JP4754460B2 - Vehicle wheel - Google Patents

Description

  The present invention relates to a vehicle wheel for automobiles, agricultural vehicles, industrial vehicles and the like, and more particularly to a vehicle wheel in which a disk is fitted and welded to a drop portion of a rim.

In recent years, vehicle wheels are required to improve handling stability and NVH (noise and vibration) in addition to strength, weight, cost, and the like. Steering stability and NVH are said to be related to wheel rigidity. For example, if the wheel rigidity is low, the response of the steered wheels to the steering operation is delayed and steering stability is lowered. In general, when the torsional rigidity of the disk surface is low, the natural frequency of the torsional mode is low, which resonates with the air column resonance frequency of the tire and is disadvantageous to NVH.
As a technique for reducing the weight of a vehicle wheel by improving the wheel rigidity, a wheel is disclosed in which a curved portion is formed on the inner slope in the radial direction in the hat portion of the disk so as to increase the wheel rigidity. (See Patent Document 1). Also, by omitting the disc's hat (projection ring) and providing a dimple-shaped ridge-shaped bent portion in the disc design portion consisting of an annular region outside the hub mounting portion, the rigidity is ensured and the design is improved. An improved wheel is disclosed (see Patent Document 2).
On the other hand, as a steel wheel, a wheel having a two-piece structure in which a disk and a drop portion of a rim are joined by welding is widely used. For example, as shown in FIG. 8, this type of wheel is formed by folding the outer edge of the steel disk 100 and extending inward along the axial direction to form a flange 100 a, and the flange outer surface is the inner surface of the drop portion 20 c of the rim 20. Are manufactured by arc welding the insides of the fitting portions 50 of both (see Patent Document 3).

JP 2001-180202 A JP 2006-082333 A Japanese Patent No. 3460764

However, in the case of the conventional vehicle wheel described above, it cannot be said that the wheel rigidity is sufficiently secured, and increasing the thickness of the disk or rim increases the wheel rigidity, but increases the weight and cost of the wheel. Problem arises.
Further, the technique described in Patent Document 2 is a wheel in which the hat portion is eliminated and the rigidity is improved by dimples or the like, but there are problems such as having a peculiar appearance and likes and dislikes and changing the design.

  The present invention has been made to solve the above-described problems, and in a vehicle wheel formed by fitting and welding a disc to the outside of a drop portion of a rim, the wheel rigidity is improved by optimizing the disc shape. An object of the present invention is to provide a vehicle wheel that can reduce the weight of the wheel and can further improve the design of the wheel design surface.

In order to achieve the above object, a vehicle wheel according to the present invention includes a rim having a drop portion whose diameter decreases from an outer side wall portion through a curved portion, and a flange formed by folding an outer edge inward along the axial direction. have a steel, titanium, or a disk made of a titanium alloy, it was fitted welding the outer peripheral surface of the outer inner peripheral surface of the drop portion flange outwardly from the surface of said disk A convex curve that forms a rising surface at a portion from the center side of the disk toward the outer diameter side when viewed from a cross section passing through the center of the disk, and having a hat portion that protrudes and forms a ring concentric with the disk. a hat portion inner surface of one of the straight lines or concave curves connected by the standing up surface and the inflection point P _1, the top portion consisting of convex curve having a predetermined curvature to connect directly with the hat portion inner and inflection point P ₂ , And a hat portion outer surface drops toward the said top to the outside of the disc, the distance d of the distance d _H between the center of the disc to the top of the hat portion, from the center of the disc to the outer periphery of the flange between the _max, characterized in that there is relationship _{0.65 ≦ d H / d max ≦} 0.80.
From the result of FEM analysis, in the range of 0.65 ≦ d _H / d _max ≦ 0.80, the wheel rigidity is improved as compared to the other range (for example, a conventional wheel of about d _H / d _max = 0.60). Therefore, the disk can be thinned to reduce the weight, and the hat is positioned on the outer peripheral side of the disk, so that the design of the wheel cap is improved. Furthermore, the reduction in wheel rigidity due to the reduction in the height of the disc hat can be compensated, and the height of the hat can be reduced while maintaining the wheel rigidity, and the design freedom of the wheel cap is also improved.

