JP2014091468A - Aluminum steering knuckle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an aluminum steering knuckle which has high rigidity in spite of being light in weight.SOLUTION: An aluminum steering knuckle 20 includes: a body part 21 which serves as a place to which a wheel support body is mounted; a dumper connecting part 22 which is connected to a dumper; a lower arm connecting part 23 which is connected to a lower arm; a tie rod connecting part 25 which is provided at the tip of an arm 24 formed by being extended from the body part 21 and connected to a tie rod; and a brake caliper installation part 26 in which a brake caliper is installed. The aluminum steering knuckle 20 is further provided with a wall surface 21c which is installed so as to surround the periphery of a plurality of bolt holes 21b and erected on the vehicle body side. The wall surface 21c is formed so as to linearly connect adjacent bolt holes 21b to each other, and formed so that the height of the erected wall surface 21c is approximately equal over the whole circumference of the wall surface 21c.

Description

  The present invention relates to an improvement in an aluminum steering knuckle used in a vehicle.

  A vehicle such as an automobile is usually provided with a friction brake mechanism such as a disc type brake mechanism. The friction brake mechanism generates frictional force between the brake rotor and the friction member by bringing the brake rotor that rotates integrally with the wheel and a friction member such as a brake pad held by the brake caliper into sliding contact with each other. , Brake the rotation of the wheel. In such a friction brake mechanism, the brake rotor usually rotates integrally with the wheel hub, and the brake caliper is coupled to a member that rotatably supports the wheel hub, such as a steering knuckle or an axle carrier (axle housing), by a bolt or the like. ing. The end portion of the support member is generally connected to a suspension arm via a rubber bush or the like, and constitutes a suspension device for a vehicle.

  The components of the suspension system including such a friction brake mechanism are positioned as important safety parts because it is necessary to maintain the safety of the vehicle. For example, for a steering knuckle, a ferrous material is cast or forged. It was common to be manufactured. This is because high rigidity can be easily obtained with an iron-based material.

  On the other hand, for the purpose of improving the fuel efficiency of vehicles, the use of lighter metal materials such as aluminum alloys instead of ferrous materials has also been implemented in recent years for important safety parts that make up vehicles. ing. Specifically, there is a movement to adopt an aluminum steering knuckle in hybrid vehicles that require high fuel efficiency.

  In the case of manufacturing a member such as a steering knuckle using a light weight metal material such as aluminum or aluminum alloy, for example, a conventionally known casting such as gravity casting or inclined gravity casting as disclosed in Patent Document 1 below. The method is adopted.

JP 2011-104613 A

  However, although an aluminum steering knuckle can obtain a very advantageous effect in terms of weight reduction, there is a problem that it is inferior to a steering knuckle using an iron-based material in terms of rigidity. That is, in the conventional technology, there is no technology that can achieve both conflicting effects of improvement in rigidity and weight reduction, and the realization of a technology that can achieve both of these effects has been demanded.

  The present invention has been made in view of the above-described problems existing in the prior art, and its purpose is as high as equal to or higher than the rigidity obtained with iron-based materials while maintaining the characteristics of being lightweight. An object is to provide an aluminum steering knuckle having rigidity.

  The present invention will be described below. In addition, in order to make an understanding of this invention easy, the reference number of an accompanying drawing is attached in parenthesis writing, However, This invention is not limited to the form of illustration by it.

  An aluminum steering knuckle (20) according to the present invention is used in a vehicle and has a substantially circular cavity (21a) and a plurality of bolt holes (21b) arranged around the substantially circular cavity (21a). And a damper connecting portion (22) provided above the main body portion (21) and connected to the damper (2). A lower arm connecting portion (23) provided below the main body portion (21) and connected to the lower arm (3), and extending from the main body portion (21) in either the front-rear direction of the vehicle. A tie rod connecting portion (25) provided at the tip of the arm (24) and connected to the tie rod (5), and a brake caliper (6) formed on the other side in the vehicle front-rear direction from the main body portion (21). A brake caliper installation portion (26), and a wall surface (21c) installed so as to surround the plurality of bolt holes (21b) and standing on the vehicle body side. The wall surface (21c) is formed so as to linearly connect the adjacent bolt holes (21b), and the height of the wall surface (21c) to be erected is substantially the same over the entire circumference of the wall surface. It is formed.

