The present invention relates generally to a ball-and-socket assembly, and in particular to an excep¬ tionally strong ball-and-socket assembly which prevents the ball from being removed from the socket. It is typical for ball-and-socket assemblies to be assembled in a manufacturing plant where various types of machinery are available to perform operations such as a crimping of the socket containing member around the ball head. In one application, a ball-and-socket connection is utilized between a hydraulic brake booster assembly and a rod attached to the brake pedal of the vehicle. The ball head of the brake pedal rod is typically inserted into the socket, which may be made of plastic or other materials, and then the socket containing member is crimped by a machine so that the ball head is captured within the socket. However, it is sometimes necessary that the brake pedal rod be attached to the hydraulic brake booster in the field where such machinery is not available. Thus, a ball-and-socket assembly is highly desirable which can be assembled with equal ease both in a factory and in the field. It is necessary that the assembly be accomplished without the utilization of any machinery, with the utilization of perhaps only hand tools, and that the ball-and-socket assembly provide an exceptionally strong coupling so that the brake pedal rod is essentially attached permanently to the hydraulic brake booster assembly.

The present invention provides solutions to the above problem by providing a ball-and-socket assembly, comprising a body having therein a multidiameter bore, the multidiameter bore comprising a flared entrance wall communicating with an open end of the body, a shoulder defined by an end of the flared entrance wall and a large diameter portion of the bore, a small diameter portion located axially interiorly of the bore relative to the

large diameter portion, the small diameter and large diameter portions of the bore connected by a frustoconical wall extending radially outwardly in an axial direction corresponding to an axial direction of radial extension of the flared entrance wall, a rod having a ball head thereon, the ball head including a groove thereabout, and a flexible member disposed within said groove and extending radially outwardly therefrom and beyond the shoulder, the flexible member movable diametrically, relative to the ball head, by engagement with the frusto¬ conical wall as the rod is pivoted.

One way of carrying out the invention is described in detail below with reference to the drawings which illustrate an embodiment in which:

Figure 1 is a section view of the ball-and-socket assembly of the present invention; ^'

Figure 2 is an isometric view of the rod and flexible circlip; and

Figure 3 is an illustration of the ball-and- socket assembly when the rod is pivoted relative to an axial centerline of the assembly.

The ball-and-socket assembly of the present invention is designated generally by reference numeral 10 in Figure 1. Assembly 10 includes brake pedal rod 12 which extends to ball or ball head 14 having therein a diametrical groove 16, and ball head 14 extends .from enlarged diameter rod portion 18 located adjacent narrow diameter rod portion 20. Located within groove 16 is groove bottom 17 surrounded by flexible member or circlip 30 having ends 32 (see Figure 2) and circumferential portion 34. A hydraulic brake booster in Figure 1 is designated generally by reference numeral 40 and includes rear member 42 constituting body 44 with axial multidiam¬ eter bore 46 located therein. Axial multidiameter bore 46 comprises open end 48 communicating with a flared entrance wall 50, and radial shoulder 52 defined between an end of flared entrance wall 50 and large diameter

portion 54 of bore 46. Bore 46 includes small diameter portion 58 located axially interiorly of the bore relative to large diameter portion 54, and frustoconical wall 56 extending between small diameter portion 58 and large diameter portion 54. Frustoconical wall 56 extends radially outwardly as the wall proceeds axially from small diameter portion 58 toward large diameter portion 54. Bore 46 comprises a blind bore having radially sloped end surfaces 60 merging at bore bottom 62. Large diameter portion 54 is located at curved corner 64 which extends between the large diameter portion 54 and radial shoulder 52.

Ball-and-socket assembly 10 is assembled according to the following procedure. Flexible member or circlip 30 is moved laterally into groove 16 such that the circlip ends 32 expand radially outwardly as they contact groove bottom 17 and then snap or retract radially inwardly of groove 16. Circlip 30 is located such that radially inward portion 30A is located within groove 16 while radially outward portion 30B is located radially outwardly of surface 14A of ball head 14. The subassembly comprising rod 12 and circlip 30 is then inserted axially into bore 46 so that as ball head 14 moves axially past flared entrance wall 50 of the bore, the flared entrance wall forces flexible circlip 30 radially inwardly so that ends 32 approach each other as the circlip compresses inwardly of groove 16. As circlip 30 is moved axially by head 14 and passes radial shoulder 52, the circlip rebounds resiliently outwardly to assume its normal at-rest position as illustrated in Figure 1. Surface 14A of ball head 14 will bottom on radially sloped surfaces 60 and the ball head will be trapped within bore 46 as a result of the radially outward portion 30B of circlip 30 engaging shoulder 52 when rod 12 is moved axially awa from bore 46.

When rod 12 is pivoted as illustrated in Figure 3, large diameter portion 18 of rod 12 and entrance wall 50 define the limit of rotation or maximum angle to whirr

rod 12 can be pivoted relative to the illustrated center- line of the assembly. As rod 12 pivots, the portion of circlip 30 which is located adjacent the side of rod 12 approaching flared entrance wall 50 engages frustoconical wall 56 such that circlip 30 is forced radially into groove 16 in the direction of arrow A and the opposite side of circlip 30 moves radially outwardly relative to the groove. The result is that the radially outward portion 30B of circlip 30 which has been moved radially outwardly continues to be adjacent frustoconical wall 56 and will engage radial shoulder 52 if the rod should be moved outwardly of the bore. This effectively prevents ball head 14 from being pulled from bore 46 despite the pivoting of rod 12.

The ball-and-socket assembly of the present invention provides an exceptionally strong coupling between the pedal rod and hydraulic brake booster. The pull out force required to remove ball head 14 from bore 46 is at least three times greater than that present in prior assemblies, such that in effect a permanent ball- and-socket assembly has been provided. Additionally, and equally important, is the easy assembly of the ball-and- socket assembly in the field without the requirement of machinery normally present in a manufacturing plant. As a result, the ball-and-socket assembly utilized between the brake pedal rod and a hydraulic booster of a vehicle can be assembled easily in either the factory or in the field with a minimal utilization of hand tools and without the requirement of any machinery. The ball-and-socket assembly provides a high strength permanent coupling highly desirable for a brake pedal rod coupled with a hydraulic brake booster.