The inflection point is the height of the P ₁ is less 20.0mm from the hub mounting surface, and the hat portion inner surface, and a straight line Ru respectively through the P ₁ and P ₂ and a is represented by 1.42x10 ^-2 / mm It is preferable that the curve is a smooth curve existing in a region sandwiched between circular arcs having a certain curvature.
From the result of the FEM analysis, the wheel rigidity is improved as compared with the case of the curve existing outside the region.

  According to the present invention, in the vehicle wheel formed by fitting and welding the disc to the outer side of the drop portion of the rim, by optimizing the disc shape, it is possible to improve wheel rigidity and reduce the weight of the wheel. The design of the wheel and wheel cap can be improved.

Hereinafter, embodiments of the present invention will be described. In the following description, a steel wheel is exemplified, but in the present invention, in addition to the steel wheel, a material that can be formed into a disk by forming the flange by folding the outer periphery of the plate material by drawing or the like (for example, titanium, titanium alloy) Can be targeted.
Moreover, it is preferable that the wheel according to the present invention satisfies the official definition of durability. However, the present invention can be applied to an industrial vehicle (agricultural) wheel or an emergency wheel (including an automobile temper wheel) that does not have an official durability strength regulation.
Here, the official endurance strength is JIS D 4103 “Auto Parts-Disc Wheel-Performance and Display” in Japan. If the standard changes in the future, the Japanese Industrial Standard JIS (and / or Refers to the official durability of a wheel determined by the International Organization for Standardization (ISO).
There is no official standard such as JIS for wheel rigidity, but due to its importance, each automobile manufacturer defines its test method and standard value. When the standard values of car manufacturers are converted to each other, they are almost equivalent. In the present invention, a rigidity test method using a “rotary bending endurance test” specified in JIS D 4103 is employed.

FIG. 1 is a sectional view showing an example of a vehicle wheel according to an embodiment of the present invention (cut along a plane parallel to the axis of the wheel). This vehicle (steel) wheel is formed by fitting a steel rim 2 and a steel disc 10 to the outside of a drop portion of the rim and welding them.
In the following description, “outside” refers to a portion that is on the outside when the wheel is mounted on the vehicle, and “inside” refers to a portion that is on the inside. However, when two wheels are connected in the axial direction, such as a double tire on a truck, the “outer side” and “inner side” of the wheel located inside are as described above, but located outside. The “outside” and “inside” of the wheel are reversed. This is because in the case of a double tire, the front and back of the wheel located on the outside is reversed and connected to the inner wheel. For example, in the case of the inner wheel, the upper part of FIG. 1 is the outer side, but in the case of the outer wheel, the lower part of FIG. 1 is the outer side.
Further, the radial direction of the rim and the disk is expressed as “inner peripheral surface” or “outer peripheral surface”.

1) Rim The rim 2 has a substantially cylindrical shape and accommodates a tire between an outer flange and an inner flange formed at both ends thereof. An outer bead sheet for receiving the tire bead is formed inside the outer flange. The drop part 2c having the smallest diameter is formed inside the outer bead sheet, and the outer bead sheet and the drop part (outer part) 2c are smoothly connected via the sidewall part 2a. The drop part 2c and the sidewall part 2a are connected via a curved part 2b having a semicircular cross section. An inner bead sheet is formed inside the drop part 2c via a sidewall part, and the inner bead sheet is connected to the inner flange. In the following description, the “drop portion” refers to the outer portion of the drop portion (the portion connected to the outer bead sheet).
The rim 2 can be produced, for example, by rolling a rolled shape steel having a predetermined shape into a cylindrical shape, or after rolling a steel plate into a cylindrical shape, it may have a predetermined cross-sectional shape by roll forming or the like. It is not limited to the method.