  In the aluminum steering knuckle (20) according to the present invention, a rib (31) is formed between the damper connecting portion (22), the tie rod connecting portion (25), and the main body portion (21). Thus, the outer shape of the rib (31) can be formed by drawing a ridge line that linearly connects the damper connecting portion (22) and the tie rod connecting portion (25).

  Furthermore, in the aluminum steering knuckle (20) according to the present invention, another rib (33) is provided between the damper connecting portion (22), the brake caliper installation portion (26), and the main body portion (21). The outer shape of the another rib (33) is formed so as to draw a ridge line that linearly connects the damper connecting portion (22) and the brake caliper installation portion (26). It can be.

  According to the present invention, there is provided an aluminum steering knuckle having high rigidity equal to or higher than that obtained with an iron-based material while maintaining the light weight characteristics of light weight metal materials such as aluminum and aluminum alloys. Can be provided.

It is the schematic explaining the schematic structure of the general vehicle suspension apparatus in which the aluminum steering knuckle which concerns on this embodiment is used. It is a front view of the aluminum steering knuckle which concerns on this embodiment, and has shown the surface which faces a vehicle main body side at the time of attachment. It is a rear view of the aluminum steering knuckle which concerns on this embodiment, and has shown the surface which faces a wheel side at the time of attachment. 1 is an external perspective view of an aluminum steering knuckle according to the present embodiment.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments for carrying out the invention will be described with reference to the drawings. The following embodiments do not limit the invention according to each claim, and all combinations of features described in the embodiments are not necessarily essential to the solution means of the invention. .

  First, the structure of the general vehicle suspension apparatus 1 in which the aluminum steering knuckle 20 according to the present embodiment is installed will be described with reference to FIG. Here, FIG. 1 is a schematic diagram illustrating a schematic configuration of a general vehicle suspension device 1 in which the aluminum steering knuckle according to the present embodiment is used. Note that FIG. 1 is a schematic diagram for explaining the usage mode of the present invention only, and therefore, the aluminum steering knuckle 120 shown in FIG. 1 is drawn with a general one different from the configuration of the present invention. It is.

  The vehicle suspension device 1 is a suspension device for a front wheel, and an aluminum steering knuckle 120 is provided as a support member that rotatably supports a wheel hub (not shown). The vehicle suspension device 1 is a McPherson-Strut suspension device, and an aluminum steering knuckle 120 as a support member is a main body 121 serving as a mounting portion of a wheel support body such as a wheel hub (not shown). A damper connecting part 122 provided above the main body part 121 and connected to the damper 2; a lower arm connecting part 123 provided below the main body part 121 and connected to the lower arm 3; A tie rod connecting portion 125 provided at the tip of an arm 124 formed extending in the direction and connected to the tie rod 5, and a brake caliper installing portion 126 formed from the main body portion 121 in the vehicle front direction and where the brake caliper 6 is installed. And is configured. Although FIG. 1 illustrates the case where the vehicle suspension device 1 is used for the front wheels, for the McPherson strut type suspension device, the width of the lower arm 3 is widened or the lower arm 3 is made two. By taking measures such as adopting a parallel link type, it can also be used for the rear wheels.

  Further, the vehicle suspension device 1 includes a disc rotor 10 that engages with a wheel hub (not shown) and rotates integrally with the wheel 15 as a component constituting a friction brake mechanism (disc type brake). In the wheel hub (not shown), a plurality of hub bolts (not shown) are arranged in the circumferential direction around the rotor rotation axis. By using the hub bolt, the disc rotor 10 and the wheel 15 It is bolted to a hub (not shown). Thereby, the disc rotor 10 rotates integrally with the wheel 15 and the wheel hub (not shown).

