Suspension clip ring mount

An actuator arm assembly that has a pair of spring-like fingers which extend from an actuator arm and clamp the arm to the housing of a bearing assembly. The actuator arm assembly includes a magnetic head that is mounted to a suspension beam. The suspension beam is welded to the actuator arm. After the beam is welded to the arm and the head is mounted to the beam, the actuator arm is clamped to the bearing assembly by merely pushing the arm and snapping the fingers onto the bearing housing. The actuator assembly may also have a coil support arm that supports a voice coil and has a pair of fingers which can be snapped onto the bearing assembly.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to an actuator arm assembly of a hard disk 
drive. 
2. Description of Related Art 
Hard disk drives contain magnetic heads that magnetize and sense the 
magnetic field of a rotating disk. The heads are typically mounted to an 
actuator arm assembly that rotates about a bearing assembly mounted to a 
base plate of the drive. At one end of the actuator arm assembly is a 
voice coil motor which moves each head across the surface of the disk. 
Conventional actuator arm assemblies include a suspension beam that 
supports a magnetic head at one end and is attached to an actuator arm at 
the other one end. The actuator arm is mounted to an outer housing of the 
bearing assembly. When mass producing the actuator arm assembly of a disk 
drive, the actuator arm is initially attached to the bearing assembly and 
the head is mounted to the suspension beam. The suspension beam is then 
attached to the actuator arm. The suspension beam is typically attached to 
the actuator arm by screws, adhesives or a swagging process. Screws are 
relatively large and limit the overall height of the assembly, adhesives 
may "outgas" chemicals that adhere to the disk surface and destroy 
segments of the disk, swagging can result in unpredictable gram loading of 
the head and thus affect the performance of the drive. It would therefore 
be desirable to provide an actuator arm assembly that did not require 
conventional fasteners, adhesives or swagging techniques to couple the 
suspension arm to the bearing assembly of a hard disk drive. 
SUMMARY OF THE INVENTION 
The present invention is an actuator arm assembly that has a pair of 
spring-like fingers which extend from an actuator arm and clamp the arm to 
the housing of a bearing assembly. The actuator arm assembly includes a 
magnetic head that is mounted to a suspension beam. The suspension beam is 
welded to the actuator arm. After the beam is welded to the arm and the 
head is mounted to the beam, the actuator arm is clamped to the bearing 
assembly by merely pushing the arm and snapping the fingers onto the 
bearing housing. The actuator assembly may also have a coil support arm 
that supports a voice coil and has a pair of fingers which can be snapped 
onto the bearing assembly.

DETAILED DESCRIPTION OF THE INVENTION 
Referring to the drawings more particularly by reference numbers, FIG. 1 
shows an actuator arm assembly 10 of the present invention located within 
a hard disk drive. The assembly 10 includes a pair of magnetic heads 12 
that magnetize and sense the magnetic field of a rotating disk 14. There 
is typically one head for each surface of the disk 14. The disk 14 is 
rotated by a spin motor (not shown). The actuator assembly 10 further 
includes a voice coil 16 that is coupled to a magnet 18 that is mounted to 
a base plate 20 of the disk drive. Together, the voice coil 16 and magnet 
18 create a voice coil motor which moves each head 12 across the surface 
of the disk 14. 
Each head 12 is mounted to a corresponding suspension beam 22. Although one 
disk 14, two heads 12 and two corresponding beams 22 are shown and 
described, it is to be understood that the present invention can be used 
in a hard drive with multiple disk 14. The suspension beams 22 are 
typically constructed from a thin metal material which supports the heads 
12 above the disk 14. The suspension beams 22 are rigidly attached to a 
pair of corresponding actuator arms 24. In the preferred embodiment, the 
beams 22 are welded to the arms 24. 