2) Disc The disc 10 has a substantially disk shape, a hub hole 10d is opened at the center, and a bolt hole 10e for attaching the hub to the outer peripheral side from the hub hole is formed.
The outer edge of the disk is folded inward along the axial direction to form a flange 10a, and the flange 10a reaches the flange end edge 10b.
The disk 10 can be formed by drawing (pressing) steel plates punched into various shapes. The punching shape is not particularly limited. In general, for example, 1) a square steel plate simply punched into a disk, 2) a square steel plate with four corners punched into a circle, 3) 2) Furthermore, the thing punched in circular arc shape also at the center part of each edge | side is mentioned. Among these, 1) is a shape in which a so-called drain hole is not formed, 2) and 3) are shapes in which a drain hole is formed, and any shape disk may be used, but in the case of 2) as an example In other words, the four corners of a square steel plate can be punched into a circular shape and drawn (pressed) to form the disk 10 (see FIG. 3 of Patent Document 3). In this case, the portion of the steel plate that is punched into a circle becomes the flange edge 10b of the disk, and the other portion of the steel plate becomes the recess 11 to form a drain hole.

  A hat portion 12 protrudes outward from the surface of the disk 10. The hat portion 12 has an annular shape concentric with the disk 10 and has a bowl shape (mountain shape) when viewed from the cross section shown in FIG. The hat portion 12 has a top portion 12b, a hat portion inner surface 12a that gently falls in a skirt shape from the top portion 12b toward the center of the disc, and a hat portion outer surface 12c that falls in a skirt shape from the top portion 12b toward the disc outer side. ing. The hat portion inner surface 12a is connected to a disk rising surface 15 that rises outward (upper side in FIG. 1) from the disk surface in the vicinity of the bolt hole 10e. Further, the outer surface 12c of the hat portion is connected to the flange 10a.

State of FIG. 1 (i.e., when viewed from the cross section passing through the center of the disk), the (connection portion between the top portion 12b of the center side and the hat portion of the disk 10) hat portion inner surface 12a is formed of a concave curve C ₁ Yes. Curve C ₁ is connected with convexly curved C ₃ and inflection point P ₁ which constitutes the rising surface 15 located in the portion toward the outer diameter side from the center side of the disc. The curve _{C 1} is connected with the convex curve _{C 2} and the inflection point _{P 2} constituting the apexes 12b.
An inflection point is a point where the curve changes between an upwardly convex state and an upwardly concave state. The tangent drawn at this point is the boundary and one side of the curve is on the other side. And
Here, the distance d _H between the center of the disk 10 to the top 12b, when the distance d _max from the center of the disk 10 to the outer circumference of the flange 10a, if a rim diameter is 14 inches wheel, disc outer diameter (d _max × 2) = 316 mm, hat top diameter (d _H × 2) = 253.5 mm, diameter from disk center to inflection point P ₁ is about 139 mm, height of inflection point P ₁ (disc bottom (= hub height from the mounting surface) to the inflection point P ₁₎ 11.5 mm, hat height (the distance from the disk bottom surface to the hat Buitadaki portion 12b) h1 = 43mm, radius 7mm curve C _2, radius 100mm curve C ₁ (Curvature 1.00 × 10 ⁻² / mm).
The radius 100 mm of the curve C ₁ means an arc having a radius of 100 mm passing through the inflection points P ₁ and P ₂ .

FIG. 2 is a partial front view of the vehicle steel wheel of FIG. In this figure, a recess 11 having a diameter smaller than that of the flange 10a is formed on the outer edge of the disk 10. The recesses 11 are respectively formed at positions obtained by dividing the disk outer circumference circle into four equal parts.
When the innermost portion 10c is located outside the R center of the curved portion, when the disc 10 is fitted to the inner peripheral surface of the drop portion 2c of the rim 2, the recess 10 and the inner peripheral surface of the drop portion 2c are interposed. A gap is formed, which becomes the drain hole 14.

  The hat portion 12 is formed concentrically with the disk, and a plurality of circular decorative holes 10f are opened along the circumferential direction on the outer surface 12c of the hat portion. The decorative hole 10f is usually formed for weight reduction and heat dissipation.