  In addition, the vehicle suspension device 1 includes a brake pad (not shown) as a friction member that generates frictional force in contact with the sliding contact surface of the disk rotor 10 as components constituting the friction brake mechanism, and the brake pad. The brake caliper 6 sandwiches the disc rotor 10 from both sides. The brake caliper 6 holds two brake pads arranged so as to sandwich the disc rotor 10, and presses the brake pad by a wheel cylinder (not shown) to transmit the operating force to the brake pad. A frictional force can be generated between the pad and the disk rotor 10. The frictional force acts in the circumferential direction of the rotor rotation shaft, and generates a braking force on the ground contact surface of the wheel 15 coupled to the disk rotor 10.

  When the disc caliper 6 is rotated integrally with the wheel 15 and the brake caliper 6 transmits an operating force to a brake pad (not shown) when the disc suspension 10 is rotated integrally with the wheel 15, the vehicle suspension device 1 configured in this way A frictional force acts on the sliding contact surface with the rotor 10 in the circumferential direction of the rotor rotation shaft. This frictional force generates a braking force on the ground contact surface of the wheel 15, and as a reaction force, a circumferential force (moment of force) of the rotor rotating shaft is made of aluminum from the brake pad via the brake caliper 6 and the like. It is transmitted to the steering knuckle 120. That is, when a frictional force is generated between a brake pad (not shown) and the disk rotor 10, a moment of force around the rotor rotational axis is transmitted from the brake caliper 6 to the aluminum steering knuckle 120.

  The general configuration of the vehicle suspension apparatus 1 on which the general aluminum steering knuckle 120 is installed has been described above with reference to FIG. The aluminum steering knuckle according to the present invention can be used for this type of general vehicle suspension apparatus 1. Therefore, next, detailed morphological features of the aluminum steering knuckle 20 according to the present embodiment will be described with reference to FIGS. Here, FIG. 2 is a front view of the aluminum steering knuckle 20 according to the present embodiment, and shows a surface facing the vehicle main body when mounted. FIG. 3 is a rear view of the aluminum steering knuckle 20 according to the present embodiment, and shows a surface facing the wheel side during mounting. FIG. 4 is an external perspective view of the aluminum steering knuckle 20 according to this embodiment.

  The aluminum steering knuckle 20 according to this embodiment shown in FIGS. 2 to 4 is manufactured by a conventionally known casting method such as gravity casting or inclined gravity casting, and has a significant feature in its morphological shape. ing. First, the basic configuration of the aluminum steering knuckle 20 according to the present embodiment will be described.

  The aluminum steering knuckle 20 according to the present embodiment has a main body portion 21 serving as a mounting portion of a wheel support body such as the wheel hub (not shown) described above at the center thereof. A substantially circular cavity 21a is formed at the center of the main body 21, and four bolt holes 21b are formed around the substantially circular cavity 21a.

  A hub bearing (not shown) that constitutes a wheel support body is disposed in the substantially circular cavity 21a. On the other hand, hub bolts (not shown) are screwed and joined to the four bolt holes 21b. That is, a hub bolt (not shown) is screwed into the four bolt holes 21b, so that the wheel support body, the wheel 15 and the like described above are installed in the main body 21 of the aluminum steering knuckle 20.

  A damper connecting portion 22 for connecting the damper 2 is formed above the main body portion 21. The damper 2 includes a spring and a piston rod. As illustrated in FIG. 1, the lower end side of the piston rod is connected and joined to the damper connecting portion 22 by a bolt via a connecting member. It will be. Therefore, the damper connecting part 22 receives a moment mainly in the direction toward the main body part 21.

  A lower arm connecting portion 23 for connecting the lower arm 3 is formed below the main body portion 21. The lower arm connecting portion 23 is also configured so that the lower arm 3 illustrated in FIG. 1 can be reliably connected to the lower arm connecting portion 23 by using fastening means such as a bolt.