The actuator arms 24 are attached to a bearing assembly 26 that is mounted 
to the base plate 20 of the disk drive. The bearing assembly 26 includes 
an outer housing 28 that rotates relative to the base plate 20. The outer 
bearing housing 28 contains a plurality of annular grooves 32 which 
receive fingers 34 of the actuator arms 24. The fingers 34 attach the 
actuator arms 24 and corresponding heads 12 to the bearing assembly 26. 
As shown in FIG. 2, each actuator arm 24 has a pair of circumferentially 
shaped fingers 34 that define an opening 36 with a diameter smaller than 
the diameter of the annular grooves 32. As shown in FIG. 3, when the arm 
24 is pushed onto the bearing housing 28, the fingers 34 are deflected in 
an outward direction. The arm 24 is pushed onto the housing 28 until the 
base 40 of the fingers 34 is adjacent to the inner diameter groove 32. 
Each finger 34 has an inward lip 42 that secures the actuator arm 24 to 
the bearing housing 28 in the fully assembly position shown in FIG. 1. The 
diameters of the outer housing groove 32 and the finger opening 36 are 
such that the fingers 34 are still deflected when the actuator arm 24 is 
fully assembled to the bearing assembly 26, wherein the fingers 34 apply a 
clamping force that secures the arm 24 to the housing 28. In the preferred 
embodiment, the actuator arms 24 are constructed from a hardened steel. 
Referring to FIGS. 1 and 2, the voice coil 16 is attached to a coil support 
arm 44. Like the actuator arms 24, the support arm 44 has a pair of 
fingers that are clamped to an annular groove 32 of the bearing housing 
28. To assemble the actuator arm assembly 10, the suspension beams 22 are 
initially attached to the actuator arms 24 and the heads 12 are mounted to 
the suspension beams 22. The voice coil 16 is also attached to the support 
arm 44 by finger members 46. The actuator arms 24 and support arm 44 are 
then snapped onto the bearing housing 28. The actuator arms 24 preferably 
have tooling holes 48 which align the heads 12 relative to each other. 
Although a groove 32 is described and shown, it is to be understood that 
the arms 24 and 44 can be clamped to a bearing assembly 26 that does not 
have grooves 32. The lack of a groove would allow the actuator arm and 
corresponding head to be adjusted along the z-axis after assembly. 
The present invention provides an actuator arm assembly that is easy to 
install and can be readily disassembled to rework the disk drive during 
mass production of the drive unit. Additionally, the actuator arm assembly 
10 may have a relatively low profile so that the assembly can be utilized 
in small disk drives which comply with the specifications promulgated by 
the Personal Computer Memory Card International Association (PCMCIA). The 
PCMCIA is an association that has promulgated a specification which list 
dimensions and other requirements for a standard memory card. Each 
computer that conforms with the PCMCIA specification will contain sockets 
that can receive a standardized card. With such a standard, memory cards 
of one computer can be readily plugged into another computer, regardless 
of the model or make of the systems. A copy of the PCMCIA standard can be 
obtained by writing to the Personal Computer Memory Card International 
Association at 1030 G East Duane Avenue, Sunnyvale, Calif. 94086. 
The PCMCIA standard includes three types of cards which each have varying 
thicknesses. A type I card is 3.3 millimeters thick, a type II card is 5.0 
millimeters thick and a type III card is 10.5 millimeters thick. The 
computer may have a plurality of adjacent sockets that are wide enough to 
receive a type II card. Both the type I and II cards occupy a single 
socket, while the type III card occupies the area of two adjacent sockets. 
Each computer socket contains a 68 pin connector that is typically mounted 
to a motherboard to provide an interconnect to the computer system. The 
actuator arm assembly 10 of the present invention can be used within disk 
drives that meet the type I, type II or type III PCMCIA specifications. 
While certain exemplary embodiments have been described and shown in the 
accompanying drawings, it is to be understood that such embodiments are 
merely illustrative of and not restrictive on the broad invention, and 
that this invention not be limited to the specific constructions and 
arrangements shown and described, since various other modifications may 
occur to those ordinarily skilled in the art.