(Range of d _H / d _max )
In the present invention, the d _H and d _max have a relationship of 0.65 ≦ d _H / d _max ≦ 0.80. The reason for this will be described with reference to FIG.
FIG. 3 shows the wheel rigidity when FEM analysis is performed on the wheel having the shape shown in FIG. The FEM analysis was performed by modeling a stiffness test using a “rotary bending durability test” test machine defined in JIS D 4103. The position of the hat portion (d _H / d _max value) on the disk was varied, and the rigidity of the disk was calculated.
The main stress of the disk is calculated as follows in a stiffness test model using a test apparatus (rotary bending durability tester) defined in JIS D 4103. First, the inner rim flange is restrained, and a bending moment is applied to the mounting surface via a load arm attached to the disk surface. When the value of the bending moment is increased from 0 to a specified value, the relationship between the bending angle θ (corresponding to the deflection angle of the central axis and the load arm) θ and the moment M becomes almost linear. The slope of this straight line is called wheel stiffness (wheel stiffness), and its unit is expressed in Nm / rad.
From this figure, it was found that the wheel rigidity was the highest at d _H / d _max = 0.7 to 0.75, and the wheel rigidity was reduced outside this range.
From the above, the present inventors consider that the safety tolerance is 5%, and obtain d _H / d _{max in} which the wheel rigidity is within 95% of the maximum value from FIG. 3, and 0.65 ≦ d _H / d _max ≦ 0.80 was defined as the range.
As a result, according to FIG. 3, in the range of 0.65 ≦ d _H / d _max ≦ 0.80, the wheel rigidity is improved by 10% or more in comparison with the conventional wheel (d _H / d _max = 0.60). it can.
On the other hand, if d _H / d _max is out of the above range, the wheel rigidity cannot be significantly improved as compared with the conventional wheel.

As described above, according to the present invention, since the wheel rigidity is improved, the disk can be thinned to reduce the weight. In the case of the present invention, since the hat is located on the outer peripheral side of the disk as compared with the conventional wheel (d _H / d _max = 0.60), the inner area of the hat portion (circle determined by the radius d _H ) is also increased. The design can be improved by expanding the part that can add a three-dimensional design to the wheel cap.
In addition, when the height of the disc hat is lowered, the wheel rigidity is reduced. According to the present invention, the wheel rigidity is maintained by adjusting d _H / d _max so as to compensate for the reduction of the wheel rigidity. While the height of the hat can be lowered. If the height of the hat is lowered, the design freedom of the wheel cap is improved.

(Hat height)
FIG. 4 shows the wheel stiffness when the hat height in the disk shown in FIG. 1 is variously changed and the FEM analysis is performed by the same method as in FIG.
From FIG. 4, when the hat height was made lower than the hat height (43 mm) in FIG. 1, the wheel rigidity was lowered. Therefore, by adjusting d _H / d _max to improve the wheel rigidity, if the reduction in the wheel rigidity due to the reduction in the hat height is offset, the hat height can be lowered without reducing the wheel rigidity. For example, first, a reduction amount of the hat height is determined, and after determining the reduction amount of the wheel stiffness from the slope of the graph of FIG. 4 (the reduction rate of the wheel stiffness due to the reduction of the hat height), D _H / d _max may be adjusted according to 3 (based on d _H / d _max corresponding to the rigidity of the current disc).

(Hat shape)
Next, a preferable shape of the hat portion will be described. In the present invention, when viewed from the cross-section through the center of the disk, it is preferable to hat portion inner surface 12a (the connecting portion between the top portion 12b of the center side and the hat portion of the disc 10) is a straight line or a concave curve C ₁ . The reason for this will be described with reference to FIG.
Figure 5 is variously changed the curvature of the curve C ₁ in the disk shown in FIG. 1, showing the wheel rigidity in the case of performing FEM analysis in the same manner as in FIG. Incidentally, in this figure, R100 is the radius of the curve C ₁ is shown to be concave in 100mm (same shape as FIG. 1), R100 is convex radius is 100mm curve C ₁ (and FIG. 1 opposite The shape swells upward.
5 that the wheel rigidity when the curve C ₁ is R100 (concave curve) or R1000 (curve substantially near a straight line with the size comparison of the disk) is maximum, decreases wheel rigidity when C ₁ is convex Turned out to be. Further, the wheel rigidity when the curvature of C ₁ is increased (R55) is lowered slightly.

