value representing the result of the vector addition are displayed on the upper wire harness at the branch destination. As a result, the operator can easily predict that a break may occur at the branch point when the calculated break force is too large although the branch point is mechanically stationary. .
[0106]
According to the balance shape calculation process described above, the optimum balance shape is automatically calculated and the magnitude of the force generated at each end is displayed, so the operator fixes a fixing member such as a connector. Therefore, it is possible to easily visually recognize the direction and magnitude of the necessary force and the positional relationship with the surrounding interference object, and to improve the supportability at the time of design.
[0107]
Further, according to the balance shape calculation process described above, in a so-called concurrent engineering environment where design work is performed in parallel in each department, the final shape of the interference surface cannot be obtained from the design department in the previous process (that is, the product Even if you can only obtain a low-precision shape model that does not have the details of the shape), use the interference surface shape (or coordinate values) that you have obtained for the time being to grasp the desired wire harness balance shape. Design efficiency.
[0108]
In addition, if it becomes necessary to change the wire material to be used, the presence or absence of protective material, the type of clip, etc., at a later date, depending on the specification change that occurred in the design department of the previous process, the change By re-entering the setting items related to the above and recalculating the basic shape and the balance shape described above, it is possible to respond flexibly and quickly to the generated specification change.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an overall shape of a wire harness to be designed in the present embodiment.
2 is a diagram illustrating a cross-sectional shape of the wire harness shown in FIG. 1;
FIG. 3 is a diagram illustrating the shape of a rotating clip that holds a wire harness to be designed in the present embodiment.
FIG. 4 is a diagram showing a list of types of support members and their degrees of freedom to be handled in the calculation of the shape of the wire harness according to the present embodiment.
FIG. 5 is a diagram for explaining a vector expression of an elastic body model employed in the present embodiment.
FIG. 6 is a diagram for explaining the shape of one wire harness calculated in the basic shape calculation process according to the present embodiment and parameters to be input by the operator in order to calculate the shape.
FIG. 7 is a flowchart showing basic shape calculation processing in the present embodiment.
FIG. 8 is a diagram illustrating a shape of a wire harness having a branch that is a target of a balanced shape calculation process in the present embodiment;
9 is a diagram for explaining forces and moments generated in the wire harnesses 2 to 4 constituting the branch point Pa included in the wire harness shown in FIG. 8. FIG.
FIG. 10 is a flowchart showing balanced shape calculation processing in the present embodiment.
FIG. 11 is a diagram illustrating display of breaking force at a branch point.
FIG. 12 is a block configuration diagram of a wire design support apparatus for a wire material according to the present embodiment.
FIG. 13 is a diagram showing a display example of the shape and force F of the wire harness calculated in the basic shape calculation process according to the present embodiment.
FIG. 14 is a diagram showing a comparative example of the shape of the wire harness calculated in the basic shape calculation process according to the present embodiment and the shape of the wire harness calculated by a general CAD system.
FIG. 15 is a diagram showing a display example of the shape and force F of the wire harness calculated in the balanced shape calculation process according to the present embodiment.
[Explanation of symbols]
11 ,: Connector,
12, 12A-12C: electrical equipment,
13, 13B, 13C: Clip,
13A: rotating clip,
14, 16: protective material,
15: Electric wire,
17: wire harness,
18: Base,
21: CPU,
22: Display
23: Keyboard
24: ROM,
25: RAM,
26: storage device,
27: Communication interface,
28: Printer,
29: Internal bus,
30: communication line,

Claims (13)

This is a wire design support device for wire rods that includes a calculation means for calculating and notifying the wire shape of the wire rods satisfying the fixed positions based on a plurality of input fixed positions and the deformation coefficients of the wire rods. And
The calculating means calculates a force applied to the plurality of fixed positions by the wire material when calculating a wiring shape of a target wire material, and notifies information on the calculated force. Wiring design support device for wire material. 2. The wire material wiring design support apparatus according to claim 1, wherein the calculation means notifies the magnitude and direction of the force as information on the force. The line according to claim 1, wherein when the information about the force is notified, the arithmetic unit warns that if the predetermined design strength is exceeded as a design strength at the fixed position. Wiring design support device for strips. The wire design of a wire rod according to claim 1, wherein the calculation means can specify the degrees of freedom at the fixed positions as input items of the plurality of fixed positions with respect to the target wire rod. Support device. The calculation means can designate whether or not the wire rod can be rotated around the normal direction at the fixed position as the degree of freedom at the fixed position,
When the fixed position is designated to be rotatable, a force that the linear member tries to rotate around the normal direction is calculated as a force applied to the fixed position by the linear member. Item 1. A wire design support device for a wire material according to item 1. The calculation means calculates the bending rigidity E of the target wire rod based on the input wire rod diameter φ by a predetermined biquadratic function relating to the curvature ρ of the wire rod, and the calculation 6. A wire material wiring design support apparatus according to claim 1, wherein the wire shape of the wire material is calculated using the bending rigidity E. Based on a plurality of fixed positions and the deformation coefficient of the line material, it is a wiring design support method for the line material that calculates and notifies the wire shape of the line material that satisfies the fixed position,
When calculating the wiring shape of the target wire material, the wire material calculates the force applied to the plurality of fixed positions by the wire material, and informs the information about the calculated force Wiring design support method. The wiring material design support method for a wire material according to claim 7, wherein as the information on the force, the magnitude and direction of the force are reported. The wiring design of the wire material according to claim 7, wherein when the information on the force is notified, if a predetermined value set in advance as a design strength at the fixed position exceeds a predetermined value, a warning is given to that effect. Support method. As an input item of the plurality of fixed positions for the target wire rod, it is configured to be able to specify whether or not the wire rod can be rotated around the normal direction at the fixed position,
When the fixed position is designated to be rotatable, a force that the linear member tries to rotate around the normal direction is calculated as a force applied to the fixed position by the linear member. Item 8. A wire design support method for a wire material according to Item 7. The wiring shape of the target wire rod is calculated by a predetermined biquadratic function relating to the curvature ρ of the wire rod based on the input wire rod diameter φ based on the input wire rod diameter φ. 11. The wire material design support method according to any one of claims 7 to 10, wherein the calculation is performed using the calculated bending stiffness E. A computer-readable storage medium storing program code for operating a computer as the wire design support device for a wire material according to any one of claims 1 to 6. 12. A computer-readable storage medium storing a program code capable of realizing the wire design support method for a wire material according to claim 7 by a computer.

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