  An arm 24 is formed to extend in the vehicle rear direction of the main body 21 (right direction in FIG. 2). A tie rod for connecting the tie rod 5 illustrated in FIG. A connecting portion 25 is formed. The tie rod connecting portion 25 according to the present embodiment is formed with an opening hole facing in the vertical direction of the vehicle. By fitting the convex portion of the tie rod 5 into this opening hole, the tie rod 5 and the aluminum steering knuckle 20 are formed. It is comprised so that connection may be realized.

  On the other hand, a brake caliper installation portion 26 for installing the brake caliper 6 is formed in the vehicle front direction of the main body portion 21 (left direction in FIG. 2). The brake caliper installation portion 26 according to the present embodiment is configured as two bolt holes, and the brake caliper 6 can be reliably fixed to the aluminum steering knuckle 20 by using fastening means such as bolts. It is like that.

  The aluminum steering knuckle 20 according to the present embodiment having the basic configuration as described above, the aluminum steering knuckle 20 is equivalent to the rigidity obtained with the iron-based material while maintaining the characteristics of being lightweight. In order to obtain the above high rigidity, various significant morphological features are provided. The specific configuration will be described below.

  First, in the aluminum steering knuckle 20 according to the present embodiment, a wall surface 21c is formed so as to surround a plurality of bolt holes 21b formed in the main body 21. The wall surface 21c is provided so as to stand toward the vehicle body side, and is formed so as to linearly connect the adjacent bolt holes 21b. Further, the wall surface 21c is formed so that the height of the wall surface 21c to be erected is substantially the same over the entire circumference of the wall surface. When the wall surface 21c according to the present embodiment has the above-described configuration, it is possible to improve the inward rigidity applied to the standing direction of the wall surface 21c, that is, the direction toward the vehicle main body. Such an effect particularly leads to a favorable reception of the moment applied at the time of turning, so that the aluminum steering knuckle 20 according to the present embodiment can be obtained with an iron-based material while maintaining the light weight characteristic of aluminum. It is possible to obtain a high rigidity equal to or higher than the rigidity obtained.

  The brake caliper 6 is installed at the position where the brake caliper installation part 26 provided in front of the aluminum steering knuckle 20 is formed. In addition, a brake moment, a vehicle front-rear direction force, an inward force, and the like are applied. Therefore, also from this point, the wall surface 21c according to the present embodiment realizes that the rigidity of the aluminum steering knuckle 20 is increased.

  On the inner side of the wall surface 21c in the main body 21, a portion 21d other than a portion where the plurality of bolt holes 21b is formed is gradually formed, and a portion 21b ′ where the plurality of bolt holes 21b are formed is the other inside the wall surface 21c. It is formed to be higher than the portion 21d. In this configuration, that is, by providing a step between the formation location 21b ′ of the plurality of bolt holes 21b to which the hub bolt is fastened and the location 21d other than the formation location of the plurality of bolt holes 21b, this step is formed on the wall surface described above. Since the same effect as 21c is exhibited, it is possible to further improve the inward rigidity.

  The arm 24 of the aluminum steering knuckle 20 has first cutout portions 24a and 24b. The first lightening portions 24a and 24b are formed on the front side of the arm 24, that is, on the surface side facing the vehicle main body when attached, and on the back side of the arm 24, that is, the attachment. It is composed of a lightening part (24b) formed on the surface side facing the wheel side. Therefore, the first cutout portion 24a according to the present embodiment is configured such that the cross-sectional shape of the arm 24 at the formation position thereof is an H shape. Such a shape is formed to reduce the weight of the aluminum steering knuckle 20.

  Furthermore, in the aluminum steering knuckle 20 according to the present embodiment, the first rib 31 is formed between the damper connecting portion 22, the tie rod connecting portion 25, and the main body portion 21. About this 1st rib 31, the outline shape is formed so that the ridgeline which connects the damper connection part 22 and the tie rod connection part 25 linearly may be drawn.