Furthermore, when each point of the graph of FIG. 5 is approximated by a quadratic curve, the equation y = −280630185894 × ² + 25604338000 × + 440057370
It was obtained (y wheel stiffness, x is representative of the radius of the inverse of the curve C _1).
From this equation, generally is as follows was determined curvature of the curve C ₁ for can be secured to the requested wheel is rigid value 4.00 × 10 ⁸ Nmm / rad or more requests (radius of the reciprocal of the curve C ₁₎ It was.
First, when 5% is considered as a variation in the required wheel stiffness value (an error in the analysis value with respect to an actual measurement value of the wheel stiffness value and a disc manufacturing variation) (that is, the wheel stiffness value is 5% larger than the required value). When the value is estimated), the preferable curvature of the curve C ₁ is −5.04 × 10 ^{−3 to} 1.42 × 10 ⁻² / mm. Incidentally, the minus sign of the curvature indicates that the curve C ₁ is convex (shape bulging upward in FIG. 1).
Similarly, when the variation is 7%, the preferable curvature of the curve C ₁ is −3.42 × 10 ^{−3 to} 1.25 × 10 ⁻² / mm, and when the variation is 9%, the preferable curvature of the curve C ₁ is − It became 1.38x10 ^-3 ~1.05x10 ^-2 / mm.

From these things, the curve C ₁ is preferably a circular arc of the curvature. Further, it may be a straight line or a shape close to a straight line instead of a curve. Here, the shape close to a straight line includes a complete straight line as well as a case where the value of the curvature is a very small value, and is good as long as the wheel rigidity is not lowered.
Further, the curve C _1, not a circular arc, or as a smooth curve expressed by high-order function, such as a cubic function. However, tables in the smooth curve comprises a first arc of curvature represented by the inflection point P ₁ and the inflection point P ₂ and the -5.04x10 ^-3 / mm respectively as, 1.42x10 ^-2 / mm It is necessary to exist in a region sandwiched by the second arc of the curvature to be performed. This is because, if the smooth curve exists in a region sandwiched between the first and second arcs, it is possible to substantially ensure the same wheel rigidity as that of the arc of curvature.

(The height of the inflection point _{P 1)}
In the present invention, the height from the hub mounting surface to the inflection point P ₁ is preferably less 20.0 mm. The reason for this will be described with reference to FIG.
Figure 6 is variously changed the height from the hub mounting surface to the inflection point P ₁ in the disc shown in FIG. 1, showing the wheel rigidity in the case of performing FEM analysis in the same manner as in FIG.
From FIG. 6, as the height from the hub mounting surface to the inflection point P ₁ decreases, the wheel stiffness was found to tend to decrease. Based on FIG. 6, when the required wheel stiffness value of 4.00 × 10 ⁸ Nmm / rad or more, which is generally required, is secured and 5% is considered as the variation in the wheel stiffness value, the inflection from the hub mounting surface the height of the point P ₁ is capable of ensuring the required wheel stiffness value equal to or smaller than 20.0 mm, defining the height from the hub mounting surface to the inflection point P ₁ below 20.0 mm.

The present invention can be generally applied to a two-piece structure wheel having a wheel diameter of 12 to 22 inches, preferably a wheel diameter of 13 to 20 inches, more preferably a two-piece structure wheel having a wheel diameter of 13 to 18 inches. It can be suitably applied.
Further, in the two-piece structure wheel of the present invention, the bolt hole pitch circle diameter can be applied to any of the cases defined in Tables 2 and 3 of JIS D 4220 “Mounting method and dimensions of an automotive disk wheel”. However, the pitch is preferably 114.3 mm or less.

Figure 7 is a disk with different shapes FIG. 1 shows a cross-sectional shape of the disk is concave (same shape as FIG. 1) at radius 25mm of the curve C _1. In this figure, only the right part from the center of the disk is shown, but the left part is shown symmetrically with the disk as the center, so the description of the left part is omitted.
FIG. 7 (a) has a hat top 120b, and this top height is high, so it is called a nipple shape. FIG. 7B is called a flat type because it has a flat portion 130d parallel to the disk surface and a hat top portion 130b. In the type shown in FIG. 7B, the rising portion 130e rising from the disk surface near the bolt hole to the outside (upper side in FIG. 7) and the flat portion 130d are connected, and the hat inner surface 130a protrudes outward from the flat portion 130d. .
In the present invention, the “flat portion” means a region on the outer peripheral side from the rising portion 130e rising outward (upper side in FIG. 6) from the disk surface near the bolt hole, and the disk surface from the disk center to the vicinity of the bolt hole is exclude. That is, a flat part may be provided in the vicinity of the bolt hole.