  Furthermore, in the aluminum steering knuckle 20 according to the present embodiment, the second rib 32 is formed between the lower arm connecting portion 23, the tie rod connecting portion 25, and the main body portion 21. About this 2nd rib 32, the outline shape is formed so that the ridgeline which connects the lower arm connection part 23 and the tie rod connection part 25 linearly may be drawn.

  The shapes of the first rib 31 and the second rib 32 realize improvement in rigidity of the arm 24 and the like without wasteful fleshing. In particular, by connecting the damper connecting portion 22 and the tie rod connecting portion 25 and the lower arm connecting portion 23 and the tie rod connecting portion 25 in a straight line, a very simple shape is realized. It produces multiple effects such as improved rigidity and lighter weight.

  Furthermore, in the aluminum steering knuckle 20 according to the present embodiment, the third rib 33 is formed between the damper connecting portion 22, the brake caliper installation portion 26, and the main body portion 21. About this 3rd rib 33, the outline shape is formed so that the ridgeline which connects the damper connection part 22 and the brake caliper installation part 26 linearly may be drawn. Although it is clear that the third rib 33 exerts the same effect as the first rib 31 and the second rib 32 described above, the place where the third rib 33 is installed is the brake caliper. 6 is close to the installation position 6, the force in the rotational direction of the wheel 15, the moment of the brake, and the like are exerted. In addition, the third rib 33 according to the present embodiment is suitable for the installation location of the third rib 33, particularly when a moment in the falling direction is applied when the vehicle suddenly brakes or starts suddenly. As a result, the rigidity of the aluminum steering knuckle 20 is increased.

  Further, the damper connecting portion 22 of the present embodiment has a shape extending in the vertical direction, and the first rib 31 and the third rib 33 are disposed in the left-right direction of the damper connecting portion 22. . The arrangement positions of the first ribs 31 and the third ribs 33 correspond to positions in the front-rear direction of the vehicle when viewed from the damper connecting portion 22. That is, the 1st rib 31 and the 3rd rib 33 are comprised so that the function which prevents the damper connection part 22 from falling down in the front-back direction of a vehicle can be exhibited. Such a fall prevention effect on the damper connecting portion 22 exhibited by the first rib 31 and the third rib 33 in cooperation improves the rigidity and strength of the aluminum steering knuckle 20 according to the present embodiment. It contributes.

  Furthermore, in the aluminum steering knuckle 20 according to the present embodiment, the second cutout portion 22a is formed on the back surface side of the damper connecting portion 22, that is, on the attachment side of the wheel support at the place where the damper connecting portion 22 is formed. Has been. Further, a thinning reinforcing rib 22b is formed inside the second thinning portion 22a.

  Here, the second cutout portion 22a is formed for weight reduction, but in order to realize a weight reduction with a good balance around the installation location of the damper connection portion 22, the second embodiment of the present embodiment. The two-walled portion 22a is formed at the center of the back surface of the place where the damper connecting portion 22 is formed. With this configuration, it is possible to receive an external force almost evenly on the left and right sides of the second cutout portion 22a. Moreover, in order to make the contradictory characteristics of weight reduction and high rigidity compatible as much as possible, in this embodiment, the thickness reduction rib 22b is formed at the center position inside the second thickness reduction portion 22a. . Thereby, while the maximum weight reduction is achieved by the formation of the second cutout portion 22a, the rigidity is maintained by the presence of the cutout reinforcement rib 22b, so that the conflicting characteristics of weight reduction and high rigidity are compatible. It has been realized. In addition, since the thickness reduction rib 22b which concerns on this embodiment is formed so that it may have a wall surface along the front-back direction of a vehicle, it has contributed especially to the improvement of the rigidity in the front-back direction of a vehicle. However, the shape, formation location, and the like of the lightening reinforcement rib according to the present invention may be arbitrarily determined according to characteristics such as the direction of external force exerted on the steering knuckle.

  As mentioned above, although preferred embodiment of this invention was described, the technical scope of this invention is not limited to the range as described in the said embodiment. Various modifications or improvements can be added to the embodiment.

  For example, the thinning reinforcing rib 22b according to the present embodiment is formed only inside the second thinning portion 22a formed on the back surface side of the damper connecting portion 22, but the first meat according to the present embodiment. It can form with respect to the site | part corresponded to the extraction parts 24a and 24b and other meat extraction parts.

  Further, for example, in the aluminum steering knuckle 20 according to the present embodiment, the arm 24 and the tie rod connecting portion 25 are formed with respect to the vehicle rear direction of the main body portion 21 (the right direction in the drawing in FIG. 2). A brake caliper installation portion 26 was formed in the forward direction (left direction in FIG. 2). However, the formation position of the arm 24 and the tie rod coupling part 25 and the formation position of the brake caliper installation part 26 may be formed in the left-right direction opposite to the case of this embodiment.

  Furthermore, although the aluminum steering knuckle 20 according to the present embodiment described above is used in a McPherson strut type suspension device, the scope of application of the present invention is not limited to this type. For example, the technical idea of the present invention can be applied to all other formats such as a double wishbone type and a multilink type.

  Furthermore, the manufacturing method of the aluminum steering knuckle 20 according to the present embodiment is manufactured not only by casting techniques such as gravity casting and inclined gravity casting exemplified in the background art column, but also by other manufacturing methods such as forging. It is possible.

  It is apparent from the description of the scope of claims that embodiments with such changes or improvements can be included in the technical scope of the present invention.

  DESCRIPTION OF SYMBOLS 1 Vehicle suspension apparatus, 2 damper, 3 lower arm, 5 tie rod, 6 brake caliper, 10 disc rotor, 15 wheel, 20, 120 aluminum steering knuckle, 21, 121 main body part, 21a substantially circular cavity, 21b bolt hole, 21b ′ (Formation point of bolt hole 21b), 21c wall surface, 21d (excluding the formation place of bolt hole 21b), 22,122 damper connection part, 22a second cutout part, 22b cutout reinforcement rib, 23,123 lower arm Connecting portion, 24, 124 arm, 24a, 24b first cutout portion, 25, 125 tie rod connecting portion, 26, 126 Brake caliper installation portion, 31 first rib, 32 second rib, 33 third rib.

Claims (3)

An aluminum steering knuckle used in vehicles,
By having a substantially circular cavity and a plurality of bolt holes arranged around the substantially circular cavity, a main body part to be an attachment location of the wheel support,
A damper connecting portion provided above the main body portion and connected to the damper;
A lower arm coupling portion provided below the main body portion and coupled to the lower arm;
A tie rod coupling portion provided at the tip of an arm formed extending from the main body portion in either the vehicle front-rear direction or coupled to a tie rod;
A brake caliper installation part that is formed on the other side of the vehicle front-rear direction from the main body part and a brake caliper is installed
In addition,
It is installed so as to surround the periphery of the plurality of bolt holes and has a wall surface provided to stand on the vehicle body side,
The aluminum steering knuckle is characterized in that the wall surface is formed so as to linearly connect adjacent bolt holes and the height of the wall surface to be erected is substantially the same in the entire circumference of the wall surface. . In the aluminum steering knuckle according to claim 1,
A rib is formed between the damper connecting portion, the tie rod connecting portion and the main body portion,
An aluminum steering knuckle characterized in that an outer shape of the rib is formed by drawing a ridge line that linearly connects the damper connecting portion and the tie rod connecting portion. In the aluminum steering knuckle according to claim 1 or 2,
Another rib is formed between the damper connecting portion, the brake caliper installation portion, and the main body portion,
The aluminum steering knuckle is characterized in that the outer shape of the another rib is formed by drawing a ridge line that linearly connects the damper connecting portion and the brake caliper installation portion.

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