7 (a) and 7 (b) and the disk of FIG. 1 type, the d _H / d _max value is outside the specified range of the present invention (invention product comparison type disk). ), The disk outer diameter (14 inches) and the hat height (43 mm) were the same, and FEM analysis was performed in the same manner as in FIG. The results are shown in Table 1.

As is clear from Table 1, the wheel rigidity of the present invention example (type of FIG. 1) is 4.41 × 10 ⁸ Nmm / rad, and the nipple type (FIG. 7A) has a wheel rigidity of 1.01 × 10 ⁸ Nmm / rad, flat type. wheel stiffness (FIG. 7 (b)) 1.37x10 ⁸ Nmm / rad, wheel stiffness inventions comparison type 3.52 x10 ⁸ Nmm / rad, and the wheel stiffness than either the wheel of the present invention is lowered. From these facts, in order to improve the wheel rigidity, d _H / d _max is 0.65 or more as the position of the top of the hat, and the curvature of the curve C ₁ is 1.42 × 10 ⁻² / mm or less, the inflection point height of P ₁ from the hub mounting surface that is preferably not more than 20.0mm has been found.

It is sectional drawing which shows an example of the steel wheel for vehicles which concerns on embodiment of this invention. It is a front view showing the steel wheel for vehicles concerning the embodiment of the present invention. It is a figure which shows the wheel rigidity at the time of performing FEM analysis about the wheel of the shape shown in FIG. It is a figure which shows the wheel rigidity at the time of performing FEM analysis by changing hat height variously. Variously changing the curvature of the curve C _1, a diagram illustrating a wheel rigidity in the case of performing FEM analysis. The height of the inflection point P ₁ is changed variously, a diagram showing the wheel rigidity in the case of performing FEM analysis. It is a figure which shows the cross-sectional shape of the disc different from FIG. It is sectional drawing which shows the aspect at the time of putting the wheel cap on the conventional steel wheel for vehicles.

Explanation of symbols

2 Rim 2a Outer side wall 2b Curved part 2c (Outside) Drop part 5 Outer part of fitting part 10 Disc 10a (Disc) flange 12 Hat part 12a Hat part inner surface 12b Top part of hat part 12c Hat part outer surface
d Distance from the center of the _H disk to the top of the hat
d _max Distance from the center of the disk to the outer periphery of the flange C ₁ Concave curve C ₂ Top curve C ₃ Curve constituting the rising surface P ₁ Inflection point of the part rising from the center side of the disk P ₂ Located near the top of the hat Inflection point

Claims (2)

Possess a rim having a drop section to be reduced in diameter from the outer side wall portion via a curved portion, a flange formed by folding inwardly along the outer edges in the axial direction, and a disk made of steel, titanium, or titanium alloy A vehicle wheel formed by fitting and welding the outer peripheral surface of the drop part and the outer peripheral surface of the flange,
A hat portion projecting outward from the surface of the disk and having a ring shape concentric with the disk;
When viewed from a cross section passing through the center of the disk, a convex curve that forms a rising surface at a portion from the center side of the disk toward the outer diameter side, and _one connecting the rising surface and the inflection point P1 . a hat portion inner surface consisting of straight or concave curve, a top consisting of a convex curve having a predetermined curvature to connect directly with the hat portion inner surface and the inflection point P _2, the hat portion outer surface from falling toward the said top to the outside of said disk And
There is a relationship of 0.65 ≦ d _H / d _max ≦ 0.80 between the distance d _H from the center of the disk to the top of the hat portion and the distance d _max from the center of the disk to the outer periphery of the flange. A vehicle wheel characterized by the following. The height of the inflection point P ₁ is equal to or less than 20.0mm from the hub mounting surface,
And the hat portion inner surface, and a straight line wherein P ₁ and P ₂ and the Ru respectively through, that it is a smooth curve that exists sandwiched by the area in an arc of curvature represented by 1.42x10 ^-2 / mm The vehicle wheel according to claim 1.

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